WSJT-X/widgets/mainwindow.cpp

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//---------------------------------------------------------- MainWindow
#include "mainwindow.h"
2020-09-24 12:57:06 -04:00
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
#include <cinttypes>
#include <cstring>
2018-12-06 12:11:57 -05:00
#include <cmath>
#include <limits>
#include <functional>
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
#include <fstream>
#include <iterator>
#include <algorithm>
#include <fftw3.h>
#include <QApplication>
#include <QStringListModel>
#include <QSettings>
#include <QKeyEvent>
#include <QProcessEnvironment>
#include <QSharedMemory>
#include <QFileDialog>
#include <QTextBlock>
#include <QProgressBar>
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
#include <QLineEdit>
#include <QRegExpValidator>
#include <QRegExp>
#include <QRegularExpression>
#include <QDesktopServices>
#include <QUrl>
#include <QStandardPaths>
#include <QDir>
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
#include <QDebug>
#include <QtConcurrent/QtConcurrentRun>
#include <QProgressDialog>
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
#include <QHostInfo>
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
#include <QVector>
#include <QCursor>
#include <QToolTip>
#include <QAction>
#include <QButtonGroup>
#include <QActionGroup>
#include <QSplashScreen>
#include <QUdpSocket>
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#include <QAbstractItemView>
#include <QInputDialog>
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#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
#include <QRandomGenerator>
#endif
#include "revision_utils.hpp"
#include "qt_helpers.hpp"
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#include "Network/NetworkAccessManager.hpp"
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#include "Audio/soundout.h"
#include "Audio/soundin.h"
#include "Modulator/Modulator.hpp"
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#include "Detector/Detector.hpp"
#include "plotter.h"
#include "echoplot.h"
#include "echograph.h"
#include "fastplot.h"
#include "fastgraph.h"
#include "about.h"
#include "messageaveraging.h"
#include "colorhighlighting.h"
#include "widegraph.h"
#include "sleep.h"
#include "logqso.h"
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#include "Decoder/decodedtext.h"
#include "Radio.hpp"
#include "models/Bands.hpp"
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#include "Transceiver/TransceiverFactory.hpp"
#include "models/StationList.hpp"
#include "validators/LiveFrequencyValidator.hpp"
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#include "Network/MessageClient.hpp"
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#include "Network/wsprnet.h"
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
#include "signalmeter.h"
#include "HelpTextWindow.hpp"
#include "SampleDownloader.hpp"
#include "Audio/BWFFile.hpp"
#include "MultiSettings.hpp"
#include "validators/MaidenheadLocatorValidator.hpp"
#include "validators/CallsignValidator.hpp"
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#include "EqualizationToolsDialog.hpp"
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#include "Network/LotWUsers.hpp"
#include "logbook/AD1CCty.hpp"
#include "models/FoxLog.hpp"
#include "models/CabrilloLog.hpp"
#include "FoxLogWindow.hpp"
#include "CabrilloLogWindow.hpp"
#include "ExportCabrillo.h"
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
#include "ui_mainwindow.h"
#include "moc_mainwindow.cpp"
extern "C" {
//----------------------------------------------------- C and Fortran routines
void symspec_(struct dec_data *, int* k, double* trperiod, int* nsps, int* ingain,
bool* bLowSidelobes, int* minw, float* px, float s[], float* df3,
int* nhsym, int* npts8, float *m_pxmax, int* npct);
void hspec_(short int d2[], int* k, int* nutc0, int* ntrperiod, int* nrxfreq, int* ntol,
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bool* bmsk144, bool* btrain, double const pcoeffs[], int* ingain,
char mycall[], char hiscall[], bool* bshmsg, bool* bswl, char ddir[], float green[],
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float s[], int* jh, float *pxmax, float *rmsNoGain, char line[],
fortran_charlen_t, fortran_charlen_t, fortran_charlen_t, fortran_charlen_t);
void genft8_(char* msg, int* i3, int* n3, char* msgsent, char ft8msgbits[],
int itone[], fortran_charlen_t, fortran_charlen_t);
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void genft4_(char* msg, int* ichk, char* msgsent, char ft4msgbits[], int itone[],
fortran_charlen_t, fortran_charlen_t);
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void genfst4_(char* msg, int* ichk, char* msgsent, char fst4msgbits[],
int itone[], int* iwspr, fortran_charlen_t, fortran_charlen_t);
void gen_ft8wave_(int itone[], int* nsym, int* nsps, float* bt, float* fsample, float* f0,
float xjunk[], float wave[], int* icmplx, int* nwave);
void gen_ft4wave_(int itone[], int* nsym, int* nsps, float* fsample, float* f0,
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float xjunk[], float wave[], int* icmplx, int* nwave);
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void gen_fst4wave_(int itone[], int* nsym, int* nsps, int* nwave, float* fsample,
int* hmod, float* f0, int* icmplx, float xjunk[], float wave[]);
void gen4_(char* msg, int* ichk, char* msgsent, int itone[],
int* itext, fortran_charlen_t, fortran_charlen_t);
void gen9_(char* msg, int* ichk, char* msgsent, int itone[],
int* itext, fortran_charlen_t, fortran_charlen_t);
void genmsk_128_90_(char* msg, int* ichk, char* msgsent, int itone[], int* itype,
fortran_charlen_t, fortran_charlen_t);
void gen65_(char* msg, int* ichk, char* msgsent, int itone[],
int* itext, fortran_charlen_t, fortran_charlen_t);
void genqra64_(char* msg, int* ichk, char* msgsent, int itone[],
int* itext, fortran_charlen_t, fortran_charlen_t);
void genwspr_(char* msg, char* msgsent, int itone[], fortran_charlen_t, fortran_charlen_t);
void geniscat_(char* msg, char* msgsent, int itone[], fortran_charlen_t, fortran_charlen_t);
void azdist_(char* MyGrid, char* HisGrid, double* utch, int* nAz, int* nEl,
int* nDmiles, int* nDkm, int* nHotAz, int* nHotABetter,
fortran_charlen_t, fortran_charlen_t);
void morse_(char* msg, int* icw, int* ncw, fortran_charlen_t);
int ptt_(int nport, int ntx, int* iptt, int* nopen);
void wspr_downsample_(short int d2[], int* k);
int savec2_(char* fname, int* TR_seconds, double* dial_freq, fortran_charlen_t);
void avecho_( short id2[], int* dop, int* nfrit, int* nqual, float* f1,
float* level, float* sigdb, float* snr, float* dfreq,
float* width);
void fast_decode_(short id2[], int narg[], double * trperiod,
char msg[], char mycall[], char hiscall[],
fortran_charlen_t, fortran_charlen_t, fortran_charlen_t);
void degrade_snr_(short d2[], int* n, float* db, float* bandwidth);
void wav12_(short d2[], short d1[], int* nbytes, short* nbitsam2);
void refspectrum_(short int d2[], bool* bclearrefspec,
bool* brefspec, bool* buseref, const char* c_fname, fortran_charlen_t);
void freqcal_(short d2[], int* k, int* nkhz,int* noffset, int* ntol,
char line[], fortran_charlen_t);
void fix_contest_msg_(char* MyGrid, char* msg, fortran_charlen_t, fortran_charlen_t);
void calibrate_(char data_dir[], int* iz, double* a, double* b, double* rms,
double* sigmaa, double* sigmab, int* irc, fortran_charlen_t);
void foxgen_();
void plotsave_(float swide[], int* m_w , int* m_h1, int* irow);
void chkcall_(char* w, char* basc_call, bool cok, int len1, int len2);
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void get_ft4msg_(int* idecode, char* line, int len);
}
int volatile itone[NUM_ISCAT_SYMBOLS]; //Audio tones for all Tx symbols
int volatile itone0[NUM_ISCAT_SYMBOLS]; //Dummy array, data not actually used
int volatile icw[NUM_CW_SYMBOLS]; //Dits for CW ID
dec_data_t dec_data; // for sharing with Fortran
int outBufSize;
int rc;
qint32 g_iptt {0};
wchar_t buffer[256];
float fast_green[703];
float fast_green2[703];
float fast_s[44992]; //44992=64*703
float fast_s2[44992];
int fast_jh {0};
int fast_jhpeak {0};
int fast_jh2 {0};
int narg[15];
QVector<QColor> g_ColorTbl;
using SpecOp = Configuration::SpecialOperatingActivity;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
namespace
{
Radio::Frequency constexpr default_frequency {14076000};
QRegExp message_alphabet {"[- @A-Za-z0-9+./?#<>;]*"};
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
// grid exact match excluding RR73
QRegularExpression grid_regexp {"\\A(?![Rr]{2}73)[A-Ra-r]{2}[0-9]{2}([A-Xa-x]{2}){0,1}\\z"};
auto quint32_max = std::numeric_limits<quint32>::max ();
constexpr int N_WIDGETS {36};
constexpr int rx_chunk_size {3456}; // audio samples at 12000 Hz
constexpr int tx_audio_buffer_size {48000 / 5}; // audio frames at 48000 Hz
bool message_is_73 (int type, QStringList const& msg_parts)
{
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
return type >= 0
&& (((type < 6 || 7 == type)
&& (msg_parts.contains ("73") || msg_parts.contains ("RR73")))
|| (type == 6 && !msg_parts.filter ("73").isEmpty ()));
}
int ms_minute_error ()
{
auto const& now = QDateTime::currentDateTimeUtc ();
auto const& time = now.time ();
auto second = time.second ();
return now.msecsTo (now.addSecs (second > 30 ? 60 - second : -second)) - time.msec ();
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
//--------------------------------------------------- MainWindow constructor
MainWindow::MainWindow(QDir const& temp_directory, bool multiple,
MultiSettings * multi_settings, QSharedMemory *shdmem,
unsigned downSampleFactor,
QSplashScreen * splash, QProcessEnvironment const& env, QWidget *parent) :
QMainWindow(parent),
m_env {env},
m_network_manager {this},
m_valid {true},
m_splash {splash},
m_revision {revision ()},
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_multiple {multiple},
m_multi_settings {multi_settings},
m_configurations_button {0},
m_settings {multi_settings->settings ()},
ui(new Ui::MainWindow),
m_config {&m_network_manager, temp_directory, m_settings, &m_logBook, this},
m_logBook {&m_config},
m_WSPR_band_hopping {m_settings, &m_config, this},
m_WSPR_tx_next {false},
m_rigErrorMessageBox {MessageBox::Critical, tr ("Rig Control Error")
, MessageBox::Cancel | MessageBox::Ok | MessageBox::Retry},
m_wideGraph (new WideGraph(m_settings)),
m_echoGraph (new EchoGraph(m_settings)),
m_fastGraph (new FastGraph(m_settings)),
// no parent so that it has a taskbar icon
m_logDlg (new LogQSO (program_title (), m_settings, &m_config, &m_logBook, nullptr)),
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_lastDialFreq {0},
m_dialFreqRxWSPR {0},
m_detector {new Detector {RX_SAMPLE_RATE, double(NTMAX), downSampleFactor}},
m_FFTSize {6192 / 2}, // conservative value to avoid buffer overruns
m_soundInput {new SoundInput},
m_modulator {new Modulator {TX_SAMPLE_RATE, NTMAX}},
m_soundOutput {new SoundOutput},
m_msErase {0},
m_secBandChanged {0},
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_freqNominal {0},
m_freqTxNominal {0},
m_reverse_Doppler {"1" == env.value ("WSJT_REVERSE_DOPPLER", "0")},
m_s6 {0.},
m_tRemaining {0.},
m_TRperiod {60.0},
m_DTtol {3.0},
m_waterfallAvg {1},
m_ntx {1},
m_gen_message_is_cq {false},
m_send_RR73 {false},
m_XIT {0},
m_sec0 {-1},
m_RxLog {1}, //Write Date and Time to RxLog
m_nutc0 {999999},
m_ntr {0},
m_tx {0},
m_inGain {0},
m_secID {0},
m_idleMinutes {0},
m_nSubMode {0},
m_nclearave {1},
m_nseq {0},
m_nWSPRdecodes {0},
m_k0 {9999999},
m_nPick {0},
m_frequency_list_fcal_iter {m_config.frequencies ()->begin ()},
m_nTx73 {0},
m_btxok {false},
m_diskData {false},
m_loopall {false},
m_txFirst {false},
m_auto {false},
m_restart {false},
m_startAnother {false},
m_saveDecoded {false},
m_saveAll {false},
m_widebandDecode {false},
m_dataAvailable {false},
m_decodedText2 {false},
m_freeText {false},
m_sentFirst73 {false},
m_currentMessageType {-1},
m_lastMessageType {-1},
m_bShMsgs {false},
m_bSWL {false},
m_uploading {false},
m_grid6 {false},
m_tuneup {false},
m_bTxTime {false},
m_rxDone {true},
m_bSimplex {false},
m_bEchoTxOK {false},
m_bTransmittedEcho {false},
m_bEchoTxed {false},
m_bFastDecodeCalled {false},
m_bDoubleClickAfterCQnnn {false},
m_bRefSpec {false},
m_bClearRefSpec {false},
m_bTrain {false},
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_bAutoReply {false},
m_QSOProgress {CALLING},
m_ihsym {0},
m_nzap {0},
m_px {0.0},
m_iptt0 {0},
m_btxok0 {false},
m_nsendingsh {0},
m_onAirFreq0 {0.0},
m_first_error {true},
2020-05-19 07:15:58 -04:00
tx_status_label {tr ("Receiving")},
wsprNet {new WSPRNet {&m_network_manager, this}},
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_appDir {QApplication::applicationDirPath ()},
m_cqStr {""},
m_palette {"Linrad"},
m_mode {"JT9"},
m_rpt {"-15"},
m_pfx {
"1A", "1S",
"3A", "3B6", "3B8", "3B9", "3C", "3C0", "3D2", "3D2C",
"3D2R", "3DA", "3V", "3W", "3X", "3Y", "3YB", "3YP",
"4J", "4L", "4S", "4U1I", "4U1U", "4W", "4X",
"5A", "5B", "5H", "5N", "5R", "5T", "5U", "5V", "5W", "5X", "5Z",
"6W", "6Y",
"7O", "7P", "7Q", "7X",
"8P", "8Q", "8R",
"9A", "9G", "9H", "9J", "9K", "9L", "9M2", "9M6", "9N",
"9Q", "9U", "9V", "9X", "9Y",
"A2", "A3", "A4", "A5", "A6", "A7", "A9", "AP",
"BS7", "BV", "BV9", "BY",
"C2", "C3", "C5", "C6", "C9", "CE", "CE0X", "CE0Y",
"CE0Z", "CE9", "CM", "CN", "CP", "CT", "CT3", "CU",
"CX", "CY0", "CY9",
"D2", "D4", "D6", "DL", "DU",
"E3", "E4", "E5", "EA", "EA6", "EA8", "EA9", "EI", "EK",
"EL", "EP", "ER", "ES", "ET", "EU", "EX", "EY", "EZ",
"F", "FG", "FH", "FJ", "FK", "FKC", "FM", "FO", "FOA",
"FOC", "FOM", "FP", "FR", "FRG", "FRJ", "FRT", "FT5W",
"FT5X", "FT5Z", "FW", "FY",
"M", "MD", "MI", "MJ", "MM", "MU", "MW",
"H4", "H40", "HA", "HB", "HB0", "HC", "HC8", "HH",
"HI", "HK", "HK0", "HK0M", "HL", "HM", "HP", "HR",
"HS", "HV", "HZ",
"I", "IS", "IS0",
"J2", "J3", "J5", "J6", "J7", "J8", "JA", "JDM",
"JDO", "JT", "JW", "JX", "JY",
"K", "KC4", "KG4", "KH0", "KH1", "KH2", "KH3", "KH4", "KH5",
"KH5K", "KH6", "KH7", "KH8", "KH9", "KL", "KP1", "KP2",
"KP4", "KP5",
"LA", "LU", "LX", "LY", "LZ",
"OA", "OD", "OE", "OH", "OH0", "OJ0", "OK", "OM", "ON",
"OX", "OY", "OZ",
"P2", "P4", "PA", "PJ2", "PJ7", "PY", "PY0F", "PT0S", "PY0T", "PZ",
"R1F", "R1M",
"S0", "S2", "S5", "S7", "S9", "SM", "SP", "ST", "SU",
"SV", "SVA", "SV5", "SV9",
"T2", "T30", "T31", "T32", "T33", "T5", "T7", "T8", "T9", "TA",
"TF", "TG", "TI", "TI9", "TJ", "TK", "TL", "TN", "TR", "TT",
"TU", "TY", "TZ",
"UA", "UA2", "UA9", "UK", "UN", "UR",
"V2", "V3", "V4", "V5", "V6", "V7", "V8", "VE", "VK", "VK0H",
"VK0M", "VK9C", "VK9L", "VK9M", "VK9N", "VK9W", "VK9X", "VP2E",
"VP2M", "VP2V", "VP5", "VP6", "VP6D", "VP8", "VP8G", "VP8H",
"VP8O", "VP8S", "VP9", "VQ9", "VR", "VU", "VU4", "VU7",
"XE", "XF4", "XT", "XU", "XW", "XX9", "XZ",
"YA", "YB", "YI", "YJ", "YK", "YL", "YN", "YO", "YS", "YU", "YV", "YV0",
"Z2", "Z3", "ZA", "ZB", "ZC4", "ZD7", "ZD8", "ZD9", "ZF", "ZK1N",
"ZK1S", "ZK2", "ZK3", "ZL", "ZL7", "ZL8", "ZL9", "ZP", "ZS", "ZS8"
},
m_sfx {"P", "0", "1", "2", "3", "4", "5", "6", "7", "8", "9", "A"},
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
mem_jt9 {shdmem},
m_downSampleFactor (downSampleFactor),
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_audioThreadPriority (QThread::HighPriority),
m_bandEdited {false},
m_splitMode {false},
m_monitoring {false},
m_tx_when_ready {false},
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_transmitting {false},
m_tune {false},
m_tx_watchdog {false},
m_block_pwr_tooltip {false},
m_PwrBandSetOK {true},
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_lastMonitoredFrequency {default_frequency},
m_toneSpacing {0.},
m_firstDecode {0},
m_optimizingProgress {"Optimizing decoder FFTs for your CPU.\n"
"Please be patient,\n"
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
"this may take a few minutes", QString {}, 0, 1, this},
m_messageClient {new MessageClient {QApplication::applicationName (),
version (), revision (),
m_config.udp_server_name (), m_config.udp_server_port (),
m_config.udp_interface_names (), m_config.udp_TTL (),
this}},
m_psk_Reporter {&m_config, QString {"WSJT-X v" + version () + " " + m_revision}.simplified ()},
m_manual {&m_network_manager},
m_block_udp_status_updates {false}
{
ui->setupUi(this);
setUnifiedTitleAndToolBarOnMac (true);
createStatusBar();
add_child_to_event_filter (this);
ui->dxGridEntry->setValidator (new MaidenheadLocatorValidator {this});
ui->dxCallEntry->setValidator (new CallsignValidator {this});
ui->sbTR->values ({5, 10, 15, 30, 60, 120, 300, 900, 1800});
ui->sbTR_FST4W->values ({120, 300, 900, 1800});
ui->decodedTextBrowser->set_configuration (&m_config, true);
ui->decodedTextBrowser2->set_configuration (&m_config);
Qt 5 Audio replaces PortAudio. Currently only Qt5 or above is known to work with this code. It may be possible to backport it to Qt4 if required. Audio output goes back to a separate thread to try and minimize stutters in streaming on Windows particularly. A crash on Linux due to mishandling of stereo audio output has been fixed and both left and right channels are now correctly synthesised with identical contents. Rigs are enumerated directly from hamlib API rather than running a sub process reading output of rigctl -l. This was initially done to get rid of some GUI thread blocking in the configuration dialog, but is generally a better way of doing it anyway. Some refactoring in MainWindow to accomodate the audio streaming, modulation and detecting classes. Exit handling for application refactored to use signals rather than brute force event loop exit. This was required to get correct thread shutdown semantics. The GUI update timer is now stopped during application shutdown which is necessary to stop crashes when shutting down gracefully with signals and window close() calls. There is an outstanding issue with Linux audio streams; the QAudio Input/Output classes create a new stream name each time a stream is started. This doesn't play well with PulseAudio utilities such as pavucontrol to set stream volume as settings are lost every tx period. I have tried to keep a single stream for all output but there are problems restarting it that haven't been resolved yet. The QtCreator project file has been rearranged a little because it passes all the object files to the linker rather than using an archive library. Since the GNU linker is single pass; the object files need to be in a logical order with definitions appearing afer references to them. This was required to avoid a linking error. The lib/Makefile.linux has been enhanced to use the fortran compiler to locate the correct version of the Fortran library to use. This is necessary on the latest Linux distros because the unversioned symlink to compiler support libraries is no longer provided. This only an issue with mixed programming language links where the linker driver for one language has to link support libraraies for another language. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3532 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-07 19:09:13 -04:00
m_baseCall = Radio::base_callsign (m_config.my_callsign ());
m_optimizingProgress.setWindowModality (Qt::WindowModal);
m_optimizingProgress.setAutoReset (false);
m_optimizingProgress.setMinimumDuration (15000); // only show after 15s delay
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// Closedown.
connect (ui->actionExit, &QAction::triggered, this, &QMainWindow::close);
// parts of the rig error message box that are fixed
m_rigErrorMessageBox.setInformativeText (tr ("Do you want to reconfigure the radio interface?"));
m_rigErrorMessageBox.setDefaultButton (MessageBox::Ok);
Qt 5 Audio replaces PortAudio. Currently only Qt5 or above is known to work with this code. It may be possible to backport it to Qt4 if required. Audio output goes back to a separate thread to try and minimize stutters in streaming on Windows particularly. A crash on Linux due to mishandling of stereo audio output has been fixed and both left and right channels are now correctly synthesised with identical contents. Rigs are enumerated directly from hamlib API rather than running a sub process reading output of rigctl -l. This was initially done to get rid of some GUI thread blocking in the configuration dialog, but is generally a better way of doing it anyway. Some refactoring in MainWindow to accomodate the audio streaming, modulation and detecting classes. Exit handling for application refactored to use signals rather than brute force event loop exit. This was required to get correct thread shutdown semantics. The GUI update timer is now stopped during application shutdown which is necessary to stop crashes when shutting down gracefully with signals and window close() calls. There is an outstanding issue with Linux audio streams; the QAudio Input/Output classes create a new stream name each time a stream is started. This doesn't play well with PulseAudio utilities such as pavucontrol to set stream volume as settings are lost every tx period. I have tried to keep a single stream for all output but there are problems restarting it that haven't been resolved yet. The QtCreator project file has been rearranged a little because it passes all the object files to the linker rather than using an archive library. Since the GNU linker is single pass; the object files need to be in a logical order with definitions appearing afer references to them. This was required to avoid a linking error. The lib/Makefile.linux has been enhanced to use the fortran compiler to locate the correct version of the Fortran library to use. This is necessary on the latest Linux distros because the unversioned symlink to compiler support libraries is no longer provided. This only an issue with mixed programming language links where the linker driver for one language has to link support libraraies for another language. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3532 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-07 19:09:13 -04:00
// start audio thread and hook up slots & signals for shutdown management
// these objects need to be in the audio thread so that invoking
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
// their slots is done in a thread safe way
m_soundOutput->moveToThread (&m_audioThread);
m_modulator->moveToThread (&m_audioThread);
m_soundInput->moveToThread (&m_audioThread);
m_detector->moveToThread (&m_audioThread);
// hook up sound output stream slots & signals and disposal
connect (this, &MainWindow::initializeAudioOutputStream, m_soundOutput, &SoundOutput::setFormat);
connect (m_soundOutput, &SoundOutput::error, this, &MainWindow::showSoundOutError);
Improve audio device handling and error recovery where possible audio devices that disappear are not forgotten until the user selects another device, this should allow temporarily missing devices or forgetting to switch on devices before starting WSJT-X to be handled more cleanly. If all else fails, visiting the Settings dialog and clicking OK should get things going again. Note that we still do not have a reliable way of detecting failed audio out devices, in that case selecting another device and then returning to the original should work. Enumerating audio devices is expensive and on Linux may take many seconds per device. To avoid lengthy blocking behaviour until it is absolutely necessary, audio devices are not enumerated until one of the "Settings->Audio" device drop-down lists is opened. Elsewhere when devices must be discovered the enumeration stops as soon as the configured device is discovered. A status bar message is posted when audio devices are being enumerated as a reminder that the UI may block while this is happening. The message box warning about unaccounted-for input audio samples now only triggers when >5 seconds of audio appears to be missing or over provided. Hopefully this will make the warning less annoying for those that are using audio sources with high and/or variable latencies. A status bar message is still posted for any amount of audio input samples unaccounted for >1/5 second, this message appearing a lot should be considered as notification that there is a problem with the audio sub-system, system load is too high, or time synchronization is stepping the PC clock rather than adjusting the frequency to maintain monotonic clock ticks.
2020-09-20 13:20:16 -04:00
connect (m_soundOutput, &SoundOutput::error, &m_config, &Configuration::invalidate_audio_output_device);
// connect (m_soundOutput, &SoundOutput::status, this, &MainWindow::showStatusMessage);
connect (this, &MainWindow::outAttenuationChanged, m_soundOutput, &SoundOutput::setAttenuation);
connect (&m_audioThread, &QThread::finished, m_soundOutput, &QObject::deleteLater);
// hook up Modulator slots and disposal
connect (this, &MainWindow::transmitFrequency, m_modulator, &Modulator::setFrequency);
connect (this, &MainWindow::endTransmitMessage, m_modulator, &Modulator::stop);
connect (this, &MainWindow::tune, m_modulator, &Modulator::tune);
connect (this, &MainWindow::sendMessage, m_modulator, &Modulator::start);
connect (&m_audioThread, &QThread::finished, m_modulator, &QObject::deleteLater);
// hook up the audio input stream signals, slots and disposal
connect (this, &MainWindow::startAudioInputStream, m_soundInput, &SoundInput::start);
connect (this, &MainWindow::suspendAudioInputStream, m_soundInput, &SoundInput::suspend);
connect (this, &MainWindow::resumeAudioInputStream, m_soundInput, &SoundInput::resume);
connect (this, &MainWindow::reset_audio_input_stream, m_soundInput, &SoundInput::reset);
connect (this, &MainWindow::finished, m_soundInput, &SoundInput::stop);
connect(m_soundInput, &SoundInput::error, this, &MainWindow::showSoundInError);
Improve audio device handling and error recovery where possible audio devices that disappear are not forgotten until the user selects another device, this should allow temporarily missing devices or forgetting to switch on devices before starting WSJT-X to be handled more cleanly. If all else fails, visiting the Settings dialog and clicking OK should get things going again. Note that we still do not have a reliable way of detecting failed audio out devices, in that case selecting another device and then returning to the original should work. Enumerating audio devices is expensive and on Linux may take many seconds per device. To avoid lengthy blocking behaviour until it is absolutely necessary, audio devices are not enumerated until one of the "Settings->Audio" device drop-down lists is opened. Elsewhere when devices must be discovered the enumeration stops as soon as the configured device is discovered. A status bar message is posted when audio devices are being enumerated as a reminder that the UI may block while this is happening. The message box warning about unaccounted-for input audio samples now only triggers when >5 seconds of audio appears to be missing or over provided. Hopefully this will make the warning less annoying for those that are using audio sources with high and/or variable latencies. A status bar message is still posted for any amount of audio input samples unaccounted for >1/5 second, this message appearing a lot should be considered as notification that there is a problem with the audio sub-system, system load is too high, or time synchronization is stepping the PC clock rather than adjusting the frequency to maintain monotonic clock ticks.
2020-09-20 13:20:16 -04:00
connect(m_soundInput, &SoundInput::error, &m_config, &Configuration::invalidate_audio_input_device);
// connect(m_soundInput, &SoundInput::status, this, &MainWindow::showStatusMessage);
connect (&m_audioThread, &QThread::finished, m_soundInput, &QObject::deleteLater);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
connect (this, &MainWindow::finished, this, &MainWindow::close);
// hook up the detector signals, slots and disposal
connect (this, &MainWindow::FFTSize, m_detector, &Detector::setBlockSize);
connect(m_detector, &Detector::framesWritten, this, &MainWindow::dataSink);
connect (&m_audioThread, &QThread::finished, m_detector, &QObject::deleteLater);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
// setup the waterfall
connect(m_wideGraph.data (), SIGNAL(freezeDecode2(int)),this,SLOT(freezeDecode(int)));
connect(m_wideGraph.data (), SIGNAL(f11f12(int)),this,SLOT(bumpFqso(int)));
connect(m_wideGraph.data (), SIGNAL(setXIT2(int)),this,SLOT(setXIT(int)));
connect (m_fastGraph.data (), &FastGraph::fastPick, this, &MainWindow::fastPick);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
connect (this, &MainWindow::finished, m_wideGraph.data (), &WideGraph::close);
connect (this, &MainWindow::finished, m_echoGraph.data (), &EchoGraph::close);
connect (this, &MainWindow::finished, m_fastGraph.data (), &FastGraph::close);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
// setup the log QSO dialog
connect (m_logDlg.data (), &LogQSO::acceptQSO, this, &MainWindow::acceptQSO);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
connect (this, &MainWindow::finished, m_logDlg.data (), &LogQSO::close);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
// hook up the log book
connect (&m_logBook, &LogBook::finished_loading, [this] (int record_count, QString const& error) {
if (error.size ())
{
MessageBox::warning_message (this, tr ("Error Scanning ADIF Log"), error);
}
else
{
showStatusMessage (tr ("Scanned ADIF log, %1 worked before records created").arg (record_count));
}
});
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
// Network message handlers
m_messageClient->enable (m_config.accept_udp_requests ());
connect (m_messageClient, &MessageClient::clear_decodes, [this] (quint8 window) {
++window;
if (window & 1)
{
ui->decodedTextBrowser->erase ();
}
if (window & 2)
{
ui->decodedTextBrowser2->erase ();
}
});
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
connect (m_messageClient, &MessageClient::reply, this, &MainWindow::replyToCQ);
connect (m_messageClient, &MessageClient::close, this, &MainWindow::close);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
connect (m_messageClient, &MessageClient::replay, this, &MainWindow::replayDecodes);
connect (m_messageClient, &MessageClient::location, this, &MainWindow::locationChange);
connect (m_messageClient, &MessageClient::halt_tx, [this] (bool auto_only) {
if (auto_only) {
if (ui->autoButton->isChecked ()) {
ui->autoButton->click();
}
} else {
ui->stopTxButton->click();
}
});
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
connect (m_messageClient, &MessageClient::error, this, &MainWindow::networkError);
connect (m_messageClient, &MessageClient::free_text, [this] (QString const& text, bool send) {
tx_watchdog (false);
// send + non-empty text means set and send the free text
// message, !send + non-empty text means set the current free
// text message, send + empty text means send the current free
// text message without change, !send + empty text means clear
// the current free text message
if (0 == ui->tabWidget->currentIndex ()) {
if (!text.isEmpty ()) {
ui->tx5->setCurrentText (text);
}
if (send) {
ui->txb5->click ();
} else if (text.isEmpty ()) {
ui->tx5->setCurrentText (text);
}
}
QApplication::alert (this);
});
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
connect (m_messageClient, &MessageClient::highlight_callsign, ui->decodedTextBrowser, &DisplayText::highlight_callsign);
connect (m_messageClient, &MessageClient::switch_configuration, m_multi_settings, &MultiSettings::select_configuration);
connect (m_messageClient, &MessageClient::configure, this, &MainWindow::remote_configure);
// Hook up WSPR band hopping
connect (ui->band_hopping_schedule_push_button, &QPushButton::clicked
, &m_WSPR_band_hopping, &WSPRBandHopping::show_dialog);
connect (ui->sbTxPercent, static_cast<void (QSpinBox::*) (int)> (&QSpinBox::valueChanged)
, &m_WSPR_band_hopping, &WSPRBandHopping::set_tx_percent);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
on_EraseButton_clicked ();
QActionGroup* modeGroup = new QActionGroup(this);
2020-07-23 13:51:05 -04:00
ui->actionFST4->setActionGroup(modeGroup);
ui->actionFST4W->setActionGroup(modeGroup);
ui->actionFT4->setActionGroup(modeGroup);
ui->actionFT8->setActionGroup(modeGroup);
ui->actionJT9->setActionGroup(modeGroup);
ui->actionJT65->setActionGroup(modeGroup);
ui->actionJT9_JT65->setActionGroup(modeGroup);
ui->actionJT4->setActionGroup(modeGroup);
ui->actionWSPR->setActionGroup(modeGroup);
ui->actionEcho->setActionGroup(modeGroup);
ui->actionISCAT->setActionGroup(modeGroup);
ui->actionMSK144->setActionGroup(modeGroup);
ui->actionQRA64->setActionGroup(modeGroup);
ui->actionFreqCal->setActionGroup(modeGroup);
QActionGroup* saveGroup = new QActionGroup(this);
ui->actionNone->setActionGroup(saveGroup);
ui->actionSave_decoded->setActionGroup(saveGroup);
ui->actionSave_all->setActionGroup(saveGroup);
QActionGroup* DepthGroup = new QActionGroup(this);
ui->actionQuickDecode->setActionGroup(DepthGroup);
ui->actionMediumDecode->setActionGroup(DepthGroup);
ui->actionDeepestDecode->setActionGroup(DepthGroup);
connect (ui->download_samples_action, &QAction::triggered, [this] () {
if (!m_sampleDownloader)
{
m_sampleDownloader.reset (new SampleDownloader {m_settings, &m_config, &m_network_manager, this});
}
m_sampleDownloader->show ();
});
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
connect (ui->view_phase_response_action, &QAction::triggered, [this] () {
if (!m_equalizationToolsDialog)
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
{
m_equalizationToolsDialog.reset (new EqualizationToolsDialog {m_settings, m_config.writeable_data_dir (), m_phaseEqCoefficients, this});
connect (m_equalizationToolsDialog.data (), &EqualizationToolsDialog::phase_equalization_changed,
[this] (QVector<double> const& coeffs) {
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
m_phaseEqCoefficients = coeffs;
});
}
m_equalizationToolsDialog->show ();
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
});
connect (&m_config.lotw_users (), &LotWUsers::LotW_users_error, this, [this] (QString const& reason) {
MessageBox::warning_message (this, tr ("Error Loading LotW Users Data"), reason);
}, Qt::QueuedConnection);
QButtonGroup* txMsgButtonGroup = new QButtonGroup {this};
txMsgButtonGroup->addButton(ui->txrb1,1);
txMsgButtonGroup->addButton(ui->txrb2,2);
txMsgButtonGroup->addButton(ui->txrb3,3);
txMsgButtonGroup->addButton(ui->txrb4,4);
txMsgButtonGroup->addButton(ui->txrb5,5);
txMsgButtonGroup->addButton(ui->txrb6,6);
set_dateTimeQSO(-1);
connect(txMsgButtonGroup,SIGNAL(buttonClicked(int)),SLOT(set_ntx(int)));
connect (ui->decodedTextBrowser, &DisplayText::selectCallsign, this, &MainWindow::doubleClickOnCall2);
connect (ui->decodedTextBrowser2, &DisplayText::selectCallsign, this, &MainWindow::doubleClickOnCall);
connect (ui->textBrowser4, &DisplayText::selectCallsign, this, &MainWindow::doubleClickOnFoxQueue);
connect (ui->decodedTextBrowser, &DisplayText::erased, this, &MainWindow::band_activity_cleared);
connect (ui->decodedTextBrowser2, &DisplayText::erased, this, &MainWindow::rx_frequency_activity_cleared);
// initialize decoded text font and hook up font change signals
// defer initialization until after construction otherwise menu
// fonts do not get set
QTimer::singleShot (0, this, SLOT (initialize_fonts ()));
connect (&m_config, &Configuration::text_font_changed, [this] (QFont const& font) {
set_application_font (font);
});
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
connect (&m_config, &Configuration::decoded_text_font_changed, [this] (QFont const& font) {
setDecodedTextFont (font);
});
setWindowTitle (program_title ());
connect(&proc_jt9, &QProcess::readyReadStandardOutput, this, &MainWindow::readFromStdout);
2020-05-06 21:56:57 -04:00
#if QT_VERSION < QT_VERSION_CHECK (5, 6, 0)
connect(&proc_jt9, static_cast<void (QProcess::*) (QProcess::ProcessError)> (&QProcess::error),
[this] (QProcess::ProcessError error) {
subProcessError (&proc_jt9, error);
});
2020-05-06 21:56:57 -04:00
#else
2020-06-13 11:04:41 -04:00
connect(&proc_jt9, &QProcess::errorOccurred, [this] (QProcess::ProcessError error) {
subProcessError (&proc_jt9, error);
});
2020-05-06 21:56:57 -04:00
#endif
connect(&proc_jt9, static_cast<void (QProcess::*) (int, QProcess::ExitStatus)> (&QProcess::finished),
[this] (int exitCode, QProcess::ExitStatus status) {
if (subProcessFailed (&proc_jt9, exitCode, status))
{
m_valid = false; // ensures exit if still
// constructing
QTimer::singleShot (0, this, SLOT (close ()));
}
});
2020-06-13 11:04:41 -04:00
connect(&p1, &QProcess::started, [this] () {
2020-07-26 19:51:12 -04:00
showStatusMessage (QString {"Started: %1 \"%2\""}.arg (p1.program ()).arg (p1.arguments ().join ("\" \"")));
2020-06-13 11:04:41 -04:00
});
connect(&p1, &QProcess::readyReadStandardOutput, this, &MainWindow::p1ReadFromStdout);
2020-05-06 21:56:57 -04:00
#if QT_VERSION < QT_VERSION_CHECK (5, 6, 0)
connect(&p1, static_cast<void (QProcess::*) (QProcess::ProcessError)> (&QProcess::error),
[this] (QProcess::ProcessError error) {
subProcessError (&p1, error);
});
2020-05-06 21:56:57 -04:00
#else
2020-06-13 11:04:41 -04:00
connect(&p1, &QProcess::errorOccurred, [this] (QProcess::ProcessError error) {
subProcessError (&p1, error);
});
2020-05-06 21:56:57 -04:00
#endif
connect(&p1, static_cast<void (QProcess::*) (int, QProcess::ExitStatus)> (&QProcess::finished),
[this] (int exitCode, QProcess::ExitStatus status) {
if (subProcessFailed (&p1, exitCode, status))
{
m_valid = false; // ensures exit if still
// constructing
QTimer::singleShot (0, this, SLOT (close ()));
}
});
2020-05-06 21:56:57 -04:00
#if QT_VERSION < QT_VERSION_CHECK (5, 6, 0)
connect(&p3, static_cast<void (QProcess::*) (QProcess::ProcessError)> (&QProcess::error),
[this] (QProcess::ProcessError error) {
2020-05-06 21:56:57 -04:00
#else
2020-06-13 11:04:41 -04:00
connect(&p3, &QProcess::errorOccurred, [this] (QProcess::ProcessError error) {
2020-05-06 21:56:57 -04:00
#endif
2020-07-26 19:51:12 -04:00
#if !defined(Q_OS_WIN)
if (QProcess::FailedToStart != error)
2020-07-26 19:51:12 -04:00
#else
if (QProcess::Crashed != error)
#endif
{
subProcessError (&p3, error);
}
});
2020-06-13 11:04:41 -04:00
connect(&p3, &QProcess::started, [this] () {
2020-07-26 19:51:12 -04:00
showStatusMessage (QString {"Started: %1 \"%2\""}.arg (p3.program ()).arg (p3.arguments ().join ("\" \"")));
2020-06-13 11:04:41 -04:00
});
connect(&p3, static_cast<void (QProcess::*) (int, QProcess::ExitStatus)> (&QProcess::finished),
[this] (int exitCode, QProcess::ExitStatus status) {
#if defined(Q_OS_WIN)
// We forgo detecting user_hardware failures with exit
// code 1 on Windows. This is because we use CMD.EXE to
// run the executable. CMD.EXE returns exit code 1 when it
// can't find the target executable.
if (exitCode != 1) // CMD.EXE couldn't find file to execute
#else
// We forgo detecting user_hardware failures with exit
// code 127 non-Windows. This is because we use /bin/sh to
// run the executable. /bin/sh returns exit code 127 when it
// can't find the target executable.
if (exitCode != 127) // /bin/sh couldn't find file to execute
#endif
{
subProcessFailed (&p3, exitCode, status);
}
});
// hook up save WAV file exit handling
connect (&m_saveWAVWatcher, &QFutureWatcher<QString>::finished, [this] {
// extract the promise from the future
auto const& result = m_saveWAVWatcher.future ().result ();
if (!result.isEmpty ()) // error
{
MessageBox::critical_message (this, tr("Error Writing WAV File"), result);
}
});
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// Hook up working frequencies.
ui->bandComboBox->setModel (m_config.frequencies ());
ui->bandComboBox->setModelColumn (FrequencyList_v2::frequency_mhz_column);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// combo box drop down width defaults to the line edit + decorator width,
// here we change that to the column width size hint of the model column
ui->bandComboBox->view ()->setMinimumWidth (ui->bandComboBox->view ()->sizeHintForColumn (FrequencyList_v2::frequency_mhz_column));
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// Enable live band combo box entry validation and action.
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
auto band_validator = new LiveFrequencyValidator {ui->bandComboBox
, m_config.bands ()
, m_config.frequencies ()
, &m_freqNominal
, this};
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
ui->bandComboBox->setValidator (band_validator);
// Hook up signals.
connect (band_validator, &LiveFrequencyValidator::valid, this, &MainWindow::band_changed);
connect (ui->bandComboBox->lineEdit (), &QLineEdit::textEdited, [this] (QString const&) {m_bandEdited = true;});
// hook up configuration signals
connect (&m_config, &Configuration::transceiver_update, this, &MainWindow::handle_transceiver_update);
connect (&m_config, &Configuration::transceiver_failure, this, &MainWindow::handle_transceiver_failure);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
connect (&m_config, &Configuration::udp_server_changed, m_messageClient, &MessageClient::set_server);
connect (&m_config, &Configuration::udp_server_port_changed, m_messageClient, &MessageClient::set_server_port);
connect (&m_config, &Configuration::udp_TTL_changed, m_messageClient, &MessageClient::set_TTL);
connect (&m_config, &Configuration::accept_udp_requests_changed, m_messageClient, &MessageClient::enable);
connect (&m_config, &Configuration::enumerating_audio_devices, [this] () {
showStatusMessage (tr ("Enumerating audio devices"));
});
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// set up configurations menu
connect (m_multi_settings, &MultiSettings::configurationNameChanged, [this] (QString const& name) {
if ("Default" != name) {
config_label.setText (name);
config_label.show ();
}
else {
config_label.hide ();
}
statusUpdate ();
});
m_multi_settings->create_menu_actions (this, ui->menuConfig);
m_configurations_button = m_rigErrorMessageBox.addButton (tr ("Configurations...")
, QMessageBox::ActionRole);
// set up message text validators
ui->tx1->setValidator (new QRegExpValidator {message_alphabet, this});
ui->tx2->setValidator (new QRegExpValidator {message_alphabet, this});
ui->tx3->setValidator (new QRegExpValidator {message_alphabet, this});
ui->tx4->setValidator (new QRegExpValidator {message_alphabet, this});
ui->tx5->setValidator (new QRegExpValidator {message_alphabet, this});
ui->tx6->setValidator (new QRegExpValidator {message_alphabet, this});
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// Free text macros model to widget hook up.
ui->tx5->setModel (m_config.macros ());
connect (ui->tx5->lineEdit(), &QLineEdit::editingFinished,
[this] () {on_tx5_currentTextChanged (ui->tx5->lineEdit()->text());});
connect(&m_guiTimer, &QTimer::timeout, this, &MainWindow::guiUpdate);
m_guiTimer.start(100); //### Don't change the 100 ms! ###
Qt 5 Audio replaces PortAudio. Currently only Qt5 or above is known to work with this code. It may be possible to backport it to Qt4 if required. Audio output goes back to a separate thread to try and minimize stutters in streaming on Windows particularly. A crash on Linux due to mishandling of stereo audio output has been fixed and both left and right channels are now correctly synthesised with identical contents. Rigs are enumerated directly from hamlib API rather than running a sub process reading output of rigctl -l. This was initially done to get rid of some GUI thread blocking in the configuration dialog, but is generally a better way of doing it anyway. Some refactoring in MainWindow to accomodate the audio streaming, modulation and detecting classes. Exit handling for application refactored to use signals rather than brute force event loop exit. This was required to get correct thread shutdown semantics. The GUI update timer is now stopped during application shutdown which is necessary to stop crashes when shutting down gracefully with signals and window close() calls. There is an outstanding issue with Linux audio streams; the QAudio Input/Output classes create a new stream name each time a stream is started. This doesn't play well with PulseAudio utilities such as pavucontrol to set stream volume as settings are lost every tx period. I have tried to keep a single stream for all output but there are problems restarting it that haven't been resolved yet. The QtCreator project file has been rearranged a little because it passes all the object files to the linker rather than using an archive library. Since the GNU linker is single pass; the object files need to be in a logical order with definitions appearing afer references to them. This was required to avoid a linking error. The lib/Makefile.linux has been enhanced to use the fortran compiler to locate the correct version of the Fortran library to use. This is necessary on the latest Linux distros because the unversioned symlink to compiler support libraries is no longer provided. This only an issue with mixed programming language links where the linker driver for one language has to link support libraraies for another language. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3532 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-07 19:09:13 -04:00
ptt0Timer.setSingleShot(true);
connect(&ptt0Timer, &QTimer::timeout, this, &MainWindow::stopTx2);
ptt1Timer.setSingleShot(true);
connect(&ptt1Timer, &QTimer::timeout, this, &MainWindow::startTx2);
p1Timer.setSingleShot(true);
connect(&p1Timer, &QTimer::timeout, this, &MainWindow::startP1);
logQSOTimer.setSingleShot(true);
connect(&logQSOTimer, &QTimer::timeout, this, &MainWindow::on_logQSOButton_clicked);
tuneButtonTimer.setSingleShot(true);
connect(&tuneButtonTimer, &QTimer::timeout, this, &MainWindow::on_stopTxButton_clicked);
tuneATU_Timer.setSingleShot(true);
connect(&tuneATU_Timer, &QTimer::timeout, this, &MainWindow::stopTuneATU);
killFileTimer.setSingleShot(true);
connect(&killFileTimer, &QTimer::timeout, this, &MainWindow::killFile);
uploadTimer.setSingleShot(true);
connect(&uploadTimer, &QTimer::timeout, [this] () {uploadWSPRSpots ();});
TxAgainTimer.setSingleShot(true);
connect(&TxAgainTimer, SIGNAL(timeout()), this, SLOT(TxAgain()));
connect(m_wideGraph.data (), SIGNAL(setFreq3(int,int)),this,
SLOT(setFreq4(int,int)));
decodeBusy(false);
m_msg[0][0]=0;
ui->labDXped->setVisible(false);
ui->labDXped->setStyleSheet("QLabel {background-color: red; color: white;}");
ui->labNextCall->setText("");
ui->labNextCall->setVisible(false);
ui->labNextCall->setToolTip(""); //### Possibly temporary ? ###
char const * const power[] = {"1 mW","2 mW","5 mW","10 mW","20 mW","50 mW","100 mW","200 mW","500 mW",
"1 W","2 W","5 W","10 W","20 W","50 W","100 W","200 W","500 W","1 kW"};
for(auto i = 0u; i < sizeof power / sizeof power[0]; ++i) { //Initialize dBm values
auto dBm = int ((10. * i / 3.) + .5);
ui->TxPowerComboBox->addItem (QString {"%1 dBm %2"}.arg (dBm).arg (power[i]), dBm);
}
m_dateTimeRcvdRR73=QDateTime::currentDateTimeUtc();
m_dateTimeSentTx3=QDateTime::currentDateTimeUtc();
ui->labAz->setStyleSheet("border: 0px;");
2019-01-09 08:47:29 -05:00
ui->labAz->setText("");
2020-05-19 07:15:58 -04:00
auto t = "UTC dB DT Freq " + tr ("Message");
ui->lh_decodes_headings_label->setText(t);
ui->rh_decodes_headings_label->setText(t);
readSettings(); //Restore user's setup parameters
m_audioThread.start (m_audioThreadPriority);
#ifdef WIN32
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
if (!m_multiple)
{
while(true)
{
int iret=killbyname("jt9.exe");
if(iret == 603) break;
if(iret != 0)
MessageBox::warning_message (this, tr ("Error Killing jt9.exe Process")
, tr ("KillByName return code: %1")
.arg (iret));
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
#endif
{
//delete any .quit file that might have been left lying around
//since its presence will cause jt9 to exit a soon as we start it
//and decodes will hang
QFile quitFile {m_config.temp_dir ().absoluteFilePath (".quit")};
while (quitFile.exists ())
{
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
if (!quitFile.remove ())
{
MessageBox::query_message (this, tr ("Error removing \"%1\"").arg (quitFile.fileName ())
, tr ("Click OK to retry"));
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
}
to_jt9(0,0,0); //initialize IPC variables
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
QStringList jt9_args {
"-s", QApplication::applicationName () // shared memory key,
// includes rig
#ifdef NDEBUG
, "-w", "1" //FFTW patience - release
#else
, "-w", "1" //FFTW patience - debug builds for speed
#endif
// The number of threads for FFTW specified here is chosen as
// three because that gives the best throughput of the large
// FFTs used in jt9. The count is the minimum of (the number
// available CPU threads less one) and three. This ensures that
// there is always at least one free CPU thread to run the other
// mode decoder in parallel.
, "-m", QString::number (qMin (qMax (QThread::idealThreadCount () - 1, 1), 3)) //FFTW threads
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
, "-e", QDir::toNativeSeparators (m_appDir)
, "-a", QDir::toNativeSeparators (m_config.writeable_data_dir ().absolutePath ())
, "-t", QDir::toNativeSeparators (m_config.temp_dir ().absolutePath ())
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
};
QProcessEnvironment new_env {m_env};
new_env.insert ("OMP_STACKSIZE", "4M");
proc_jt9.setProcessEnvironment (new_env);
proc_jt9.start(QDir::toNativeSeparators (m_appDir) + QDir::separator () +
"jt9", jt9_args, QIODevice::ReadWrite | QIODevice::Unbuffered);
QString fname {QDir::toNativeSeparators(m_config.writeable_data_dir ().absoluteFilePath ("wsjtx_wisdom.dat"))};
QByteArray cfname=fname.toLocal8Bit();
fftwf_import_wisdom_from_filename(cfname);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
//genStdMsgs(m_rpt);
m_ntx = 6;
ui->txrb6->setChecked(true);
connect (&m_wav_future_watcher, &QFutureWatcher<void>::finished, this, &MainWindow::diskDat);
connect(&watcher3, SIGNAL(finished()),this,SLOT(fast_decode_done()));
if (!m_config.audio_input_device ().isNull ())
{
Q_EMIT startAudioInputStream (m_config.audio_input_device ()
, rx_chunk_size * m_downSampleFactor
, m_detector, m_downSampleFactor, m_config.audio_input_channel ());
}
if (!m_config.audio_output_device ().isNull ())
{
Q_EMIT initializeAudioOutputStream (m_config.audio_output_device ()
, AudioDevice::Mono == m_config.audio_output_channel () ? 1 : 2
, tx_audio_buffer_size);
}
Q_EMIT transmitFrequency (ui->TxFreqSpinBox->value () - m_XIT);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
enable_DXCC_entity (m_config.DXCC ()); // sets text window proportions and (re)inits the logbook
// this must be done before initializing the mode as some modes need
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
// to turn off split on the rig e.g. WSPR
m_config.transceiver_online ();
bool vhf {m_config.enable_VHF_features ()};
ui->txFirstCheckBox->setChecked(m_txFirst);
morse_(const_cast<char *> (m_config.my_callsign ().toLatin1().constData()),
const_cast<int *> (icw), &m_ncw, m_config.my_callsign ().length());
on_actionWide_Waterfall_triggered();
ui->cbShMsgs->setChecked(m_bShMsgs);
ui->cbSWL->setChecked(m_bSWL);
if(m_bFast9) m_bFastMode=true;
ui->cbFast9->setChecked(m_bFast9 or m_bFastMode);
set_mode (m_mode);
if(m_mode=="Echo") monitor(false); //Don't auto-start Monitor in Echo mode.
ui->sbSubmode->setValue (vhf ? m_nSubMode : 0); //Submodes require VHF features
if(m_mode=="ISCAT" and !vhf) mode_label.setText("ISCAT A");
if(m_mode=="MSK144") {
Q_EMIT transmitFrequency (1000.0);
} else {
Q_EMIT transmitFrequency (ui->TxFreqSpinBox->value() - m_XIT);
}
m_saveDecoded=ui->actionSave_decoded->isChecked();
m_saveAll=ui->actionSave_all->isChecked();
ui->TxPowerComboBox->setCurrentIndex(int(.3 * m_dBm + .2));
ui->cbUploadWSPR_Spots->setChecked(m_uploadWSPRSpots);
if((m_ndepth&7)==1) ui->actionQuickDecode->setChecked(true);
if((m_ndepth&7)==2) ui->actionMediumDecode->setChecked(true);
if((m_ndepth&7)==3) ui->actionDeepestDecode->setChecked(true);
ui->actionInclude_averaging->setChecked(m_ndepth&16);
ui->actionInclude_correlation->setChecked(m_ndepth&32);
ui->actionEnable_AP_DXcall->setChecked(m_ndepth&64);
m_UTCdisk=-1;
m_fCPUmskrtd=0.0;
m_bFastDone=false;
m_bAltV=false;
m_bNoMoreFiles=false;
m_bDoubleClicked=false;
m_bCallingCQ=false;
m_bCheckedContest=false;
m_bDisplayedOnce=false;
m_wait=0;
m_isort=-3;
m_max_dB=70;
m_CQtype="CQ";
fixStop();
VHF_features_enabled(m_config.enable_VHF_features());
m_wideGraph->setVHF(m_config.enable_VHF_features());
connect( wsprNet, SIGNAL(uploadStatus(QString)), this, SLOT(uploadResponse(QString)));
statusChanged();
m_fastGraph->setMode(m_mode);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
connect (&minuteTimer, &QTimer::timeout, this, &MainWindow::on_the_minute);
minuteTimer.setSingleShot (true);
minuteTimer.start (ms_minute_error () + 60 * 1000);
connect (&splashTimer, &QTimer::timeout, this, &MainWindow::splash_done);
splashTimer.setSingleShot (true);
splashTimer.start (20 * 1000);
2018-12-09 19:47:31 -05:00
if(QCoreApplication::applicationVersion().contains("-devel") or
QCoreApplication::applicationVersion().contains("-rc")) {
QTimer::singleShot (0, this, SLOT (not_GA_warning_message ()));
2018-12-09 19:47:31 -05:00
}
ui->pbBestSP->setVisible(m_mode=="FT4");
if(!ui->cbMenus->isChecked()) {
ui->cbMenus->setChecked(true);
ui->cbMenus->setChecked(false);
}
// this must be the last statement of constructor
if (!m_valid) throw std::runtime_error {"Fatal initialization exception"};
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
void MainWindow::not_GA_warning_message ()
{
2020-11-14 20:12:55 -05:00
MessageBox::critical_message (this,
"This is a pre-release version of WSJT-X 2.3.0 made\n"
"available for testing purposes. By design it will\n"
"be nonfunctional after 0000 UTC on Jan 19, 2021.");
auto now = QDateTime::currentDateTimeUtc ();
if (now >= QDateTime {{2021, 1, 19}, {0, 0}, Qt::UTC}) {
Q_EMIT finished ();
}
}
void MainWindow::initialize_fonts ()
{
set_application_font (m_config.text_font ());
setDecodedTextFont (m_config.decoded_text_font ());
}
void MainWindow::splash_done ()
{
m_splash && m_splash->close ();
}
void MainWindow::on_the_minute ()
{
if (minuteTimer.isSingleShot ())
{
minuteTimer.setSingleShot (false);
minuteTimer.start (60 * 1000); // run free
}
else
{
auto const& ms_error = ms_minute_error ();
if (qAbs (ms_error) > 1000) // keep drift within +-1s
{
minuteTimer.setSingleShot (true);
minuteTimer.start (ms_error + 60 * 1000);
}
}
2020-07-23 13:51:05 -04:00
if (m_config.watchdog () && m_mode!="WSPR" && m_mode!="FST4W") {
if (m_idleMinutes < m_config.watchdog ()) ++m_idleMinutes;
update_watchdog_label ();
} else {
tx_watchdog (false);
}
}
//--------------------------------------------------- MainWindow destructor
MainWindow::~MainWindow()
{
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_astroWidget.reset ();
QString fname {QDir::toNativeSeparators(m_config.writeable_data_dir ().absoluteFilePath ("wsjtx_wisdom.dat"))};
QByteArray cfname=fname.toLocal8Bit();
fftwf_export_wisdom_to_filename(cfname);
m_audioThread.quit ();
m_audioThread.wait ();
remove_child_from_event_filter (this);
}
//-------------------------------------------------------- writeSettings()
void MainWindow::writeSettings()
{
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->beginGroup("MainWindow");
m_settings->setValue ("geometry", saveGeometry ());
m_settings->setValue ("geometryNoControls", m_geometryNoControls);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->setValue ("state", saveState ());
m_settings->setValue("MRUdir", m_path);
m_settings->setValue("TxFirst",m_txFirst);
m_settings->setValue("DXcall",ui->dxCallEntry->text());
m_settings->setValue("DXgrid",ui->dxGridEntry->text());
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_settings->setValue ("AstroDisplayed", m_astroWidget && m_astroWidget->isVisible());
m_settings->setValue ("MsgAvgDisplayed", m_msgAvgWidget && m_msgAvgWidget->isVisible ());
m_settings->setValue ("FoxLogDisplayed", m_foxLogWindow && m_foxLogWindow->isVisible ());
m_settings->setValue ("ContestLogDisplayed", m_contestLogWindow && m_contestLogWindow->isVisible ());
m_settings->setValue("ShowMenus",ui->cbMenus->isChecked());
m_settings->setValue("CallFirst",ui->cbFirst->isChecked());
m_settings->setValue("HoundSort",ui->comboBoxHoundSort->currentIndex());
m_settings->setValue("FoxNlist",ui->sbNlist->value());
m_settings->setValue("FoxNslots",ui->sbNslots->value());
m_settings->setValue("FoxMaxDB_v2",ui->sbMax_dB->value()); // original key abandoned
m_settings->setValue ("SerialNumber",ui->sbSerialNumber->value ());
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->endGroup();
m_settings->beginGroup("Common");
m_settings->setValue("Mode",m_mode);
m_settings->setValue("ModeTx",m_modeTx);
m_settings->setValue("SaveNone",ui->actionNone->isChecked());
m_settings->setValue("SaveDecoded",ui->actionSave_decoded->isChecked());
m_settings->setValue("SaveAll",ui->actionSave_all->isChecked());
m_settings->setValue("NDepth",m_ndepth);
m_settings->setValue("RxFreq",ui->RxFreqSpinBox->value());
m_settings->setValue("TxFreq",ui->TxFreqSpinBox->value());
m_settings->setValue("WSPRfreq",ui->WSPRfreqSpinBox->value());
m_settings->setValue("FST4W_RxFreq",ui->sbFST4W_RxFreq->value());
m_settings->setValue("FST4W_FTol",ui->sbFST4W_FTol->value());
m_settings->setValue("FST4_FLow",ui->sbF_Low->value());
m_settings->setValue("FST4_FHigh",ui->sbF_High->value());
m_settings->setValue("SubMode",ui->sbSubmode->value());
m_settings->setValue("DTtol",m_DTtol);
m_settings->setValue("Ftol", ui->sbFtol->value ());
m_settings->setValue("MinSync",m_minSync);
m_settings->setValue ("AutoSeq", ui->cbAutoSeq->isChecked ());
m_settings->setValue ("RxAll", ui->cbRxAll->isChecked ());
m_settings->setValue("ShMsgs",m_bShMsgs);
m_settings->setValue("SWL",ui->cbSWL->isChecked());
m_settings->setValue ("DialFreq", QVariant::fromValue(m_lastMonitoredFrequency));
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->setValue("OutAttenuation", ui->outAttenuation->value ());
m_settings->setValue("NoSuffix",m_noSuffix);
m_settings->setValue("GUItab",ui->tabWidget->currentIndex());
m_settings->setValue("OutBufSize",outBufSize);
m_settings->setValue ("HoldTxFreq", ui->cbHoldTxFreq->isChecked ());
m_settings->setValue("PctTx", ui->sbTxPercent->value ());
m_settings->setValue("RoundRobin",ui->RoundRobin->currentText());
m_settings->setValue("dBm",m_dBm);
m_settings->setValue("RR73",m_send_RR73);
m_settings->setValue ("WSPRPreferType1", ui->WSPR_prefer_type_1_check_box->isChecked ());
m_settings->setValue("UploadSpots",m_uploadWSPRSpots);
m_settings->setValue("NoOwnCall",ui->cbNoOwnCall->isChecked());
m_settings->setValue ("BandHopping", ui->band_hopping_group_box->isChecked ());
m_settings->setValue ("TRPeriod", ui->sbTR->value ());
2020-07-23 13:51:05 -04:00
m_settings->setValue ("TRPeriod_FST4W", ui->sbTR_FST4W->value ());
m_settings->setValue("FastMode",m_bFastMode);
m_settings->setValue("Fast9",m_bFast9);
m_settings->setValue ("CQTxfreq", ui->sbCQTxFreq->value ());
m_settings->setValue("pwrBandTxMemory",m_pwrBandTxMemory);
m_settings->setValue("pwrBandTuneMemory",m_pwrBandTuneMemory);
m_settings->setValue ("FT8AP", ui->actionEnable_AP_FT8->isChecked ());
m_settings->setValue ("JT65AP", ui->actionEnable_AP_JT65->isChecked ());
m_settings->setValue("SplitterState",ui->splitter->saveState());
m_settings->setValue("Blanker",ui->sbNB->value());
m_settings->setValue ("SWLView", ui->actionSWL_Mode->isChecked ());
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
{
QList<QVariant> coeffs; // suitable for QSettings
for (auto const& coeff : m_phaseEqCoefficients)
{
coeffs << coeff;
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
}
m_settings->setValue ("PhaseEqualizationCoefficients", QVariant {coeffs});
}
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->endGroup();
}
//---------------------------------------------------------- readSettings()
void MainWindow::readSettings()
{
ui->cbAutoSeq->setVisible(false);
ui->cbFirst->setVisible(false);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->beginGroup("MainWindow");
restoreGeometry (m_settings->value ("geometry", saveGeometry ()).toByteArray ());
m_geometryNoControls = m_settings->value ("geometryNoControls",saveGeometry()).toByteArray();
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
restoreState (m_settings->value ("state", saveState ()).toByteArray ());
ui->dxCallEntry->setText (m_settings->value ("DXcall", QString {}).toString ());
ui->dxGridEntry->setText (m_settings->value ("DXgrid", QString {}).toString ());
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_path = m_settings->value("MRUdir", m_config.save_directory ().absolutePath ()).toString ();
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_txFirst = m_settings->value("TxFirst",false).toBool();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
auto displayAstro = m_settings->value ("AstroDisplayed", false).toBool ();
auto displayMsgAvg = m_settings->value ("MsgAvgDisplayed", false).toBool ();
auto displayFoxLog = m_settings->value ("FoxLogDisplayed", false).toBool ();
auto displayContestLog = m_settings->value ("ContestLogDisplayed", false).toBool ();
ui->cbMenus->setChecked(m_settings->value("ShowMenus",true).toBool());
ui->cbFirst->setChecked(m_settings->value("CallFirst",true).toBool());
ui->comboBoxHoundSort->setCurrentIndex(m_settings->value("HoundSort",3).toInt());
ui->sbNlist->setValue(m_settings->value("FoxNlist",12).toInt());
m_Nslots=m_settings->value("FoxNslots",5).toInt();
ui->sbNslots->setValue(m_Nslots);
ui->sbMax_dB->setValue(m_settings->value("FoxMaxDB_v2",70).toInt());
ui->sbSerialNumber->setValue (m_settings->value ("SerialNumber", 1).toInt ());
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->endGroup();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// do this outside of settings group because it uses groups internally
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
ui->actionAstronomical_data->setChecked (displayAstro);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_settings->beginGroup("Common");
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_mode=m_settings->value("Mode","JT9").toString();
m_modeTx=m_settings->value("ModeTx","JT9").toString();
if(m_modeTx.mid(0,3)=="JT9") ui->pbTxMode->setText("Tx JT9 @");
if(m_modeTx=="JT65") ui->pbTxMode->setText("Tx JT65 #");
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
ui->actionNone->setChecked(m_settings->value("SaveNone",true).toBool());
ui->actionSave_decoded->setChecked(m_settings->value("SaveDecoded",false).toBool());
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
ui->actionSave_all->setChecked(m_settings->value("SaveAll",false).toBool());
ui->RxFreqSpinBox->setValue(0); // ensure a change is signaled
ui->RxFreqSpinBox->setValue(m_settings->value("RxFreq",1500).toInt());
ui->sbFST4W_RxFreq->setValue(0);
ui->sbFST4W_RxFreq->setValue(m_settings->value("FST4W_RxFreq",1500).toInt());
ui->sbF_Low->setValue(m_settings->value("FST4_FLow",600).toInt());
ui->sbF_High->setValue(m_settings->value("FST4_FHigh",1400).toInt());
m_nSubMode=m_settings->value("SubMode",0).toInt();
ui->sbFtol->setValue (m_settings->value("Ftol", 50).toInt());
ui->sbFST4W_FTol->setValue(m_settings->value("FST4W_FTol",100).toInt());
m_minSync=m_settings->value("MinSync",0).toInt();
ui->syncSpinBox->setValue(m_minSync);
ui->cbAutoSeq->setChecked (m_settings->value ("AutoSeq", false).toBool());
ui->cbRxAll->setChecked (m_settings->value ("RxAll", false).toBool());
m_bShMsgs=m_settings->value("ShMsgs",false).toBool();
m_bSWL=m_settings->value("SWL",false).toBool();
m_bFast9=m_settings->value("Fast9",false).toBool();
m_bFastMode=m_settings->value("FastMode",false).toBool();
ui->sbTR->setValue (m_settings->value ("TRPeriod", 15).toInt());
2020-07-23 13:51:05 -04:00
ui->sbTR_FST4W->setValue (m_settings->value ("TRPeriod_FST4W", 15).toInt());
m_lastMonitoredFrequency = m_settings->value ("DialFreq",
QVariant::fromValue<Frequency> (default_frequency)).value<Frequency> ();
ui->WSPRfreqSpinBox->setValue(0); // ensure a change is signaled
ui->WSPRfreqSpinBox->setValue(m_settings->value("WSPRfreq",1500).toInt());
ui->TxFreqSpinBox->setValue(0); // ensure a change is signaled
ui->TxFreqSpinBox->setValue(m_settings->value("TxFreq",1500).toInt());
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_ndepth=m_settings->value("NDepth",3).toInt();
ui->sbTxPercent->setValue (m_settings->value ("PctTx", 20).toInt ());
on_sbTxPercent_valueChanged (ui->sbTxPercent->value ());
ui->RoundRobin->setCurrentText(m_settings->value("RoundRobin",tr("Random")).toString());
m_dBm=m_settings->value("dBm",37).toInt();
m_send_RR73=m_settings->value("RR73",false).toBool();
if(m_send_RR73) {
m_send_RR73=false;
on_txrb4_doubleClicked();
}
ui->WSPR_prefer_type_1_check_box->setChecked (m_settings->value ("WSPRPreferType1", true).toBool ());
m_uploadWSPRSpots=m_settings->value("UploadSpots",false).toBool();
ui->cbNoOwnCall->setChecked(m_settings->value("NoOwnCall",false).toBool());
ui->band_hopping_group_box->setChecked (m_settings->value ("BandHopping", false).toBool());
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
// setup initial value of tx attenuator
m_block_pwr_tooltip = true;
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
ui->outAttenuation->setValue (m_settings->value ("OutAttenuation", 0).toInt ());
m_block_pwr_tooltip = false;
ui->sbCQTxFreq->setValue (m_settings->value ("CQTxFreq", 260).toInt());
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_noSuffix=m_settings->value("NoSuffix",false).toBool();
int n=m_settings->value("GUItab",0).toInt();
ui->tabWidget->setCurrentIndex(n);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
outBufSize=m_settings->value("OutBufSize",4096).toInt();
ui->cbHoldTxFreq->setChecked (m_settings->value ("HoldTxFreq", false).toBool ());
m_pwrBandTxMemory=m_settings->value("pwrBandTxMemory").toHash();
m_pwrBandTuneMemory=m_settings->value("pwrBandTuneMemory").toHash();
ui->actionEnable_AP_FT8->setChecked (m_settings->value ("FT8AP", false).toBool());
ui->actionEnable_AP_JT65->setChecked (m_settings->value ("JT65AP", false).toBool());
ui->splitter->restoreState(m_settings->value("SplitterState").toByteArray());
ui->sbNB->setValue(m_settings->value("Blanker",0).toInt());
ui->actionSWL_Mode->setChecked (m_settings->value ("SWLView", false).toBool ());
on_actionSWL_Mode_triggered (ui->actionSWL_Mode->isChecked ());
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
{
auto const& coeffs = m_settings->value ("PhaseEqualizationCoefficients"
, QList<QVariant> {0., 0., 0., 0., 0.}).toList ();
m_phaseEqCoefficients.clear ();
for (auto const& coeff : coeffs)
{
m_phaseEqCoefficients.append (coeff.value<double> ());
}
}
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_settings->endGroup();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// use these initialisation settings to tune the audio o/p buffer
// size and audio thread priority
m_settings->beginGroup ("Tune");
m_audioThreadPriority = static_cast<QThread::Priority> (m_settings->value ("Audio/ThreadPriority", QThread::HighPriority).toInt () % 8);
m_settings->endGroup ();
checkMSK144ContestType();
if(displayMsgAvg) on_actionMessage_averaging_triggered();
if (displayFoxLog) on_fox_log_action_triggered ();
if (displayContestLog) on_contest_log_action_triggered ();
}
void MainWindow::checkMSK144ContestType()
{
if(SpecOp::NONE != m_config.special_op_id())
{
if(m_mode=="MSK144" && SpecOp::EU_VHF < m_config.special_op_id())
{
MessageBox::warning_message (this, tr ("Improper mode"),
"Mode will be changed to FT8. MSK144 not available if Field Day, WW Digi, RTTY or Fox/Hound is selected.");
on_actionFT8_triggered();
}
}
}
void MainWindow::set_application_font (QFont const& font)
{
qApp->setFont (font);
// set font in the application style sheet as well in case it has
// been modified in the style sheet which has priority
QString ss;
if (qApp->styleSheet ().size ())
{
auto sheet = qApp->styleSheet ();
sheet.remove ("file:///");
QFile sf {sheet};
if (sf.open (QFile::ReadOnly | QFile::Text))
{
ss = sf.readAll () + ss;
}
}
qApp->setStyleSheet (ss + "* {" + font_as_stylesheet (font) + '}');
for (auto& widget : qApp->topLevelWidgets ())
{
widget->updateGeometry ();
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::setDecodedTextFont (QFont const& font)
{
ui->decodedTextBrowser->setContentFont (font);
ui->decodedTextBrowser2->setContentFont (font);
ui->textBrowser4->setContentFont(font);
ui->textBrowser4->displayFoxToBeCalled(" ");
ui->textBrowser4->setText("");
auto style_sheet = "QLabel {" + font_as_stylesheet (font) + '}';
ui->lh_decodes_headings_label->setStyleSheet (ui->lh_decodes_headings_label->styleSheet () + style_sheet);
ui->rh_decodes_headings_label->setStyleSheet (ui->rh_decodes_headings_label->styleSheet () + style_sheet);
if (m_msgAvgWidget) {
m_msgAvgWidget->changeFont (font);
}
if (m_foxLogWindow) {
m_foxLogWindow->set_log_view_font (font);
}
if (m_contestLogWindow) {
m_contestLogWindow->set_log_view_font (font);
}
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
updateGeometry ();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
void MainWindow::fixStop()
{
m_hsymStop=179;
if(m_mode=="WSPR") {
m_hsymStop=396;
} else if(m_mode=="Echo") {
m_hsymStop=9;
} else if (m_mode=="JT4"){
m_hsymStop=176;
if(m_config.decode_at_52s()) m_hsymStop=179;
} else if (m_mode=="JT9"){
m_hsymStop=173;
if(m_config.decode_at_52s()) m_hsymStop=179;
} else if (m_mode=="JT65" or m_mode=="JT9+JT65"){
m_hsymStop=174;
if(m_config.decode_at_52s()) m_hsymStop=179;
} else if (m_mode=="QRA64"){
m_hsymStop=179;
if(m_config.decode_at_52s()) m_hsymStop=186;
} else if (m_mode=="FreqCal"){
m_hsymStop=((int(m_TRperiod/0.288))/8)*8;
} else if (m_mode=="FT8") {
m_hsymStop=50;
} else if (m_mode=="FT4") {
m_hsymStop=21;
2020-07-23 13:51:05 -04:00
} else if(m_mode=="FST4" or m_mode=="FST4W") {
2020-07-18 13:52:09 -04:00
int stop[] = {39,85,187,387,1003,3107,6232};
int stop_EME[] = {48,95,197,396,1012,3107,6232};
int i=0;
if(m_TRperiod==30) i=1;
if(m_TRperiod==60) i=2;
if(m_TRperiod==120) i=3;
if(m_TRperiod==300) i=4;
2020-07-18 13:50:08 -04:00
if(m_TRperiod==900) i=5;
if(m_TRperiod==1800) i=6;
if(m_config.decode_at_52s()) {
m_hsymStop=stop_EME[i];
} else {
m_hsymStop=stop[i];
}
}
}
//-------------------------------------------------------------- dataSink()
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
void MainWindow::dataSink(qint64 frames)
{
static float s[NSMAX];
char line[80];
int k(frames);
QString fname {QDir::toNativeSeparators(m_config.writeable_data_dir ().absoluteFilePath ("refspec.dat"))};
QByteArray bafname = fname.toLatin1();
const char *c_fname = bafname.data();
int len=fname.length();
if(m_diskData) {
dec_data.params.ndiskdat=1;
} else {
dec_data.params.ndiskdat=0;
}
m_bUseRef=m_wideGraph->useRef();
if(!m_diskData) {
refspectrum_(&dec_data.d2[k-m_nsps/2],&m_bClearRefSpec,&m_bRefSpec,
&m_bUseRef,c_fname,len);
}
m_bClearRefSpec=false;
if(m_mode=="ISCAT" or m_mode=="MSK144" or m_bFast9) {
fastSink(frames);
if(m_bFastMode) return;
}
// Get power, spectrum, and ihsym
dec_data.params.nfa=m_wideGraph->nStartFreq();
dec_data.params.nfb=m_wideGraph->Fmax();
if(m_mode=="FST4") {
dec_data.params.nfa=ui->sbF_Low->value();
dec_data.params.nfb=ui->sbF_High->value();
}
int nsps=m_nsps;
if(m_bFastMode) nsps=6912;
int nsmo=m_wideGraph->smoothYellow()-1;
bool bLowSidelobes=m_config.lowSidelobes();
int npct=0;
2020-07-23 13:51:05 -04:00
if(m_mode.startsWith("FST4")) npct=ui->sbNB->value();
symspec_(&dec_data,&k,&m_TRperiod,&nsps,&m_inGain,&bLowSidelobes,&nsmo,&m_px,s,
&m_df3,&m_ihsym,&m_npts8,&m_pxmax,&npct);
2020-07-23 13:51:05 -04:00
if(m_mode=="WSPR" or m_mode=="FST4W") wspr_downsample_(dec_data.d2,&k);
if(m_ihsym <=0) return;
if(ui) ui->signal_meter_widget->setValue(m_px,m_pxmax); // Update thermometer
if(m_monitoring || m_diskData) {
m_wideGraph->dataSink2(s,m_df3,m_ihsym,m_diskData);
}
if(m_mode=="MSK144") return;
fixStop();
if (m_mode == "FreqCal"
// only calculate after 1st chunk, also skip chunk where rig
// changed frequency
&& !(m_ihsym % 8) && m_ihsym > 8 && m_ihsym <= m_hsymStop) {
int RxFreq=ui->RxFreqSpinBox->value ();
int nkhz=(m_freqNominal+RxFreq)/1000;
int ftol = ui->sbFtol->value ();
freqcal_(&dec_data.d2[0],&k,&nkhz,&RxFreq,&ftol,&line[0],80);
QString t=QString::fromLatin1(line);
DecodedText decodedtext {t};
ui->decodedTextBrowser->displayDecodedText (decodedtext,m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand, m_config.ppfx());
if (ui->measure_check_box->isChecked ()) {
// Append results text to file "fmt.all".
QFile f {m_config.writeable_data_dir ().absoluteFilePath ("fmt.all")};
if (f.open(QIODevice::WriteOnly | QIODevice::Text | QIODevice::Append)) {
QTextStream out(&f);
2020-06-13 11:04:41 -04:00
out << t
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f.close();
} else {
MessageBox::warning_message (this, tr ("File Open Error")
, tr ("Cannot open \"%1\" for append: %2")
.arg (f.fileName ()).arg (f.errorString ()));
}
}
if(m_ihsym==m_hsymStop && ui->actionFrequency_calibration->isChecked()) {
freqCalStep();
}
}
if(m_ihsym==3*m_hsymStop/4) {
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_dialFreqRxWSPR=m_freqNominal;
}
if(m_mode=="FT8") {
to_jt9(m_ihsym,-1,-1); //Allow jt9 to bail out early, if necessary
2020-03-13 14:25:12 -04:00
if(m_ihsym==40 and m_decoderBusy) {
qDebug() << "Clearing hung decoder status";
2020-03-13 14:25:12 -04:00
decodeDone(); //Clear a hung decoder status
}
}
bool bCallDecoder=false;
if(m_ihsym==m_hsymStop) bCallDecoder=true;
if(m_mode=="FT8" and !m_diskData) {
if(m_ihsym==m_earlyDecode) bCallDecoder=true;
if(m_ihsym==m_earlyDecode2) bCallDecoder=true;
}
if(bCallDecoder) {
if(m_mode=="Echo") {
float snr=0;
int nfrit=0;
int nqual=0;
float f1=1500.0;
float xlevel=0.0;
float sigdb=0.0;
float dfreq=0.0;
float width=0.0;
echocom_.nclearave=m_nclearave;
int nDop=0;
avecho_(dec_data.d2,&nDop,&nfrit,&nqual,&f1,&xlevel,&sigdb,
&snr,&dfreq,&width);
QString t;
2020-05-06 21:56:57 -04:00
t = t.asprintf("%3d %7.1f %7.1f %7.1f %7.1f %3d",echocom_.nsum,xlevel,sigdb,
dfreq,width,nqual);
t=QDateTime::currentDateTimeUtc().toString("hh:mm:ss ") + t;
if (ui) ui->decodedTextBrowser->appendText(t);
if(m_echoGraph->isVisible()) m_echoGraph->plotSpec();
m_nclearave=0;
//Don't restart Monitor after an Echo transmission
if(m_bEchoTxed and !m_auto) {
monitor(false);
m_bEchoTxed=false;
}
return;
}
if(m_mode=="FreqCal") {
return;
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if( m_dialFreqRxWSPR==0) m_dialFreqRxWSPR=m_freqNominal;
m_dataAvailable=true;
dec_data.params.npts8=(m_ihsym*m_nsps)/16;
dec_data.params.newdat=1;
dec_data.params.nagain=0;
dec_data.params.nzhsym=m_hsymStop;
2020-02-13 15:05:37 -05:00
if(m_mode=="FT8" and m_ihsym==m_earlyDecode and !m_diskData) dec_data.params.nzhsym=m_earlyDecode;
if(m_mode=="FT8" and m_ihsym==m_earlyDecode2 and !m_diskData) dec_data.params.nzhsym=m_earlyDecode2;
QDateTime now {QDateTime::currentDateTimeUtc ()};
m_dateTime = now.toString ("yyyy-MMM-dd hh:mm");
if(m_mode!="WSPR") decode(); //Start decoder
if(m_mode=="FT8" and !m_diskData and (m_ihsym==m_earlyDecode or m_ihsym==m_earlyDecode2)) return;
if (!m_diskData)
{
Q_EMIT reset_audio_input_stream (true); // reports dropped samples
}
2020-07-23 13:51:05 -04:00
if(!m_diskData and (m_saveAll or m_saveDecoded or m_mode=="WSPR" or m_mode=="FST4W")) {
//Always save unless "Save None"; may delete later
if(m_TRperiod < 60) {
int n=fmod(double(now.time().second()),m_TRperiod);
if(n<(m_TRperiod/2)) n=n+m_TRperiod;
auto const& period_start=now.addSecs(-n);
m_fnameWE=m_config.save_directory().absoluteFilePath (period_start.toString("yyMMdd_hhmmss"));
} else {
auto const& period_start = now.addSecs (-(now.time ().minute () % (int(m_TRperiod) / 60)) * 60);
m_fnameWE=m_config.save_directory ().absoluteFilePath (period_start.toString ("yyMMdd_hhmm"));
}
int samples=m_TRperiod*12000;
if(m_mode=="FT4") samples=21*3456;
// the following is potential a threading hazard - not a good
// idea to pass pointer to be processed in another thread
m_saveWAVWatcher.setFuture (QtConcurrent::run (std::bind (&MainWindow::save_wave_file,
this, m_fnameWE, &dec_data.d2[0], samples, m_config.my_callsign(),
m_config.my_grid(), m_mode, m_nSubMode, m_freqNominal, m_hisCall, m_hisGrid)));
2020-07-23 13:51:05 -04:00
if (m_mode=="WSPR" or m_mode=="FST4W") {
QString c2name_string {m_fnameWE + ".c2"};
int len1=c2name_string.length();
char c2name[80];
strcpy(c2name,c2name_string.toLatin1 ().constData ());
int nsec=120;
int nbfo=1500;
double f0m1500=m_freqNominal/1000000.0 + nbfo - 1500;
int err = savec2_(c2name,&nsec,&f0m1500,len1);
if (err!=0) MessageBox::warning_message (this, tr ("Error saving c2 file"), c2name);
}
}
if(m_mode=="WSPR") {
2020-06-13 11:04:41 -04:00
QStringList t2;
QStringList depth_args;
t2 << "-f" << QString {"%1"}.arg (m_dialFreqRxWSPR / 1e6, 0, 'f', 6);
2020-06-13 11:04:41 -04:00
if((m_ndepth&7)==1) depth_args << "-qB"; //2 pass w subtract, no Block detection, no shift jittering
if((m_ndepth&7)==2) depth_args << "-C" << "500" << "-o" << "4"; //3 pass, subtract, Block detection, OSD
if((m_ndepth&7)==3) depth_args << "-C" << "500" << "-o" << "4" << "-d"; //3 pass, subtract, Block detect, OSD, more candidates
QStringList degrade;
degrade << "-d" << QString {"%1"}.arg (m_config.degrade(), 4, 'f', 1);
m_cmndP1.clear ();
if(m_diskData) {
2020-06-13 11:04:41 -04:00
m_cmndP1 << depth_args << "-a"
<< QDir::toNativeSeparators (m_config.writeable_data_dir ().absolutePath()) << m_path;
} else {
m_cmndP1 << depth_args << "-a"
<< QDir::toNativeSeparators (m_config.writeable_data_dir ().absolutePath())
<< t2 << m_fnameWE + ".wav";
}
if (ui) ui->DecodeButton->setChecked (true);
p1Timer.start(1000);
m_decoderBusy = true;
statusUpdate ();
}
m_rxDone=true;
}
}
void MainWindow::startP1()
{
p1.start (QDir::toNativeSeparators (QDir {QApplication::applicationDirPath ()}.absoluteFilePath ("wsprd")), m_cmndP1);
}
QString MainWindow::save_wave_file (QString const& name, short const * data, int samples,
QString const& my_callsign, QString const& my_grid, QString const& mode, qint32 sub_mode,
Frequency frequency, QString const& his_call, QString const& his_grid) const
{
//
// This member function runs in a thread and should not access
// members that may be changed in the GUI thread or any other thread
// without suitable synchronization.
//
QAudioFormat format;
format.setCodec ("audio/pcm");
format.setSampleRate (12000);
format.setChannelCount (1);
format.setSampleSize (16);
format.setSampleType (QAudioFormat::SignedInt);
auto source = QString {"%1; %2"}.arg (my_callsign).arg (my_grid);
auto comment = QString {"Mode=%1%2; Freq=%3%4"}
.arg (mode)
.arg (QString {(mode.contains ('J') && !mode.contains ('+'))
|| mode.startsWith ("FST4") || mode.startsWith ("QRA")
? QString {"; Sub Mode="} + QString::number (int (samples / 12000)) + QChar {'A' + sub_mode}
: QString {}})
.arg (Radio::frequency_MHz_string (frequency))
.arg (QString {mode!="WSPR" ? QString {"; DXCall=%1; DXGrid=%2"}
.arg (his_call)
.arg (his_grid).toLocal8Bit () : ""});
BWFFile::InfoDictionary list_info {
{{{'I','S','R','C'}}, source.toLocal8Bit ()},
{{{'I','S','F','T'}}, program_title (revision ()).simplified ().toLocal8Bit ()},
{{{'I','C','R','D'}}, QDateTime::currentDateTimeUtc ()
.toString ("yyyy-MM-ddTHH:mm:ss.zzzZ").toLocal8Bit ()},
{{{'I','C','M','T'}}, comment.toLocal8Bit ()},
};
auto file_name = name + ".wav";
BWFFile wav {format, file_name, list_info};
if (!wav.open (BWFFile::WriteOnly)
|| 0 > wav.write (reinterpret_cast<char const *> (data)
, sizeof (short) * samples))
{
return file_name + ": " + wav.errorString ();
}
return QString {};
}
//-------------------------------------------------------------- fastSink()
void MainWindow::fastSink(qint64 frames)
{
int k (frames);
bool decodeNow=false;
if(k < m_k0) { //New sequence ?
memcpy(fast_green2,fast_green,4*703); //Copy fast_green[] to fast_green2[]
memcpy(fast_s2,fast_s,4*703*64); //Copy fast_s[] into fast_s2[]
fast_jh2=fast_jh;
if(!m_diskData) memset(dec_data.d2,0,2*30*12000); //Zero the d2[] array
m_bFastDecodeCalled=false;
m_bDecoded=false;
}
QDateTime tnow=QDateTime::currentDateTimeUtc();
int ihr=tnow.toString("hh").toInt();
int imin=tnow.toString("mm").toInt();
int isec=tnow.toString("ss").toInt();
isec=isec - fmod(double(isec),m_TRperiod);
int nutc0=10000*ihr + 100*imin + isec;
if(m_diskData) nutc0=m_UTCdisk;
char line[80];
bool bmsk144=((m_mode=="MSK144") and (m_monitoring or m_diskData));
line[0]=0;
int RxFreq=ui->RxFreqSpinBox->value ();
int nTRpDepth=m_TRperiod + 1000*(m_ndepth & 3);
qint64 ms0 = QDateTime::currentMSecsSinceEpoch();
2019-07-02 20:51:40 -04:00
// ::memcpy(dec_data.params.mycall, (m_baseCall+" ").toLatin1(),sizeof dec_data.params.mycall);
::memcpy(dec_data.params.mycall,(m_config.my_callsign () + " ").toLatin1(),sizeof dec_data.params.mycall);
QString hisCall {ui->dxCallEntry->text ()};
bool bshmsg=ui->cbShMsgs->isChecked();
bool bswl=ui->cbSWL->isChecked();
2019-07-02 20:51:40 -04:00
// ::memcpy(dec_data.params.hiscall,(Radio::base_callsign (hisCall) + " ").toLatin1 ().constData (), sizeof dec_data.params.hiscall);
::memcpy(dec_data.params.hiscall,(hisCall + " ").toLatin1 ().constData (), sizeof dec_data.params.hiscall);
::memcpy(dec_data.params.mygrid, (m_config.my_grid()+" ").toLatin1(), sizeof dec_data.params.mygrid);
QString dataDir;
dataDir = m_config.writeable_data_dir ().absolutePath ();
char ddir[512];
2019-07-02 20:51:40 -04:00
::strncpy(ddir,dataDir.toLatin1(), sizeof (ddir) - 1);
float pxmax = 0;
float rmsNoGain = 0;
int ftol = ui->sbFtol->value ();
2020-03-19 11:43:22 -04:00
hspec_(dec_data.d2,&k,&nutc0,&nTRpDepth,&RxFreq,&ftol,&bmsk144,
First attempt at a UI phase compensation tool for MSK144 This builds on the static phase compensation in the MSK144 decoder and the phase analysis and polynomial fitting capabilities also in teh MSK144 decoder, by allowing captured data to be selected for phase equalization from the WSJT-X UI. Reads captured phase compensation curve estimate files containing fitted polynomial coefficients and measured phase data from MSK144 receptions. Intent is to select a compensation curve that is from a known transmitter like an SDR which have good phase linearity. Phase plots and compensation polynomials may be viewed and compared with the current compensation polynomial. A suitable polynomial can be applied to be use in all further decoding of MSK144 signals. Plots of the currently selected polynomial and its modified higher order terms polynomial which is actually used in equalization (this plot may be dropped - it is just for kicks at the moment). When a captured phase analysis file is loaded plots of the measured phase and the proposed best fit polynomial are shown. Basic maintenance is also included allowing clearing and loading captured plots and an option to revert to a flat no equalization curve. More to come on this as amplitude equalization is also possible, this will probably be similar, maybe even plotted on the same graph with dual axes for phase and amplitude. Amplitude correction from a measured reference spectrum could be viewed and selected for equalization for all modes. TBC... This change also introduces the QCustomPlot 3rd party widget. Currently this is statically linked from a qcp library built by the WSJT-X CMake script. This will probably be migrated to a shared object (DLL) build as a CMake external project, once some CMake script re-factoring has been completed, which is more in line with the QCustomPlot author's intentions. This will allow efficient reuse in other tools shipped with WSJT-X. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7570 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-02-20 21:13:13 -05:00
&m_bTrain,m_phaseEqCoefficients.constData(),&m_inGain,&dec_data.params.mycall[0],
&dec_data.params.hiscall[0],&bshmsg,&bswl,
2020-03-19 12:04:56 -04:00
&ddir[0],fast_green,fast_s,&fast_jh,&pxmax,&rmsNoGain,&line[0],12,12,512,80);
float px = fast_green[fast_jh];
QString t;
2020-05-06 21:56:57 -04:00
t = t.asprintf(" Rx noise: %5.1f ",px);
ui->signal_meter_widget->setValue(rmsNoGain,pxmax); // Update thermometer
m_fastGraph->plotSpec(m_diskData,m_UTCdisk);
if(bmsk144 and (line[0]!=0)) {
QString message {QString::fromLatin1 (line)};
DecodedText decodedtext {message.replace (QChar::LineFeed, "")};
ui->decodedTextBrowser->displayDecodedText (decodedtext,m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand,m_config.ppfx());
m_bDecoded=true;
auto_sequence (decodedtext, ui->sbFtol->value (), std::numeric_limits<unsigned>::max ());
if (m_mode != "ISCAT") postDecode (true, decodedtext.string ());
// writeAllTxt(message);
write_all("Rx",message);
bool stdMsg = decodedtext.report(m_baseCall,
Radio::base_callsign(ui->dxCallEntry->text()),m_rptRcvd);
if (stdMsg) pskPost (decodedtext);
}
float fracTR=float(k)/(12000.0*m_TRperiod);
decodeNow=false;
if(fracTR>0.92) {
m_dataAvailable=true;
fast_decode_done();
m_bFastDone=true;
}
m_k0=k;
if(m_diskData and m_k0 >= dec_data.params.kin - 7 * 512) decodeNow=true;
if(!m_diskData and m_tRemaining<0.35 and !m_bFastDecodeCalled) decodeNow=true;
if(m_mode=="MSK144") decodeNow=false;
if(decodeNow) {
m_dataAvailable=true;
m_t0=0.0;
m_t1=k/12000.0;
m_kdone=k;
dec_data.params.newdat=1;
if(!m_decoderBusy) {
m_bFastDecodeCalled=true;
decode();
}
}
if(decodeNow or m_bFastDone) {
if(!m_diskData and (m_saveAll or m_saveDecoded)) {
QDateTime now {QDateTime::currentDateTimeUtc()};
int n=fmod(double(now.time().second()),m_TRperiod);
if(n<(m_TRperiod/2)) n=n+m_TRperiod;
auto const& period_start = now.addSecs (-n);
m_fnameWE = m_config.save_directory ().absoluteFilePath (period_start.toString ("yyMMdd_hhmmss"));
if(m_saveAll or m_bAltV or (m_bDecoded and m_saveDecoded) or (m_mode!="MSK144")) {
m_bAltV=false;
// the following is potential a threading hazard - not a good
// idea to pass pointer to be processed in another thread
m_saveWAVWatcher.setFuture (QtConcurrent::run (std::bind (&MainWindow::save_wave_file,
this, m_fnameWE, &dec_data.d2[0], int(m_TRperiod*12000.0), m_config.my_callsign(),
m_config.my_grid(), m_mode, m_nSubMode, m_freqNominal, m_hisCall, m_hisGrid)));
}
if(m_mode!="MSK144") {
killFileTimer.start (int(750.0*m_TRperiod)); //Kill 3/4 period from now
}
}
m_bFastDone=false;
}
float tsec=0.001*(QDateTime::currentMSecsSinceEpoch() - ms0);
m_fCPUmskrtd=0.9*m_fCPUmskrtd + 0.1*tsec;
}
void MainWindow::showSoundInError(const QString& errorMsg)
{
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
MessageBox::critical_message (this, tr ("Error in Sound Input"), errorMsg);
}
void MainWindow::showSoundOutError(const QString& errorMsg)
{
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
MessageBox::critical_message (this, tr ("Error in Sound Output"), errorMsg);
}
void MainWindow::showStatusMessage(const QString& statusMsg)
{
statusBar()->showMessage(statusMsg, 5000);
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::on_actionSettings_triggered() //Setup Dialog
{
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
// things that might change that we need know about
auto callsign = m_config.my_callsign ();
auto my_grid = m_config.my_grid ();
SpecOp nContest0=m_config.special_op_id();
auto psk_on = m_config.spot_to_psk_reporter ();
if (QDialog::Accepted == m_config.exec ()) {
checkMSK144ContestType();
if (m_config.my_callsign () != callsign) {
m_baseCall = Radio::base_callsign (m_config.my_callsign ());
ui->tx1->setEnabled (elide_tx1_not_allowed () || ui->tx1->isEnabled ());
morse_(const_cast<char *> (m_config.my_callsign ().toLatin1().constData()),
const_cast<int *> (icw), &m_ncw, m_config.my_callsign ().length());
}
if (m_config.my_callsign () != callsign || m_config.my_grid () != my_grid) {
statusUpdate ();
}
on_dxGridEntry_textChanged (m_hisGrid); // recalculate distances in case of units change
enable_DXCC_entity (m_config.DXCC ()); // sets text window proportions and (re)inits the logbook
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
pskSetLocal ();
// this will close the connection to PSKReporter if it has been
// disabled
if (psk_on && !m_config.spot_to_psk_reporter ())
{
m_psk_Reporter.sendReport (true);
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
Improve audio device handling and error recovery where possible audio devices that disappear are not forgotten until the user selects another device, this should allow temporarily missing devices or forgetting to switch on devices before starting WSJT-X to be handled more cleanly. If all else fails, visiting the Settings dialog and clicking OK should get things going again. Note that we still do not have a reliable way of detecting failed audio out devices, in that case selecting another device and then returning to the original should work. Enumerating audio devices is expensive and on Linux may take many seconds per device. To avoid lengthy blocking behaviour until it is absolutely necessary, audio devices are not enumerated until one of the "Settings->Audio" device drop-down lists is opened. Elsewhere when devices must be discovered the enumeration stops as soon as the configured device is discovered. A status bar message is posted when audio devices are being enumerated as a reminder that the UI may block while this is happening. The message box warning about unaccounted-for input audio samples now only triggers when >5 seconds of audio appears to be missing or over provided. Hopefully this will make the warning less annoying for those that are using audio sources with high and/or variable latencies. A status bar message is still posted for any amount of audio input samples unaccounted for >1/5 second, this message appearing a lot should be considered as notification that there is a problem with the audio sub-system, system load is too high, or time synchronization is stepping the PC clock rather than adjusting the frequency to maintain monotonic clock ticks.
2020-09-20 13:20:16 -04:00
if(m_config.restart_audio_input () && !m_config.audio_input_device ().isNull ()) {
Q_EMIT startAudioInputStream (m_config.audio_input_device ()
, rx_chunk_size * m_downSampleFactor
, m_detector, m_downSampleFactor
, m_config.audio_input_channel ());
}
Improve audio device handling and error recovery where possible audio devices that disappear are not forgotten until the user selects another device, this should allow temporarily missing devices or forgetting to switch on devices before starting WSJT-X to be handled more cleanly. If all else fails, visiting the Settings dialog and clicking OK should get things going again. Note that we still do not have a reliable way of detecting failed audio out devices, in that case selecting another device and then returning to the original should work. Enumerating audio devices is expensive and on Linux may take many seconds per device. To avoid lengthy blocking behaviour until it is absolutely necessary, audio devices are not enumerated until one of the "Settings->Audio" device drop-down lists is opened. Elsewhere when devices must be discovered the enumeration stops as soon as the configured device is discovered. A status bar message is posted when audio devices are being enumerated as a reminder that the UI may block while this is happening. The message box warning about unaccounted-for input audio samples now only triggers when >5 seconds of audio appears to be missing or over provided. Hopefully this will make the warning less annoying for those that are using audio sources with high and/or variable latencies. A status bar message is still posted for any amount of audio input samples unaccounted for >1/5 second, this message appearing a lot should be considered as notification that there is a problem with the audio sub-system, system load is too high, or time synchronization is stepping the PC clock rather than adjusting the frequency to maintain monotonic clock ticks.
2020-09-20 13:20:16 -04:00
if(m_config.restart_audio_output () && !m_config.audio_output_device ().isNull ()) {
Q_EMIT initializeAudioOutputStream (m_config.audio_output_device ()
, AudioDevice::Mono == m_config.audio_output_channel () ? 1 : 2
, tx_audio_buffer_size);
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
displayDialFrequency ();
bool vhf {m_config.enable_VHF_features()};
m_wideGraph->setVHF(vhf);
if (!vhf) ui->sbSubmode->setValue (0);
setup_status_bar (vhf);
bool b = vhf && (m_mode=="JT4" or m_mode=="JT65" or m_mode=="ISCAT" or
m_mode=="JT9" or m_mode=="MSK144" or m_mode=="QRA64");
if(b) VHF_features_enabled(b);
set_mode (m_mode);
if(b) VHF_features_enabled(b);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_config.transceiver_online ();
if(!m_bFastMode) setXIT (ui->TxFreqSpinBox->value ());
2020-07-23 13:51:05 -04:00
if ((m_config.single_decode () && !m_mode.startsWith ("FST4")) || m_mode=="JT4") {
ui->lh_decodes_title_label->setText(tr ("Single-Period Decodes"));
ui->rh_decodes_title_label->setText(tr ("Average Decodes"));
}
update_watchdog_label ();
if(!m_splitMode) ui->cbCQTx->setChecked(false);
if(!m_config.enable_VHF_features()) {
ui->actionInclude_averaging->setVisible(false);
ui->actionInclude_correlation->setVisible (false);
ui->actionInclude_averaging->setChecked(false);
ui->actionInclude_correlation->setChecked(false);
ui->actionEnable_AP_JT65->setVisible(false);
}
if(m_config.special_op_id()!=nContest0) ui->tx1->setEnabled(true);
chkFT4();
if(SpecOp::EU_VHF==m_config.special_op_id() and m_config.my_grid().size()<6) {
MessageBox::information_message (this,
"EU VHF Contest messages require a 6-character locator.");
}
if((m_config.special_op_id()==SpecOp::FOX or m_config.special_op_id()==SpecOp::HOUND) and
m_mode!="FT8") {
MessageBox::information_message (this,
"Fox-and-Hound operation is available only in FT8 mode.");
}
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::on_monitorButton_clicked (bool checked)
{
if (!m_transmitting) {
auto prior = m_monitoring;
monitor (checked);
if (checked && !prior) {
if (m_config.monitor_last_used ()) {
// put rig back where it was when last in control
setRig (m_lastMonitoredFrequency);
setXIT (ui->TxFreqSpinBox->value ());
}
// ensure FreqCal triggers
if(m_mode=="FST4W") {
on_sbFST4W_RxFreq_valueChanged(ui->sbFST4W_RxFreq->value());
} else {
on_RxFreqSpinBox_valueChanged (ui->RxFreqSpinBox->value ());
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
//Get Configuration in/out of strict split and mode checking
2020-09-08 07:54:19 -04:00
m_config.sync_transceiver (true, checked);
} else {
ui->monitorButton->setChecked (false); // disallow
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
void MainWindow::monitor (bool state)
{
ui->monitorButton->setChecked (state);
if (state) {
m_diskData = false; // no longer reading WAV files
if (!m_monitoring) Q_EMIT resumeAudioInputStream ();
} else {
Q_EMIT suspendAudioInputStream ();
}
m_monitoring = state;
}
void MainWindow::on_actionAbout_triggered() //Display "About"
{
CAboutDlg {this}.exec ();
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::on_autoButton_clicked (bool checked)
{
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_auto = checked;
if (checked
&& ui->cbFirst->isVisible () && ui->cbFirst->isChecked()
&& CALLING == m_QSOProgress) {
m_bAutoReply = false; // ready for next
m_bCallingCQ = true; // allows tail-enders to be picked up
ui->cbFirst->setStyleSheet ("QCheckBox{color:red}");
} else {
ui->cbFirst->setStyleSheet("");
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (!checked) m_bCallingCQ = false;
statusUpdate ();
m_bEchoTxOK=false;
if(m_auto and (m_mode=="Echo")) {
m_nclearave=1;
echocom_.nsum=0;
}
m_tAutoOn=QDateTime::currentMSecsSinceEpoch()/1000;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
void MainWindow::on_sbTxPercent_valueChanged (int n)
{
update_dynamic_property (ui->sbTxPercent, "notx", !n);
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::auto_tx_mode (bool state)
{
ui->autoButton->setChecked (state);
on_autoButton_clicked (state);
}
void MainWindow::keyPressEvent (QKeyEvent * e)
{
if(SpecOp::FOX == m_config.special_op_id()) {
switch (e->key()) {
case Qt::Key_Return:
doubleClickOnCall2(Qt::KeyboardModifier(Qt::ShiftModifier + Qt::ControlModifier + Qt::AltModifier));
return;
case Qt::Key_Enter:
doubleClickOnCall2(Qt::KeyboardModifier(Qt::ShiftModifier + Qt::ControlModifier + Qt::AltModifier));
return;
case Qt::Key_Backspace:
qDebug() << "Key Backspace";
return;
}
QMainWindow::keyPressEvent (e);
}
if(SpecOp::HOUND == m_config.special_op_id()) {
switch (e->key()) {
case Qt::Key_Return:
auto_tx_mode(true);
return;
case Qt::Key_Enter:
auto_tx_mode(true);
return;
}
QMainWindow::keyPressEvent (e);
}
int n;
bool bAltF1F6=m_config.alternate_bindings();
switch(e->key())
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
case Qt::Key_B:
if(m_mode=="FT4" && e->modifiers() & Qt::AltModifier) {
on_pbBestSP_clicked();
}
return;
case Qt::Key_C:
if(m_mode=="FT4" && e->modifiers() & Qt::AltModifier) {
bool b=ui->cbFirst->isChecked();
ui->cbFirst->setChecked(!b);
}
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_D:
if(m_mode != "WSPR" && e->modifiers() & Qt::ShiftModifier) {
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
if(!m_decoderBusy) {
dec_data.params.newdat=0;
dec_data.params.nagain=0;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
decode();
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
break;
case Qt::Key_F1:
if(bAltF1F6) {
auto_tx_mode(true);
on_txb6_clicked();
return;
} else {
on_actionOnline_User_Guide_triggered();
return;
}
case Qt::Key_F2:
if(bAltF1F6) {
auto_tx_mode(true);
on_txb2_clicked();
return;
} else {
on_actionSettings_triggered();
return;
}
case Qt::Key_F3:
if(bAltF1F6) {
auto_tx_mode(true);
on_txb3_clicked();
return;
} else {
on_actionKeyboard_shortcuts_triggered();
return;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_F4:
if(bAltF1F6) {
auto_tx_mode(true);
on_txb4_clicked();
return;
} else {
clearDX ();
ui->dxCallEntry->setFocus();
return;
}
case Qt::Key_F5:
if(bAltF1F6) {
auto_tx_mode(true);
on_txb5_clicked();
return;
} else {
on_actionSpecial_mouse_commands_triggered();
return;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_F6:
if(bAltF1F6) {
bool b=ui->cbFirst->isChecked();
ui->cbFirst->setChecked(!b);
} else {
if(e->modifiers() & Qt::ShiftModifier) {
on_actionDecode_remaining_files_in_directory_triggered();
} else {
on_actionOpen_next_in_directory_triggered();
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_F11:
2018-10-16 13:08:15 -04:00
if((e->modifiers() & Qt::ControlModifier) and (e->modifiers() & Qt::ShiftModifier)) {
m_bandEdited = true;
band_changed(m_freqNominal-2000);
} else {
n=11;
if(e->modifiers() & Qt::ControlModifier) n+=100;
if(e->modifiers() & Qt::ShiftModifier) {
int offset=60;
if(m_mode=="FT4") offset=90;
ui->TxFreqSpinBox->setValue(ui->TxFreqSpinBox->value()-offset);
} else{
bumpFqso(n);
}
}
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_F12:
2018-10-16 13:08:15 -04:00
if((e->modifiers() & Qt::ControlModifier) and (e->modifiers() & Qt::ShiftModifier)) {
m_bandEdited = true;
band_changed(m_freqNominal+2000);
} else {
n=12;
if(e->modifiers() & Qt::ControlModifier) n+=100;
if(e->modifiers() & Qt::ShiftModifier) {
int offset=60;
if(m_mode=="FT4") offset=90;
ui->TxFreqSpinBox->setValue(ui->TxFreqSpinBox->value()+offset);
} else {
bumpFqso(n);
}
}
return;
case Qt::Key_Escape:
m_nextCall="";
ui->labNextCall->setStyleSheet("");
ui->labNextCall->setText("");
on_stopTxButton_clicked();
abortQSO();
return;
case Qt::Key_E:
if((e->modifiers() & Qt::ShiftModifier) and SpecOp::FOX > m_config.special_op_id()) {
ui->txFirstCheckBox->setChecked(false);
return;
}
else if((e->modifiers() & Qt::ControlModifier) and SpecOp::FOX > m_config.special_op_id()) {
ui->txFirstCheckBox->setChecked(true);
return;
}
break;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_F:
if(e->modifiers() & Qt::ControlModifier) {
if(ui->tabWidget->currentIndex()==0) {
ui->tx5->clearEditText();
ui->tx5->setFocus();
}
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
break;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_G:
if(e->modifiers() & Qt::AltModifier) {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
genStdMsgs (m_rpt, true);
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
break;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_H:
if(e->modifiers() & Qt::AltModifier) {
on_stopTxButton_clicked();
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
break;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
case Qt::Key_L:
if(e->modifiers() & Qt::ControlModifier) {
lookup();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
genStdMsgs(m_rpt);
return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
break;
case Qt::Key_O:
if(e->modifiers() & Qt::ControlModifier) {
on_actionOpen_triggered();
return;
}
else if(e->modifiers() & Qt::AltModifier) {
bool ok;
auto call = QInputDialog::getText (this, tr ("Change Operator"), tr ("New operator:"),
QLineEdit::Normal, m_config.opCall (), &ok);
if (ok) {
m_config.opCall (call);
}
return;
}
break;
case Qt::Key_R:
if(e->modifiers() & Qt::AltModifier) {
if(!m_send_RR73) on_txrb4_doubleClicked();
return;
}
if(e->modifiers() & Qt::ControlModifier) {
if(m_send_RR73) on_txrb4_doubleClicked();
return;
}
break;
case Qt::Key_Z: //### Recover from hung decode() ?? ###
if(e->modifiers() & Qt::AltModifier) {
decodeDone();
return;
}
break; case Qt::Key_PageUp:
break;
case Qt::Key_PageDown:
band_changed(m_freqNominal-2000);
break; }
QMainWindow::keyPressEvent (e);
}
void MainWindow::bumpFqso(int n) //bumpFqso()
{
int i;
bool ctrl = (n>=100);
n=n%100;
i=ui->RxFreqSpinBox->value();
bool bTrackTx=ui->TxFreqSpinBox->value() == i;
if(n==11) i--;
if(n==12) i++;
if (ui->RxFreqSpinBox->isEnabled ()) {
ui->RxFreqSpinBox->setValue (i);
}
if(ctrl and m_mode=="WSPR") {
ui->WSPRfreqSpinBox->setValue(i);
} else {
if(ctrl and bTrackTx) {
ui->TxFreqSpinBox->setValue (i);
}
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::displayDialFrequency ()
{
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
Frequency dial_frequency {m_rigState.ptt () && m_rigState.split () ?
m_rigState.tx_frequency () : m_rigState.frequency ()};
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// lookup band
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
auto const& band_name = m_config.bands ()->find (dial_frequency);
if (m_lastBand != band_name)
{
// only change this when necessary as we get called a lot and it
// would trash any user input to the band combo box line edit
ui->bandComboBox->setCurrentText (band_name.size () ? band_name : m_config.bands ()->oob ());
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_wideGraph->setRxBand (band_name);
m_lastBand = band_name;
band_changed(dial_frequency);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// search working frequencies for one we are within 10kHz of (1 Mhz
// of on VHF and up)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
bool valid {false};
quint64 min_offset {99999999};
for (auto const& item : *m_config.frequencies ())
{
// we need to do specific checks for above and below here to
// ensure that we can use unsigned Radio::Frequency since we
// potentially use the full 64-bit unsigned range.
auto const& working_frequency = item.frequency_;
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
auto const& offset = dial_frequency > working_frequency ?
dial_frequency - working_frequency :
working_frequency - dial_frequency;
if (offset < min_offset) {
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
min_offset = offset;
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
if (min_offset < 10000u || (m_config.enable_VHF_features() && min_offset < 1000000u)) {
valid = true;
}
update_dynamic_property (ui->labDialFreq, "oob", !valid);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
ui->labDialFreq->setText (Radio::pretty_frequency_MHz_string (dial_frequency));
}
void MainWindow::statusChanged()
{
statusUpdate ();
QFile f {m_config.temp_dir ().absoluteFilePath ("wsjtx_status.txt")};
if(f.open(QFile::WriteOnly | QIODevice::Text)) {
QTextStream out(&f);
QString tmpGrid = m_hisGrid;
if (!tmpGrid.size ()) tmpGrid="n/a"; // Not Available
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
out << qSetRealNumberPrecision (12) << (m_freqNominal / 1.e6)
<< ";" << m_mode << ";" << m_hisCall << ";"
2020-06-13 11:04:41 -04:00
<< ui->rptSpinBox->value() << ";" << m_modeTx << ";" << tmpGrid
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f.close();
} else {
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
MessageBox::warning_message (this, tr ("Status File Error")
, tr ("Cannot open \"%1\" for writing: %2")
.arg (f.fileName ()).arg (f.errorString ()));
}
on_dxGridEntry_textChanged(m_hisGrid);
}
bool MainWindow::eventFilter (QObject * object, QEvent * event)
{
switch (event->type())
{
case QEvent::KeyPress:
// fall through
case QEvent::MouseButtonPress:
// reset the Tx watchdog
tx_watchdog (false);
break;
case QEvent::ChildAdded:
// ensure our child widgets get added to our event filter
add_child_to_event_filter (static_cast<QChildEvent *> (event)->child ());
break;
case QEvent::ChildRemoved:
// ensure our child widgets get d=removed from our event filter
remove_child_from_event_filter (static_cast<QChildEvent *> (event)->child ());
break;
default: break;
}
return QObject::eventFilter(object, event);
}
void MainWindow::createStatusBar() //createStatusBar
{
tx_status_label.setAlignment (Qt::AlignHCenter);
tx_status_label.setMinimumSize (QSize {100, 18});
tx_status_label.setStyleSheet ("QLabel{color: #000000; background-color: #00ff00}");
tx_status_label.setFrameStyle (QFrame::Panel | QFrame::Sunken);
statusBar()->addWidget (&tx_status_label);
config_label.setAlignment (Qt::AlignHCenter);
config_label.setMinimumSize (QSize {80, 18});
config_label.setFrameStyle (QFrame::Panel | QFrame::Sunken);
statusBar()->addWidget (&config_label);
config_label.hide (); // only shown for non-default configuration
mode_label.setAlignment (Qt::AlignHCenter);
mode_label.setMinimumSize (QSize {80, 18});
mode_label.setFrameStyle (QFrame::Panel | QFrame::Sunken);
statusBar()->addWidget (&mode_label);
last_tx_label.setAlignment (Qt::AlignHCenter);
last_tx_label.setMinimumSize (QSize {150, 18});
last_tx_label.setFrameStyle (QFrame::Panel | QFrame::Sunken);
statusBar()->addWidget (&last_tx_label);
ndecodes_label.setAlignment (Qt::AlignHCenter);
ndecodes_label.setMinimumSize (QSize {30, 18});
ndecodes_label.setFrameStyle (QFrame::Panel | QFrame::Sunken);
statusBar()->addWidget (&ndecodes_label);
band_hopping_label.setAlignment (Qt::AlignHCenter);
band_hopping_label.setMinimumSize (QSize {90, 18});
band_hopping_label.setFrameStyle (QFrame::Panel | QFrame::Sunken);
statusBar()->addPermanentWidget(&progressBar);
progressBar.setMinimumSize (QSize {150, 18});
statusBar ()->addPermanentWidget (&watchdog_label);
update_watchdog_label ();
}
void MainWindow::setup_status_bar (bool vhf)
{
auto submode = current_submode ();
if (vhf && submode != QChar::Null)
{
mode_label.setText (m_mode + " " + submode);
}
else
{
mode_label.setText (m_mode);
}
if ("ISCAT" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff9933}");
} else if ("JT9" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff6ec7}");
} else if ("JT4" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #cc99ff}");
} else if ("Echo" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #66ffff}");
} else if ("JT9+JT65" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ffff66}");
} else if ("JT65" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #66ff66}");
} else if ("QRA64" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #99ff33}");
} else if ("MSK144" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff6666}");
} else if ("FT4" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff0099}");
} else if ("FT8" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff6699}");
2020-07-23 13:51:05 -04:00
} else if ("FST4" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #99ff66}");
2020-07-23 13:51:05 -04:00
} else if ("FST4W" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #6699ff}");
} else if ("FreqCal" == m_mode) {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff9933}");
}
last_tx_label.setText (QString {});
if (m_mode.contains (QRegularExpression {R"(^(Echo|ISCAT))"})) {
if (band_hopping_label.isVisible ()) statusBar ()->removeWidget (&band_hopping_label);
} else if (m_mode=="WSPR") {
mode_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff66ff}");
if (!band_hopping_label.isVisible ()) {
statusBar ()->addWidget (&band_hopping_label);
band_hopping_label.show ();
}
} else {
if (band_hopping_label.isVisible ()) statusBar ()->removeWidget (&band_hopping_label);
}
}
bool MainWindow::subProcessFailed (QProcess * process, int exit_code, QProcess::ExitStatus status)
{
if (m_valid && (exit_code || QProcess::NormalExit != status))
{
QStringList arguments;
for (auto argument: process->arguments ())
{
if (argument.contains (' ')) argument = '"' + argument + '"';
arguments << argument;
}
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
MessageBox::critical_message (this, tr ("Subprocess Error")
, tr ("Subprocess failed with exit code %1")
.arg (exit_code)
, tr ("Running: %1\n%2")
.arg (process->program () + ' ' + arguments.join (' '))
.arg (QString {process->readAllStandardError()}));
return true;
}
return false;
}
void MainWindow::subProcessError (QProcess * process, QProcess::ProcessError)
{
if (m_valid)
{
QStringList arguments;
for (auto argument: process->arguments ())
{
if (argument.contains (' ')) argument = '"' + argument + '"';
arguments << argument;
}
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
MessageBox::critical_message (this, tr ("Subprocess error")
, tr ("Running: %1\n%2")
.arg (process->program () + ' ' + arguments.join (' '))
.arg (process->errorString ()));
m_valid = false; // ensures exit if still constructing
QTimer::singleShot (0, this, SLOT (close ()));
}
}
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
void MainWindow::closeEvent(QCloseEvent * e)
{
m_valid = false; // suppresses subprocess errors
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_config.transceiver_offline ();
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
writeSettings ();
m_astroWidget.reset ();
Qt 5 Audio replaces PortAudio. Currently only Qt5 or above is known to work with this code. It may be possible to backport it to Qt4 if required. Audio output goes back to a separate thread to try and minimize stutters in streaming on Windows particularly. A crash on Linux due to mishandling of stereo audio output has been fixed and both left and right channels are now correctly synthesised with identical contents. Rigs are enumerated directly from hamlib API rather than running a sub process reading output of rigctl -l. This was initially done to get rid of some GUI thread blocking in the configuration dialog, but is generally a better way of doing it anyway. Some refactoring in MainWindow to accomodate the audio streaming, modulation and detecting classes. Exit handling for application refactored to use signals rather than brute force event loop exit. This was required to get correct thread shutdown semantics. The GUI update timer is now stopped during application shutdown which is necessary to stop crashes when shutting down gracefully with signals and window close() calls. There is an outstanding issue with Linux audio streams; the QAudio Input/Output classes create a new stream name each time a stream is started. This doesn't play well with PulseAudio utilities such as pavucontrol to set stream volume as settings are lost every tx period. I have tried to keep a single stream for all output but there are problems restarting it that haven't been resolved yet. The QtCreator project file has been rearranged a little because it passes all the object files to the linker rather than using an archive library. Since the GNU linker is single pass; the object files need to be in a logical order with definitions appearing afer references to them. This was required to avoid a linking error. The lib/Makefile.linux has been enhanced to use the fortran compiler to locate the correct version of the Fortran library to use. This is necessary on the latest Linux distros because the unversioned symlink to compiler support libraries is no longer provided. This only an issue with mixed programming language links where the linker driver for one language has to link support libraraies for another language. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3532 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-07 19:09:13 -04:00
m_guiTimer.stop ();
m_prefixes.reset ();
m_shortcuts.reset ();
m_mouseCmnds.reset ();
m_colorHighlighting.reset ();
if(m_mode!="MSK144" and m_mode!="FT8") killFile();
float sw=0.0;
int nw=400;
int nh=100;
int irow=-99;
plotsave_(&sw,&nw,&nh,&irow);
to_jt9(m_ihsym,999,-1); //Tell jt9 to terminate
if (!proc_jt9.waitForFinished(1000)) proc_jt9.close();
mem_jt9->detach();
Qt 5 Audio replaces PortAudio. Currently only Qt5 or above is known to work with this code. It may be possible to backport it to Qt4 if required. Audio output goes back to a separate thread to try and minimize stutters in streaming on Windows particularly. A crash on Linux due to mishandling of stereo audio output has been fixed and both left and right channels are now correctly synthesised with identical contents. Rigs are enumerated directly from hamlib API rather than running a sub process reading output of rigctl -l. This was initially done to get rid of some GUI thread blocking in the configuration dialog, but is generally a better way of doing it anyway. Some refactoring in MainWindow to accomodate the audio streaming, modulation and detecting classes. Exit handling for application refactored to use signals rather than brute force event loop exit. This was required to get correct thread shutdown semantics. The GUI update timer is now stopped during application shutdown which is necessary to stop crashes when shutting down gracefully with signals and window close() calls. There is an outstanding issue with Linux audio streams; the QAudio Input/Output classes create a new stream name each time a stream is started. This doesn't play well with PulseAudio utilities such as pavucontrol to set stream volume as settings are lost every tx period. I have tried to keep a single stream for all output but there are problems restarting it that haven't been resolved yet. The QtCreator project file has been rearranged a little because it passes all the object files to the linker rather than using an archive library. Since the GNU linker is single pass; the object files need to be in a logical order with definitions appearing afer references to them. This was required to avoid a linking error. The lib/Makefile.linux has been enhanced to use the fortran compiler to locate the correct version of the Fortran library to use. This is necessary on the latest Linux distros because the unversioned symlink to compiler support libraries is no longer provided. This only an issue with mixed programming language links where the linker driver for one language has to link support libraraies for another language. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3532 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-07 19:09:13 -04:00
Q_EMIT finished ();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
QMainWindow::closeEvent (e);
}
void MainWindow::on_stopButton_clicked() //stopButton
{
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
monitor (false);
m_loopall=false;
if(m_bRefSpec) {
MessageBox::information_message (this, tr ("Reference spectrum saved"));
m_bRefSpec=false;
}
}
void MainWindow::on_actionRelease_Notes_triggered ()
{
QDesktopServices::openUrl (QUrl {"http://physics.princeton.edu/pulsar/k1jt/Release_Notes.txt"});
}
void MainWindow::on_actionFT8_DXpedition_Mode_User_Guide_triggered()
{
QDesktopServices::openUrl (QUrl {"http://physics.princeton.edu/pulsar/k1jt/FT8_DXpedition_Mode.pdf"});
}
void MainWindow::on_actionQuick_Start_Guide_triggered()
{
QDesktopServices::openUrl (QUrl {"https://physics.princeton.edu/pulsar/k1jt/FST4_Quick_Start.pdf"});
}
void MainWindow::on_actionOnline_User_Guide_triggered() //Display manual
{
#if defined (CMAKE_BUILD)
m_manual.display_html_url (QUrl {PROJECT_MANUAL_DIRECTORY_URL}, PROJECT_MANUAL);
#endif
}
//Display local copy of manual
void MainWindow::on_actionLocal_User_Guide_triggered()
{
#if defined (CMAKE_BUILD)
m_manual.display_html_file (m_config.doc_dir (), PROJECT_MANUAL);
#endif
}
void MainWindow::on_actionWide_Waterfall_triggered() //Display Waterfalls
{
m_wideGraph->showNormal();
}
void MainWindow::on_actionEcho_Graph_triggered()
{
m_echoGraph->showNormal();
}
void MainWindow::on_actionFast_Graph_triggered()
{
m_fastGraph->showNormal();
}
void MainWindow::on_actionSolve_FreqCal_triggered()
{
QString dpath{QDir::toNativeSeparators(m_config.writeable_data_dir().absolutePath()+"/")};
char data_dir[512];
int len=dpath.length();
int iz,irc;
double a,b,rms,sigmaa,sigmab;
strncpy(data_dir,dpath.toLatin1(),len);
calibrate_(data_dir,&iz,&a,&b,&rms,&sigmaa,&sigmab,&irc,len);
QString t2;
if(irc==-1) t2="Cannot open " + dpath + "fmt.all";
if(irc==-2) t2="Cannot open " + dpath + "fcal2.out";
if(irc==-3) t2="Insufficient data in fmt.all";
if(irc==-4) t2 = tr ("Invalid data in fmt.all at line %1").arg (iz);
if(irc>0 or rms>1.0) t2="Check fmt.all for possible bad data.";
if (irc < 0 || irc > 0 || rms > 1.) {
MessageBox::warning_message (this, "Calibration Error", t2);
}
else if (MessageBox::Apply == MessageBox::query_message (this
, tr ("Good Calibration Solution")
, tr ("<pre>"
"%1%L2 ±%L3 ppm\n"
"%4%L5 ±%L6 Hz\n\n"
"%7%L8\n"
"%9%L10 Hz"
"</pre>")
.arg ("Slope: ", 12).arg (b, 0, 'f', 3).arg (sigmab, 0, 'f', 3)
.arg ("Intercept: ", 12).arg (a, 0, 'f', 2).arg (sigmaa, 0, 'f', 2)
.arg ("N: ", 12).arg (iz)
.arg ("StdDev: ", 12).arg (rms, 0, 'f', 2)
, QString {}
, MessageBox::Cancel | MessageBox::Apply)) {
m_config.set_calibration (Configuration::CalibrationParams {a, b});
if (MessageBox::Yes == MessageBox::query_message (this
, tr ("Delete Calibration Measurements")
, tr ("The \"fmt.all\" file will be renamed as \"fmt.bak\""))) {
// rename fmt.all as we have consumed the resulting calibration
// solution
auto const& backup_file_name = m_config.writeable_data_dir ().absoluteFilePath ("fmt.bak");
QFile::remove (backup_file_name);
QFile::rename (m_config.writeable_data_dir ().absoluteFilePath ("fmt.all"), backup_file_name);
}
}
}
void MainWindow::on_actionCopyright_Notice_triggered()
{
auto const& message = tr("If you make fair use of any part of WSJT-X under terms of the GNU "
"General Public License, you must display the following copyright "
"notice prominently in your derivative work:\n\n"
"\"The algorithms, source code, look-and-feel of WSJT-X and related "
"programs, and protocol specifications for the modes FSK441, FT8, JT4, "
"JT6M, JT9, JT65, JTMS, QRA64, ISCAT, MSK144 are Copyright (C) "
2020-04-10 11:19:42 -04:00
"2001-2020 by one or more of the following authors: Joseph Taylor, "
"K1JT; Bill Somerville, G4WJS; Steven Franke, K9AN; Nico Palermo, "
"IV3NWV; Greg Beam, KI7MT; Michael Black, W9MDB; Edson Pereira, PY2SDR; "
"Philip Karn, KA9Q; and other members of the WSJT Development Group.\"");
MessageBox::warning_message(this, message);
}
void MainWindow::on_actionSWL_Mode_triggered (bool checked)
{
ui->lower_panel_widget->setVisible (!checked);
if (checked)
{
hideMenus (false); // make sure we can be turned off
}
}
// This allows the window to shrink by removing certain things
// and reducing space used by controls
void MainWindow::hideMenus(bool checked)
{
int spacing = checked ? 1 : 6;
if (checked) {
statusBar ()->removeWidget (&auto_tx_label);
minimumSize().setHeight(450);
minimumSize().setWidth(700);
restoreGeometry(m_geometryNoControls);
updateGeometry();
} else {
m_geometryNoControls = saveGeometry();
statusBar ()->addWidget(&auto_tx_label);
minimumSize().setHeight(520);
minimumSize().setWidth(770);
}
ui->menuBar->setVisible(!checked);
if(m_mode!="FreqCal" and m_mode!="WSPR" and m_mode!="FST4W") {
ui->lh_decodes_title_label->setVisible(!checked);
ui->rh_decodes_title_label->setVisible(!checked);
}
ui->lh_decodes_headings_label->setVisible(!checked);
ui->rh_decodes_headings_label->setVisible(!checked);
ui->gridLayout_5->layout()->setSpacing(spacing);
ui->horizontalLayout_2->layout()->setSpacing(spacing);
ui->horizontalLayout_5->layout()->setSpacing(spacing);
ui->horizontalLayout_6->layout()->setSpacing(spacing);
ui->horizontalLayout_7->layout()->setSpacing(spacing);
ui->horizontalLayout_8->layout()->setSpacing(spacing);
ui->horizontalLayout_9->layout()->setSpacing(spacing);
ui->horizontalLayout_10->layout()->setSpacing(spacing);
ui->horizontalLayout_11->layout()->setSpacing(spacing);
ui->horizontalLayout_12->layout()->setSpacing(spacing);
ui->horizontalLayout_13->layout()->setSpacing(spacing);
ui->horizontalLayout_14->layout()->setSpacing(spacing);
ui->rh_decodes_widget->layout()->setSpacing(spacing);
ui->verticalLayout_2->layout()->setSpacing(spacing);
ui->verticalLayout_3->layout()->setSpacing(spacing);
ui->verticalLayout_5->layout()->setSpacing(spacing);
ui->verticalLayout_7->layout()->setSpacing(spacing);
ui->verticalLayout_8->layout()->setSpacing(spacing);
ui->tab->layout()->setSpacing(spacing);
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
void MainWindow::on_actionAstronomical_data_toggled (bool checked)
{
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (checked)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
m_astroWidget.reset (new Astro {m_settings, &m_config});
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// hook up termination signal
connect (this, &MainWindow::finished, m_astroWidget.data (), &Astro::close);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
connect (m_astroWidget.data (), &Astro::tracking_update, [this] {
m_astroCorrection = {};
setRig ();
setXIT (ui->TxFreqSpinBox->value ());
displayDialFrequency ();
});
m_astroWidget->showNormal();
m_astroWidget->raise ();
m_astroWidget->activateWindow ();
m_astroWidget->nominal_frequency (m_freqNominal, m_freqTxNominal);
}
else
{
m_astroWidget.reset ();
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
void MainWindow::on_fox_log_action_triggered()
{
if (!m_foxLogWindow)
{
m_foxLogWindow.reset (new FoxLogWindow {m_settings, &m_config, m_logBook.fox_log ()});
// Connect signals from fox log window
connect (this, &MainWindow::finished, m_foxLogWindow.data (), &FoxLogWindow::close);
connect (m_foxLogWindow.data (), &FoxLogWindow::reset_log_model, [this] () {
m_logBook.fox_log ()->reset ();
});
}
m_foxLogWindow->showNormal ();
m_foxLogWindow->raise ();
m_foxLogWindow->activateWindow ();
}
void MainWindow::on_contest_log_action_triggered()
{
if (!m_contestLogWindow)
{
m_contestLogWindow.reset (new CabrilloLogWindow {m_settings, &m_config, m_logBook.contest_log ()->model ()});
// Connect signals from contest log window
connect (this, &MainWindow::finished, m_contestLogWindow.data (), &CabrilloLogWindow::close);
}
m_contestLogWindow->showNormal ();
m_contestLogWindow->raise ();
m_contestLogWindow->activateWindow ();
}
void MainWindow::on_actionColors_triggered()
{
if (!m_colorHighlighting)
{
m_colorHighlighting.reset (new ColorHighlighting {m_settings, m_config.decode_highlighting ()});
connect (&m_config, &Configuration::decode_highlighting_changed, m_colorHighlighting.data (), &ColorHighlighting::set_items);
}
m_colorHighlighting->showNormal ();
m_colorHighlighting->raise ();
m_colorHighlighting->activateWindow ();
}
void MainWindow::on_actionMessage_averaging_triggered()
{
if(m_msgAvgWidget == NULL) {
m_msgAvgWidget.reset (new MessageAveraging {m_settings, m_config.decoded_text_font ()});
// Connect signals from Message Averaging window
connect (this, &MainWindow::finished, m_msgAvgWidget.data (), &MessageAveraging::close);
}
m_msgAvgWidget->showNormal();
m_msgAvgWidget->raise();
m_msgAvgWidget->activateWindow();
}
void MainWindow::on_actionOpen_triggered() //Open File
{
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
monitor (false);
QString fname;
fname=QFileDialog::getOpenFileName(this, "Open File", m_path,
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
"WSJT Files (*.wav)");
if(!fname.isEmpty ()) {
m_path=fname;
int i1=fname.lastIndexOf("/");
QString baseName=fname.mid(i1+1);
tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #99ffff}");
tx_status_label.setText(" " + baseName + " ");
on_stopButton_clicked();
m_diskData=true;
read_wav_file (fname);
}
}
void MainWindow::read_wav_file (QString const& fname)
{
// call diskDat() when done
int i0=fname.lastIndexOf("_");
int i1=fname.indexOf(".wav");
m_nutc0=m_UTCdisk;
m_UTCdisk=fname.mid(i0+1,i1-i0-1).toInt();
m_wav_future_watcher.setFuture (QtConcurrent::run ([this, fname] {
auto basename = fname.mid (fname.lastIndexOf ('/') + 1);
auto pos = fname.indexOf (".wav", 0, Qt::CaseInsensitive);
// global variables and threads do not mix well, this needs changing
dec_data.params.nutc = 0;
if (pos > 0) {
if (pos == fname.indexOf ('_', -11) + 7) {
dec_data.params.nutc = fname.mid (pos - 6, 6).toInt ();
m_fileDateTime=fname.mid(pos-13,13);
} else {
dec_data.params.nutc = 100 * fname.mid (pos - 4, 4).toInt ();
m_fileDateTime=fname.mid(pos-11,11);
}
}
BWFFile file {QAudioFormat {}, fname};
bool ok=file.open (BWFFile::ReadOnly);
if(ok) {
auto bytes_per_frame = file.format ().bytesPerFrame ();
int nsamples=m_TRperiod * RX_SAMPLE_RATE;
qint64 max_bytes = std::min (std::size_t (nsamples),
sizeof (dec_data.d2) / sizeof (dec_data.d2[0]))* bytes_per_frame;
auto n = file.read (reinterpret_cast<char *> (dec_data.d2),
std::min (max_bytes, file.size ()));
int frames_read = n / bytes_per_frame;
// zero unfilled remaining sample space
std::memset(&dec_data.d2[frames_read],0,max_bytes - n);
if (11025 == file.format ().sampleRate ()) {
short sample_size = file.format ().sampleSize ();
wav12_ (dec_data.d2, dec_data.d2, &frames_read, &sample_size);
}
dec_data.params.kin = frames_read;
dec_data.params.newdat = 1;
} else {
dec_data.params.kin = 0;
dec_data.params.newdat = 0;
}
if(basename.mid(0,10)=="000000_000" && m_mode == "FT8") {
int isec=15*basename.mid(10,3).toInt();
int ih=isec/3600;
int im=(isec-3600*ih)/60;
isec=isec%60;
dec_data.params.nutc=3600*ih+60*im+isec;
}
}));
}
void MainWindow::on_actionOpen_next_in_directory_triggered() //Open Next
{
if(m_decoderBusy) return;
monitor (false);
int i,len;
QFileInfo fi(m_path);
QStringList list;
list= fi.dir().entryList().filter(".wav",Qt::CaseInsensitive);
for (i = 0; i < list.size()-1; ++i) {
len=list.at(i).length();
if(list.at(i)==m_path.right(len)) {
int n=m_path.length();
QString fname=m_path.replace(n-len,len,list.at(i+1));
m_path=fname;
int i1=fname.lastIndexOf("/");
QString baseName=fname.mid(i1+1);
tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #99ffff}");
tx_status_label.setText(" " + baseName + " ");
m_diskData=true;
read_wav_file (fname);
if(m_loopall and (i==list.size()-2)) {
m_loopall=false;
m_bNoMoreFiles=true;
}
return;
}
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
//Open all remaining files
void MainWindow::on_actionDecode_remaining_files_in_directory_triggered()
{
if(m_decoderBusy) return;
m_loopall=true;
on_actionOpen_next_in_directory_triggered();
}
void MainWindow::diskDat() //diskDat()
{
if(dec_data.params.kin>0) {
int k;
int kstep=m_FFTSize;
m_diskData=true;
float db=m_config.degrade();
float bw=m_config.RxBandwidth();
if(db > 0.0) degrade_snr_(dec_data.d2,&dec_data.params.kin,&db,&bw);
for(int n=1; n<=m_hsymStop; n++) { // Do the waterfall spectra
// k=(n+1)*kstep; //### Why was this (n+1) ??? ###
k=n*kstep;
if(k > dec_data.params.kin) break;
dec_data.params.npts8=k/8;
dataSink(k);
qApp->processEvents(); //Update the waterfall
}
} else {
MessageBox::information_message(this, tr("No data read from disk. Wrong file format?"));
}
}
//Delete ../save/*.wav
void MainWindow::on_actionDelete_all_wav_files_in_SaveDir_triggered()
{
auto button = MessageBox::query_message (this, tr ("Confirm Delete"),
tr ("Are you sure you want to delete all *.wav and *.c2 files in \"%1\"?")
.arg (QDir::toNativeSeparators (m_config.save_directory ().absolutePath ())));
if (MessageBox::Yes == button) {
Q_FOREACH (auto const& file
, m_config.save_directory ().entryList ({"*.wav", "*.c2"}, QDir::Files | QDir::Writable)) {
m_config.save_directory ().remove (file);
}
}
}
void MainWindow::on_actionNone_triggered() //Save None
{
m_saveDecoded=false;
m_saveAll=false;
ui->actionNone->setChecked(true);
}
void MainWindow::on_actionSave_decoded_triggered()
{
m_saveDecoded=true;
m_saveAll=false;
ui->actionSave_decoded->setChecked(true);
}
void MainWindow::on_actionSave_all_triggered() //Save All
{
m_saveDecoded=false;
m_saveAll=true;
ui->actionSave_all->setChecked(true);
}
void MainWindow::on_actionKeyboard_shortcuts_triggered()
{
if (!m_shortcuts)
{
QFont font;
font.setPointSize (10);
2020-07-29 13:44:34 -04:00
m_shortcuts.reset (new HelpTextWindow {tr ("Keyboard Shortcuts"),
//: Keyboard shortcuts help window contents
tr (R"(<table cellspacing=1>
<tr><td><b>Esc </b></td><td>Stop Tx, abort QSO, clear next-call queue</td></tr>
<tr><td><b>F1 </b></td><td>Online User's Guide (Alt: transmit Tx6)</td></tr>
<tr><td><b>Shift+F1 </b></td><td>Copyright Notice</td></tr>
<tr><td><b>Ctrl+F1 </b></td><td>About WSJT-X</td></tr>
<tr><td><b>F2 </b></td><td>Open settings window (Alt: transmit Tx2)</td></tr>
<tr><td><b>F3 </b></td><td>Display keyboard shortcuts (Alt: transmit Tx3)</td></tr>
<tr><td><b>F4 </b></td><td>Clear DX Call, DX Grid, Tx messages 1-4 (Alt: transmit Tx4)</td></tr>
<tr><td><b>Alt+F4 </b></td><td>Exit program</td></tr>
<tr><td><b>F5 </b></td><td>Display special mouse commands (Alt: transmit Tx5)</td></tr>
<tr><td><b>F6 </b></td><td>Open next file in directory (Alt: toggle "Call 1st")</td></tr>
2020-09-15 10:53:14 -04:00
<tr><td><b>Shift+F6 </b></td><td>Decode all remaining files in directory</td></tr>
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<tr><td><b>F7 </b></td><td>Display Message Averaging window</td></tr>
<tr><td><b>F11 </b></td><td>Move Rx frequency down 1 Hz</td></tr>
<tr><td><b>Ctrl+F11 </b></td><td>Move identical Rx and Tx frequencies down 1 Hz</td></tr>
<tr><td><b>Shift+F11 </b></td><td>Move Tx frequency down 60 Hz (FT8) or 90 Hz (FT4)</td></tr>
<tr><td><b>Ctrl+Shift+F11 </b></td><td>Move dial frequency down 2000 Hz</td></tr>
<tr><td><b>F12 </b></td><td>Move Rx frequency up 1 Hz</td></tr>
<tr><td><b>Ctrl+F12 </b></td><td>Move identical Rx and Tx frequencies up 1 Hz</td></tr>
<tr><td><b>Shift+F12 </b></td><td>Move Tx frequency up 60 Hz (FT8) or 90 Hz (FT4)</td></tr>
<tr><td><b>Ctrl+Shift+F12 </b></td><td>Move dial frequency up 2000 Hz</td></tr>
<tr><td><b>Alt+1-6 </b></td><td>Set now transmission to this number on Tab 1</td></tr>
<tr><td><b>Ctl+1-6 </b></td><td>Set next transmission to this number on Tab 1</td></tr>
<tr><td><b>Alt+B </b></td><td>Toggle "Best S+P" status</td></tr>
<tr><td><b>Alt+C </b></td><td>Toggle "Call 1st" checkbox</td></tr>
<tr><td><b>Alt+D </b></td><td>Decode again at QSO frequency</td></tr>
<tr><td><b>Shift+D </b></td><td>Full decode (both windows)</td></tr>
<tr><td><b>Ctrl+E </b></td><td>Turn on TX even/1st</td></tr>
<tr><td><b>Shift+E </b></td><td>Turn off TX even/1st</td></tr>
<tr><td><b>Alt+E </b></td><td>Erase</td></tr>
<tr><td><b>Ctrl+F </b></td><td>Edit the free text message box</td></tr>
<tr><td><b>Alt+G </b></td><td>Generate standard messages</td></tr>
<tr><td><b>Alt+H </b></td><td>Halt Tx</td></tr>
<tr><td><b>Ctrl+L </b></td><td>Lookup callsign in database, generate standard messages</td></tr>
<tr><td><b>Alt+M </b></td><td>Monitor</td></tr>
<tr><td><b>Alt+N </b></td><td>Enable Tx</td></tr>
<tr><td><b>Ctrl+O </b></td><td>Open a .wav file</td></tr>
<tr><td><b>Alt+O </b></td><td>Change operator</td></tr>
<tr><td><b>Alt+Q </b></td><td>Log QSO</td></tr>
<tr><td><b>Ctrl+R </b></td><td>Set Tx4 message to RRR (not in FT4)</td></tr>
<tr><td><b>Alt+R </b></td><td>Set Tx4 message to RR73</td></tr>
<tr><td><b>Alt+S </b></td><td>Stop monitoring</td></tr>
<tr><td><b>Alt+T </b></td><td>Toggle Tune status</td></tr>
<tr><td><b>Alt+Z </b></td><td>Clear hung decoder status</td></tr>
</table>)"), font});
}
m_shortcuts->showNormal ();
m_shortcuts->raise ();
}
void MainWindow::on_actionSpecial_mouse_commands_triggered()
{
if (!m_mouseCmnds)
{
QFont font;
font.setPointSize (10);
2020-07-29 13:44:34 -04:00
m_mouseCmnds.reset (new HelpTextWindow {tr ("Special Mouse Commands"),
//: Mouse commands help window contents
tr (R"(<table cellpadding=5>
<tr>
<th align="right">Click on</th>
<th align="left">Action</th>
</tr>
<tr>
<td align="right">Waterfall:</td>
<td><b>Click</b> to set Rx frequency.<br/>
<b>Shift-click</b> to set Tx frequency.<br/>
<b>Ctrl-click</b> or <b>Right-click</b> to set Rx and Tx frequencies.<br/>
2020-08-13 05:30:49 -04:00
<b>Double-click</b> to also decode at Rx frequency.<br/>
2020-07-29 13:44:34 -04:00
</td>
</tr>
<tr>
<td align="right">Decoded text:</td>
<td><b>Double-click</b> to copy second callsign to Dx Call,<br/>
locator to Dx Grid, change Rx and Tx frequency to<br/>
decoded signal's frequency, and generate standard<br/>
2020-08-13 05:30:49 -04:00
messages.<br/>
If <b>Hold Tx Freq</b> is checked or first callsign in message<br/>
is your own call, Tx frequency is not changed unless <br/>
<b>Ctrl</b> is held down.<br/>
2020-07-29 13:44:34 -04:00
</td>
</tr>
<tr>
<td align="right">Erase button:</td>
<td><b>Click</b> to erase QSO window.<br/>
<b>Double-click</b> to erase QSO and Band Activity windows.
</td>
</tr>
</table>)"), font});
}
m_mouseCmnds->showNormal ();
m_mouseCmnds->raise ();
}
void MainWindow::on_DecodeButton_clicked (bool /* checked */) //Decode request
{
if(m_mode=="MSK144") {
ui->DecodeButton->setChecked(false);
} else {
if(m_mode!="WSPR" && !m_decoderBusy) {
dec_data.params.newdat=0;
dec_data.params.nagain=1;
decode();
}
}
}
void MainWindow::freezeDecode(int n) //freezeDecode()
{
if((n%100)==2) {
if(m_mode=="FST4" and m_config.single_decode() and ui->sbFtol->value()>10) ui->sbFtol->setValue(10);
on_DecodeButton_clicked (true);
}
}
void MainWindow::on_ClrAvgButton_clicked()
{
m_nclearave=1;
if(m_msgAvgWidget != NULL) {
if(m_msgAvgWidget->isVisible()) m_msgAvgWidget->displayAvg("");
}
}
void MainWindow::msgAvgDecode2()
{
on_DecodeButton_clicked (true);
}
void MainWindow::decode() //decode()
{
if(m_decoderBusy) return; //Don't start decoder if it's already busy.
QDateTime now = QDateTime::currentDateTimeUtc ();
if( m_dateTimeLastTX.isValid () ) {
qint64 isecs_since_tx = m_dateTimeLastTX.secsTo(now);
dec_data.params.lapcqonly= (isecs_since_tx > 300);
} else {
m_dateTimeLastTX = now.addSecs(-900);
dec_data.params.lapcqonly=true;
}
if( m_diskData ) {
dec_data.params.lapcqonly=false;
}
if(!m_dataAvailable or m_TRperiod==0.0) return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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ui->DecodeButton->setChecked (true);
if(!dec_data.params.nagain && m_diskData && m_TRperiod >= 60.) {
dec_data.params.nutc=dec_data.params.nutc/100;
}
if(dec_data.params.nagain==0 && dec_data.params.newdat==1 && (!m_diskData)) {
m_dateTimeSeqStart = qt_truncate_date_time_to (QDateTime::currentDateTimeUtc (), m_TRperiod * 1.e3);
auto t = m_dateTimeSeqStart.time ();
dec_data.params.nutc = t.hour () * 100 + t.minute ();
if (m_TRperiod < 60.)
{
dec_data.params.nutc = dec_data.params.nutc * 100 + t.second ();
}
}
if(m_nPick==1 and !m_diskData) {
QDateTime t=QDateTime::currentDateTimeUtc();
int ihr=t.toString("hh").toInt();
int imin=t.toString("mm").toInt();
int isec=t.toString("ss").toInt();
isec=isec - fmod(double(isec),m_TRperiod);
dec_data.params.nutc=10000*ihr + 100*imin + isec;
}
if(m_nPick==2) dec_data.params.nutc=m_nutc0;
dec_data.params.nQSOProgress = m_QSOProgress;
dec_data.params.nfqso=m_wideGraph->rxFreq();
dec_data.params.nftx = ui->TxFreqSpinBox->value ();
qint32 depth {m_ndepth};
if (!ui->actionInclude_averaging->isVisible ()) depth &= ~16;
if (!ui->actionInclude_correlation->isVisible ()) depth &= ~32;
if (!ui->actionEnable_AP_DXcall->isVisible ()) depth &= ~64;
dec_data.params.ndepth=depth;
dec_data.params.n2pass=1;
if(m_config.twoPass()) dec_data.params.n2pass=2;
dec_data.params.nranera=m_config.ntrials();
dec_data.params.naggressive=m_config.aggressive();
dec_data.params.nrobust=0;
dec_data.params.ndiskdat=0;
if(m_diskData) dec_data.params.ndiskdat=1;
dec_data.params.nfa=m_wideGraph->nStartFreq();
dec_data.params.nfSplit=m_wideGraph->Fmin();
dec_data.params.nfb=m_wideGraph->Fmax();
if(m_mode=="FT8" and SpecOp::HOUND == m_config.special_op_id() and !ui->cbRxAll->isChecked()) dec_data.params.nfb=1000;
if(m_mode=="FT8" and SpecOp::FOX == m_config.special_op_id() ) dec_data.params.nfqso=200;
dec_data.params.ntol=ui->sbFtol->value ();
if(m_mode=="JT9+JT65" or !m_config.enable_VHF_features()) {
dec_data.params.ntol=20;
dec_data.params.naggressive=0;
}
if(m_mode=="FST4") {
dec_data.params.ntol=ui->sbFtol->value();
if(m_config.single_decode()) {
dec_data.params.nfa=m_wideGraph->rxFreq() - ui->sbFtol->value();
dec_data.params.nfb=m_wideGraph->rxFreq() + ui->sbFtol->value();
} else {
dec_data.params.nfa=ui->sbF_Low->value();
dec_data.params.nfb=ui->sbF_High->value();
}
}
if(m_mode=="FST4W") dec_data.params.ntol=ui->sbFST4W_FTol->value();
if(dec_data.params.nutc < m_nutc0) m_RxLog = 1; //Date and Time to file "ALL.TXT".
if(dec_data.params.newdat==1 and !m_diskData) m_nutc0=dec_data.params.nutc;
dec_data.params.ntxmode=9;
if(m_modeTx=="JT65") dec_data.params.ntxmode=65;
dec_data.params.nmode=9;
if(m_mode=="JT65") dec_data.params.nmode=65;
if(m_mode=="JT65") dec_data.params.ljt65apon = ui->actionEnable_AP_JT65->isVisible () &&
ui->actionEnable_AP_JT65->isChecked ();
if(m_mode=="QRA64") dec_data.params.nmode=164;
if(m_mode=="QRA64") dec_data.params.ntxmode=164;
if(m_mode=="JT9+JT65") dec_data.params.nmode=9+65; // = 74
if(m_mode=="JT4") {
dec_data.params.nmode=4;
dec_data.params.ntxmode=4;
}
if(m_mode=="FT8") dec_data.params.nmode=8;
if(m_mode=="FT8") dec_data.params.lft8apon = ui->actionEnable_AP_FT8->isVisible () &&
ui->actionEnable_AP_FT8->isChecked ();
if(m_mode=="FT8") dec_data.params.napwid=50;
if(m_mode=="FT4") {
dec_data.params.nmode=5;
m_BestCQpriority="";
}
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if(m_mode=="FST4") dec_data.params.nmode=240;
if(m_mode=="FST4W") dec_data.params.nmode=241;
dec_data.params.ntrperiod=m_TRperiod;
dec_data.params.nsubmode=m_nSubMode;
if(m_mode=="QRA64") dec_data.params.nsubmode=100 + m_nSubMode;
dec_data.params.minw=0;
dec_data.params.nclearave=m_nclearave;
if(m_nclearave!=0) {
QFile f(m_config.temp_dir ().absoluteFilePath ("avemsg.txt"));
f.remove();
}
dec_data.params.dttol=m_DTtol;
dec_data.params.emedelay=0.0;
if(m_config.decode_at_52s()) dec_data.params.emedelay=2.5;
dec_data.params.minSync=ui->syncSpinBox->isVisible () ? m_minSync : 0;
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dec_data.params.nexp_decode = static_cast<int> (m_config.special_op_id());
if(m_config.single_decode()) dec_data.params.nexp_decode += 32;
if(m_config.enable_VHF_features()) dec_data.params.nexp_decode += 64;
if(m_mode.startsWith("FST4")) dec_data.params.nexp_decode += 256*(ui->sbNB->value()+3);
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::memcpy(dec_data.params.datetime, m_dateTime.toLatin1()+" ", sizeof dec_data.params.datetime);
::memcpy(dec_data.params.mycall, (m_config.my_callsign()+" ").toLatin1(), sizeof dec_data.params.mycall);
::memcpy(dec_data.params.mygrid, (m_config.my_grid()+" ").toLatin1(), sizeof dec_data.params.mygrid);
QString hisCall {ui->dxCallEntry->text ()};
QString hisGrid {ui->dxGridEntry->text ()};
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memcpy(dec_data.params.hiscall,(hisCall + " ").toLatin1 ().constData (), sizeof dec_data.params.hiscall);
memcpy(dec_data.params.hisgrid,(hisGrid + " ").toLatin1 ().constData (), sizeof dec_data.params.hisgrid);
//newdat=1 ==> this is new data, must do the big FFT
//nagain=1 ==> decode only at fQSO +/- Tol
if (auto * to = reinterpret_cast<char *> (mem_jt9->data()))
{
char *from = (char*) dec_data.ipc;
int size=sizeof(struct dec_data);
if(dec_data.params.newdat==0) {
int noffset {offsetof (struct dec_data, params.nutc)};
to += noffset;
from += noffset;
size -= noffset;
}
if(m_mode=="ISCAT" or m_mode=="MSK144" or m_bFast9) {
float t0=m_t0;
float t1=m_t1;
qApp->processEvents(); //Update the waterfall
if(m_nPick > 0) {
t0=m_t0Pick;
t1=m_t1Pick;
}
static short int d2b[360000];
narg[0]=dec_data.params.nutc;
if(m_kdone>int(12000.0*m_TRperiod)) {
m_kdone=int(12000.0*m_TRperiod);
}
narg[1]=m_kdone;
narg[2]=m_nSubMode;
narg[3]=dec_data.params.newdat;
narg[4]=dec_data.params.minSync;
narg[5]=m_nPick;
narg[6]=1000.0*t0;
narg[7]=1000.0*t1;
narg[8]=2; //Max decode lines per decode attempt
if(dec_data.params.minSync<0) narg[8]=50;
if(m_mode=="ISCAT") narg[9]=101; //ISCAT
if(m_mode=="JT9") narg[9]=102; //Fast JT9
if(m_mode=="MSK144") narg[9]=104; //MSK144
narg[10]=ui->RxFreqSpinBox->value();
narg[11]=ui->sbFtol->value ();
narg[12]=0;
narg[13]=-1;
narg[14]=m_config.aggressive();
memcpy(d2b,dec_data.d2,2*360000);
watcher3.setFuture (QtConcurrent::run (std::bind (fast_decode_,&d2b[0],
&narg[0],&m_TRperiod,&m_msg[0][0],
dec_data.params.mycall,dec_data.params.hiscall,8000,12,12)));
} else {
mem_jt9->lock ();
memcpy(to, from, qMin(mem_jt9->size(), size));
mem_jt9->unlock ();
to_jt9(m_ihsym,1,-1); //Send m_ihsym to jt9[.exe] and start decoding
decodeBusy(true);
}
}
}
void::MainWindow::fast_decode_done()
{
float t,tmax=-99.0;
dec_data.params.nagain=false;
dec_data.params.ndiskdat=false;
// if(m_msg[0][0]==0) m_bDecoded=false;
for(int i=0; m_msg[i][0] && i<100; i++) {
QString message=QString::fromLatin1(m_msg[i]);
m_msg[i][0]=0;
if(message.length()>80) message=message.left (80);
if(narg[13]/8==narg[12]) message=message.trimmed().replace("<...>",m_calls);
//Left (Band activity) window
DecodedText decodedtext {message.replace (QChar::LineFeed, "")};
if(!m_bFastDone) {
ui->decodedTextBrowser->displayDecodedText (decodedtext,m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand,m_config.ppfx());
}
t=message.mid(10,5).toFloat();
if(t>tmax) {
tmax=t;
m_bDecoded=true;
}
postDecode (true, decodedtext.string ());
write_all("Rx",message);
if(m_mode=="JT9" or m_mode=="MSK144") {
// find and extract any report for myCall
bool stdMsg = decodedtext.report(m_baseCall,
Radio::base_callsign(ui->dxCallEntry->text()), m_rptRcvd);
// extract details and send to PSKreporter
if (stdMsg) pskPost (decodedtext);
}
if (tmax >= 0.0) auto_sequence (decodedtext, ui->sbFtol->value (), ui->sbFtol->value ());
}
m_startAnother=m_loopall;
m_nPick=0;
ui->DecodeButton->setChecked (false);
m_bFastDone=false;
}
void MainWindow::to_jt9(qint32 n, qint32 istart, qint32 idone)
{
if (auto * dd = reinterpret_cast<dec_data_t *> (mem_jt9->data()))
{
mem_jt9->lock ();
dd->ipc[0]=n;
if(istart>=0) dd->ipc[1]=istart;
if(idone>=0) dd->ipc[2]=idone;
mem_jt9->unlock ();
}
}
void MainWindow::decodeDone ()
{
if(m_mode!="FT8" or dec_data.params.nzhsym==50) m_nDecodes=0;
if(m_mode=="QRA64") m_wideGraph->drawRed(0,0);
if ("FST4W" == m_mode)
{
if (m_uploadWSPRSpots
&& m_config.is_transceiver_online ()) { // need working rig control
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
uploadTimer.start(QRandomGenerator::global ()->bounded (0, 20000)); // Upload delay
#else
uploadTimer.start(20000 * qrand()/((double)RAND_MAX + 1.0)); // Upload delay
#endif
}
}
auto tnow = QDateTime::currentDateTimeUtc ();
double tdone = fmod(double(tnow.time().second()),m_TRperiod);
int mswait;
if( tdone < 0.5*m_TRperiod ) {
mswait = 1000.0 * ( 0.75 * m_TRperiod - tdone );
} else {
mswait = 1000.0 * ( 1.75 * m_TRperiod - tdone );
}
if(!m_diskData) killFileTimer.start(mswait); //Kill at 3/4 period
dec_data.params.nagain=0;
dec_data.params.ndiskdat=0;
m_nclearave=0;
// pause_jt9 ();
ui->DecodeButton->setChecked (false);
decodeBusy(false);
m_RxLog=0;
if(SpecOp::FOX == m_config.special_op_id()) houndCallers();
to_jt9(m_ihsym,-1,1); //Tell jt9 we know it has finished
m_startAnother=m_loopall;
if(m_bNoMoreFiles) {
MessageBox::information_message(this, tr("No more files to open."));
m_bNoMoreFiles=false;
}
}
void MainWindow::readFromStdout() //readFromStdout
{
while(proc_jt9.canReadLine()) {
auto line_read = proc_jt9.readLine ();
if (auto p = std::strpbrk (line_read.constData (), "\n\r")) {
// truncate before line ending chars
line_read = line_read.left (p - line_read.constData ());
}
bool haveFSpread {false};
float fSpread {0.};
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if (m_mode.startsWith ("FST4"))
{
auto text = line_read.mid (64, 6).trimmed ();
if (text.size ())
{
fSpread = text.toFloat (&haveFSpread);
line_read = line_read.left (64);
}
auto const& cs = m_config.my_callsign ().toLocal8Bit ();
if ("FST4W" == m_mode && ui->cbNoOwnCall->isChecked ()
&& (line_read.contains (" " + cs + " ")
|| line_read.contains ("<" + cs + ">"))) {
continue;
}
}
if (m_mode!="FT8" and m_mode!="FT4"
&& !m_mode.startsWith ("FST4")) {
//Pad 22-char msg to at least 37 chars
line_read = line_read.left(44) + " " + line_read.mid(44);
}
bool bAvgMsg=false;
int navg=0;
if(line_read.indexOf("<DecodeFinished>") >= 0) {
m_bDecoded = line_read.mid(20).trimmed().toInt() > 0;
if(m_nDecodes==0) ndecodes_label.setText("0");
decodeDone ();
return;
} else {
m_nDecodes+=1;
ndecodes_label.setText(QString::number(m_nDecodes));
if(m_mode=="JT4" or m_mode=="JT65" or m_mode=="QRA64") {
int nf=line_read.indexOf("f");
if(nf>0) {
navg=line_read.mid(nf+1,1).toInt();
if(line_read.indexOf("f*")>0) navg=10;
}
int nd=-1;
if(nf<0) nd=line_read.indexOf("d");
if(nd>0) {
navg=line_read.mid(nd+2,1).toInt();
if(line_read.mid(nd+2,1)=="*") navg=10;
}
if(m_mode=="JT65" or m_mode=="JT4") {
int na=-1;
if(nf<0 and nd<0) na=line_read.indexOf("a");
if(na>0) {
navg=line_read.mid(na+2,1).toInt();
if(line_read.mid(na+2,1)=="*") navg=10;
}
}
if(navg>=2) bAvgMsg=true;
}
write_all("Rx",line_read.trimmed());
int ntime=6;
if(m_TRperiod>=60) ntime=4;
if (line_read.left(ntime) != m_tBlankLine) {
ui->decodedTextBrowser->new_period ();
if (m_config.insert_blank ()
&& SpecOp::FOX != m_config.special_op_id()) {
QString band;
if((QDateTime::currentMSecsSinceEpoch() / 1000 - m_secBandChanged) > 4*int(m_TRperiod)/4) {
band = ' ' + m_config.bands ()->find (m_freqNominal);
}
ui->decodedTextBrowser->insertLineSpacer (band.rightJustified (40, '-'));
}
m_tBlankLine = line_read.left(ntime);
}
if ("FST4W" == m_mode)
{
uploadWSPRSpots (true, line_read);
}
DecodedText decodedtext0 {QString::fromUtf8(line_read.constData())};
DecodedText decodedtext {QString::fromUtf8(line_read.constData()).remove("TU; ")};
if(m_mode=="FT8" and SpecOp::FOX == m_config.special_op_id() and
(decodedtext.string().contains("R+") or decodedtext.string().contains("R-"))) {
auto for_us = decodedtext.string().contains(" " + m_config.my_callsign() + " ") or
decodedtext.string().contains(" "+m_baseCall) or
decodedtext.string().contains(m_baseCall+" ") or
decodedtext.string().contains(" <" + m_config.my_callsign() + "> ");
if(decodedtext.string().contains(" DE ")) for_us=true; //Hound with compound callsign
if(for_us) {
QString houndCall,houndGrid;
decodedtext.deCallAndGrid(/*out*/houndCall,houndGrid);
foxRxSequencer(decodedtext.string(),houndCall,houndGrid);
}
}
//Left (Band activity) window
if(!bAvgMsg) {
if(m_mode=="FT8" and SpecOp::FOX == m_config.special_op_id()) {
if(!m_bDisplayedOnce) {
// This hack sets the font. Surely there's a better way!
DecodedText dt{"."};
ui->decodedTextBrowser->displayDecodedText(dt,m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand,m_config.ppfx());
m_bDisplayedOnce=true;
}
} else {
DecodedText decodedtext1=decodedtext0;
ui->decodedTextBrowser->displayDecodedText(decodedtext1,m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand,m_config.ppfx(),
ui->cbCQonly->isVisible() && ui->cbCQonly->isChecked(),
haveFSpread, fSpread);
if(m_bBestSPArmed and m_mode=="FT4") {
QString messagePriority=ui->decodedTextBrowser->CQPriority();
if(messagePriority!="") {
if(messagePriority=="New Call on Band"
and m_BestCQpriority!="New Call on Band"
and m_BestCQpriority!="New Multiplier") {
m_BestCQpriority="New Call on Band";
processMessage(decodedtext0);
}
if(messagePriority=="New DXCC"
and m_BestCQpriority!="New DXCC"
and m_BestCQpriority!="New Multiplier") {
m_BestCQpriority="New DXCC";
processMessage(decodedtext0);
}
}
}
}
}
//Right (Rx Frequency) window
bool bDisplayRight=bAvgMsg;
int audioFreq=decodedtext.frequencyOffset();
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if(m_mode=="FT8" or m_mode=="FT4" or m_mode=="FST4") {
auto const& parts = decodedtext.string().remove("<").remove(">")
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.split (' ', SkipEmptyParts);
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if (parts.size() > 6) {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
auto for_us = parts[5].contains (m_baseCall)
|| ("DE" == parts[5] && qAbs (ui->RxFreqSpinBox->value () - audioFreq) <= 10);
if(m_baseCall==m_config.my_callsign() and m_baseCall!=parts[5]) for_us=false;
if(m_bCallingCQ && !m_bAutoReply && for_us && ui->cbFirst->isChecked() and
SpecOp::FOX > m_config.special_op_id()) {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_bDoubleClicked=true;
m_bAutoReply = true;
if(SpecOp::FOX != m_config.special_op_id()) processMessage (decodedtext);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
ui->cbFirst->setStyleSheet("");
}
if(SpecOp::FOX==m_config.special_op_id() and decodedtext.string().contains(" DE ")) for_us=true; //Hound with compound callsign
if(SpecOp::FOX==m_config.special_op_id() and for_us and (audioFreq<1000)) bDisplayRight=true;
if(SpecOp::FOX!=m_config.special_op_id() and (for_us or (abs(audioFreq - m_wideGraph->rxFreq()) <= 10))) bDisplayRight=true;
}
} else {
if((abs(audioFreq - m_wideGraph->rxFreq()) <= 10) and
!m_config.enable_VHF_features()) bDisplayRight=true;
}
if (bDisplayRight) {
// This msg is within 10 hertz of our tuned frequency, or a JT4 or JT65 avg,
// or contains MyCall
if(!m_bBestSPArmed or m_mode!="FT4") {
ui->decodedTextBrowser2->displayDecodedText(decodedtext0,m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand,m_config.ppfx());
}
if(m_mode!="JT4") {
bool b65=decodedtext.isJT65();
if(b65 and m_modeTx!="JT65") on_pbTxMode_clicked();
if(!b65 and m_modeTx=="JT65") on_pbTxMode_clicked();
}
m_QSOText = decodedtext.string ().trimmed ();
}
postDecode (true, decodedtext.string ());
if(m_mode=="FT8" and SpecOp::HOUND==m_config.special_op_id()) {
if(decodedtext.string().contains(";")) {
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QStringList w=decodedtext.string().mid(24).split(" ",SkipEmptyParts);
QString foxCall=w.at(3);
foxCall=foxCall.remove("<").remove(">");
if(w.at(0)==m_config.my_callsign() or w.at(0)==Radio::base_callsign(m_config.my_callsign())) {
//### Check for ui->dxCallEntry->text()==foxCall before logging! ###
ui->stopTxButton->click ();
logQSOTimer.start(0);
}
if((w.at(2)==m_config.my_callsign() or w.at(2)==Radio::base_callsign(m_config.my_callsign()))
and ui->tx3->text().length()>0) {
m_rptRcvd=w.at(4);
m_rptSent=decodedtext.string().mid(7,3);
m_nFoxFreq=decodedtext.string().mid(16,4).toInt();
hound_reply ();
}
} else {
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QStringList w=decodedtext.string().mid(24).split(" ",SkipEmptyParts);
if(decodedtext.string().contains("/")) w.append(" +00"); //Add a dummy report
if(w.size()>=3) {
QString foxCall=w.at(1);
if((w.at(0)==m_config.my_callsign() or w.at(0)==Radio::base_callsign(m_config.my_callsign())) and
ui->tx3->text().length()>0) {
if(w.at(2)=="RR73") {
ui->stopTxButton->click ();
logQSOTimer.start(0);
} else {
if(w.at(1)==Radio::base_callsign(ui->dxCallEntry->text()) and
(w.at(2).mid(0,1)=="+" or w.at(2).mid(0,1)=="-")) {
m_rptRcvd=w.at(2);
m_rptSent=decodedtext.string().mid(7,3);
m_nFoxFreq=decodedtext.string().mid(16,4).toInt();
hound_reply ();
}
}
}
}
}
}
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//### I think this is where we are preventing Hounds from spotting Fox ###
if(m_mode!="FT8" or (SpecOp::HOUND != m_config.special_op_id())) {
if(m_mode=="FT8" or m_mode=="FT4" or m_mode=="QRA64" or m_mode=="JT4"
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or m_mode=="JT65" or m_mode=="JT9" or m_mode=="FST4") {
auto_sequence (decodedtext, 25, 50);
}
// find and extract any report for myCall, but save in m_rptRcvd only if it's from DXcall
QString rpt;
bool stdMsg = decodedtext.report(m_baseCall,
Radio::base_callsign(ui->dxCallEntry->text()), rpt);
QString deCall;
QString grid;
decodedtext.deCallAndGrid(/*out*/deCall,grid);
{
auto t = Radio::base_callsign (ui->dxCallEntry->text ());
if ((t == deCall || ui->dxCallEntry->text () == deCall || !t.size ()) && rpt.size ()) m_rptRcvd = rpt;
}
// extract details and send to PSKreporter
int nsec=QDateTime::currentMSecsSinceEpoch()/1000-m_secBandChanged;
bool okToPost=(nsec > int(4*m_TRperiod)/5);
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if(m_mode=="FST4W" and okToPost) {
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line_read=line_read.left(22) + " CQ " + line_read.trimmed().mid(22);
auto p = line_read.lastIndexOf (' ');
DecodedText FST4W_post {QString::fromUtf8 (line_read.left (p).constData ())};
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pskPost(FST4W_post);
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} else {
if (stdMsg && okToPost) pskPost(decodedtext);
}
if((m_mode=="JT4" or m_mode=="JT65" or m_mode=="QRA64") and m_msgAvgWidget!=NULL) {
if(m_msgAvgWidget->isVisible()) {
QFile f(m_config.temp_dir ().absoluteFilePath ("avemsg.txt"));
if(f.open(QIODevice::ReadOnly | QIODevice::Text)) {
QTextStream s(&f);
QString t=s.readAll();
m_msgAvgWidget->displayAvg(t);
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
}
}
}
}
//
// start_tolerance - only respond to "DE ..." and free text 73
// messages within +/- this value
//
// stop_tolerance - kill Tx if running station is seen to reply to
// another caller and we are going to transmit within
// +/- this value of the reply to another caller
//
void MainWindow::auto_sequence (DecodedText const& message, unsigned start_tolerance, unsigned stop_tolerance)
{
auto const& message_words = message.messageWords ();
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auto is_73 = message_words.filter (QRegularExpression {"^(73|RR73)$"}).size();
bool is_OK=false;
if(m_mode=="MSK144" and message.string().indexOf(ui->dxCallEntry->text()+" R ")>0) is_OK=true;
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if (message_words.size () > 2 && (message.isStandardMessage() || (is_73 or is_OK))) {
auto df = message.frequencyOffset ();
auto within_tolerance = (qAbs (ui->RxFreqSpinBox->value () - df) <= int (start_tolerance)
|| qAbs (ui->TxFreqSpinBox->value () - df) <= int (start_tolerance));
bool acceptable_73 = is_73
&& m_QSOProgress >= ROGER_REPORT
&& ((message.isStandardMessage ()
&& (message_words.contains (m_baseCall)
|| message_words.contains (m_config.my_callsign ())
|| message_words.contains (ui->dxCallEntry->text ())
|| message_words.contains (Radio::base_callsign (ui->dxCallEntry->text ()))
|| message_words.contains ("DE")))
|| !message.isStandardMessage ()); // free text 73/RR73
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QStringList w=message.string().mid(22).remove("<").remove(">").split(" ",SkipEmptyParts);
QString w2;
int nrpt=0;
if (w.size () > 2)
{
w2=w.at(2);
if(w.size()>3) {
nrpt=w2.toInt();
if(w2=="R") nrpt=w.at(3).toInt();
}
}
bool bEU_VHF=(nrpt>=520001 and nrpt<=594000);
if(bEU_VHF and message.string().contains("<"+m_config.my_callsign() + "> ")) {
m_xRcvd=message.string().trimmed().right(13);
}
if (m_auto
&& (m_QSOProgress==REPLYING or (!ui->tx1->isEnabled () and m_QSOProgress==REPORT))
&& qAbs (ui->TxFreqSpinBox->value () - df) <= int (stop_tolerance)
&& message_words.at (1) != "DE"
&& !message_words.at (1).contains (QRegularExpression {"(^(CQ|QRZ))|" + m_baseCall})
&& message_words.at (2).contains (Radio::base_callsign (ui->dxCallEntry->text ()))) {
// auto stop to avoid accidental QRM
ui->stopTxButton->click (); // halt any transmission
} else if (m_auto // transmit allowed
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
&& ui->cbAutoSeq->isVisible () && ui->cbAutoSeq->isChecked() // auto-sequencing allowed
&& ((!m_bCallingCQ // not calling CQ/QRZ
&& !m_sentFirst73 // not finished QSO
&& ((message_words.at (1).contains (m_baseCall)
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
// being called and not already in a QSO
&& (message_words.at(2).contains(Radio::base_callsign(ui->dxCallEntry->text())) or bEU_VHF))
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
// type 2 compound replies
|| (within_tolerance &&
(acceptable_73 ||
("DE" == message_words.at (1) &&
w2.contains(Radio::base_callsign (m_hisCall)))))))
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
|| (m_bCallingCQ && m_bAutoReply
// look for type 2 compound call replies on our Tx and Rx offsets
&& ((within_tolerance && "DE" == message_words.at (1))
|| message_words.at (1).contains (m_baseCall))))) {
if(SpecOp::FOX != m_config.special_op_id()) processMessage (message);
}
}
}
void MainWindow::pskPost (DecodedText const& decodedtext)
{
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if (m_diskData || !m_config.spot_to_psk_reporter() || decodedtext.isLowConfidence ()) return;
QString msgmode=m_mode;
if(m_mode=="JT9+JT65") {
msgmode="JT9";
if (decodedtext.isJT65()) msgmode="JT65";
}
QString deCall;
QString grid;
decodedtext.deCallAndGrid(/*out*/deCall,grid);
int audioFrequency = decodedtext.frequencyOffset();
if(m_mode=="FT8" or m_mode=="MSK144" or m_mode=="FT4") {
audioFrequency=decodedtext.string().mid(16,4).toInt();
}
int snr = decodedtext.snr();
Frequency frequency = m_freqNominal + audioFrequency;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if(grid.contains (grid_regexp)) {
// qDebug() << "To PSKreporter:" << deCall << grid << frequency << msgmode << snr;
if (!m_psk_Reporter.addRemoteStation (deCall, grid, frequency, msgmode, snr))
{
showStatusMessage (tr ("Spotting to PSK Reporter unavailable"));
}
}
}
void MainWindow::killFile ()
{
if (m_fnameWE.size () && !(m_saveAll || (m_saveDecoded && m_bDecoded))) {
QFile f1 {m_fnameWE + ".wav"};
if(f1.exists()) f1.remove();
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if(m_mode=="WSPR" or m_mode=="FST4W") {
QFile f2 {m_fnameWE + ".c2"};
if(f2.exists()) f2.remove();
}
}
}
void MainWindow::on_EraseButton_clicked ()
{
qint64 ms=QDateTime::currentMSecsSinceEpoch();
ui->decodedTextBrowser2->erase ();
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if(m_mode=="WSPR" or m_mode=="Echo" or m_mode=="ISCAT" or m_mode=="FST4W") {
ui->decodedTextBrowser->erase ();
} else {
if((ms-m_msErase)<500) {
ui->decodedTextBrowser->erase ();
}
}
m_msErase=ms;
}
void MainWindow::band_activity_cleared ()
{
m_messageClient->decodes_cleared ();
QFile f(m_config.temp_dir ().absoluteFilePath ("decoded.txt"));
if(f.exists()) f.remove();
}
void MainWindow::rx_frequency_activity_cleared ()
{
m_QSOText.clear();
set_dateTimeQSO(-1); // G4WJS: why do we do this?
}
void MainWindow::decodeBusy(bool b) //decodeBusy()
{
if (!b) {
m_optimizingProgress.reset ();
}
m_decoderBusy=b;
ui->DecodeButton->setEnabled(!b);
ui->actionOpen->setEnabled(!b);
ui->actionOpen_next_in_directory->setEnabled(!b);
ui->actionDecode_remaining_files_in_directory->setEnabled(!b);
statusUpdate ();
}
//------------------------------------------------------------- //guiUpdate()
void MainWindow::guiUpdate()
{
static char message[38];
static char msgsent[38];
double txDuration;
QString rt;
if(m_TRperiod==0) m_TRperiod=60.0;
txDuration=0.0;
if(m_modeTx=="FT4") txDuration=1.0 + 105*576/12000.0; // FT4
if(m_modeTx=="FT8") txDuration=1.0 + 79*1920/12000.0; // FT8
if(m_modeTx=="JT4") txDuration=1.0 + 207.0*2520/11025.0; // JT4
if(m_modeTx=="JT9") txDuration=1.0 + 85.0*m_nsps/12000.0; // JT9
if(m_modeTx=="JT65") txDuration=1.0 + 126*4096/11025.0; // JT65
if(m_modeTx=="QRA64") txDuration=1.0 + 84*6912/12000.0; // QRA64
if(m_modeTx=="WSPR") txDuration=2.0 + 162*8192/12000.0; // WSPR
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if(m_modeTx=="FST4" or m_mode=="FST4W") { //FST4, FST4W
if(m_TRperiod==15) txDuration=1.0 + 160*720/12000.0;
if(m_TRperiod==30) txDuration=1.0 + 160*1680/12000.0;
if(m_TRperiod==60) txDuration=1.0 + 160*3888/12000.0;
if(m_TRperiod==120) txDuration=1.0 + 160*8200/12000.0;
if(m_TRperiod==300) txDuration=1.0 + 160*21504/12000.0;
if(m_TRperiod==900) txDuration=1.0 + 160*66560/12000.0;
if(m_TRperiod==1800) txDuration=1.0 + 160*134400/12000.0;
}
if(m_modeTx=="ISCAT" or m_mode=="MSK144" or m_bFast9) {
txDuration=m_TRperiod-0.25; // ISCAT, JT9-fast, MSK144
}
double tx1=0.0;
double tx2=txDuration;
if(m_mode=="FT8" or m_mode=="FT4") icw[0]=0; //No CW ID in FT4 or FT8 mode
if((icw[0]>0) and (!m_bFast9)) tx2 += icw[0]*2560.0/48000.0; //Full length including CW ID
if(tx2>m_TRperiod) tx2=m_TRperiod;
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if(!m_txFirst and m_mode!="WSPR" and m_mode!="FST4W") {
tx1 += m_TRperiod;
tx2 += m_TRperiod;
}
qint64 ms = QDateTime::currentMSecsSinceEpoch() % 86400000;
int nsec=ms/1000;
double tsec=0.001*ms;
double t2p=fmod(tsec,2*m_TRperiod);
m_s6=fmod(tsec,6.0);
m_nseq = fmod(double(nsec),m_TRperiod);
m_tRemaining=m_TRperiod - fmod(tsec,m_TRperiod);
if(m_mode=="Echo") {
txDuration=2.4;
tx1=0.0;
tx2=txDuration;
if(m_auto and m_s6>4.0) m_bEchoTxOK=true;
if(m_transmitting) m_bEchoTxed=true;
}
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if(m_mode=="WSPR" or m_mode=="FST4W") {
if(m_nseq==0 and m_ntr==0) { //Decide whether to Tx or Rx
m_tuneup=false; //This is not an ATU tuneup
bool btx = m_auto && m_WSPR_tx_next; // To Tx, we need m_auto and
// scheduled transmit
m_WSPR_tx_next = false;
if(btx) {
m_ntr=-1; //This says we will have transmitted
ui->pbTxNext->setChecked (false);
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m_bTxTime=true; //Start a WSPR or FST4W Tx sequence
} else {
// This will be a WSPR or FST4W Rx sequence.
m_ntr=1; //This says we will have received
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m_bTxTime=false; //Start a WSPR or FST4W Rx sequence
}
}
} else {
// For all modes other than WSPR and FST4W
m_bTxTime = (t2p >= tx1) and (t2p < tx2);
if(m_mode=="Echo") m_bTxTime = m_bTxTime and m_bEchoTxOK;
if(m_mode=="FT8" and ui->tx5->currentText().contains("/B ")) {
//FT8 beacon transmissiion from Tx5 only at top of a UTC minute
double t4p=fmod(tsec,4*m_TRperiod);
if(t4p >= 30.0) m_bTxTime=false;
}
}
if(m_tune) m_bTxTime=true; //"Tune" takes precedence
if(m_transmitting or m_auto or m_tune) {
m_dateTimeLastTX = QDateTime::currentDateTimeUtc ();
// Check for "txboth" (FT4 testing purposes only)
QFile f(m_appDir + "/txboth");
if(f.exists() and fmod(tsec,m_TRperiod) < (0.5 + 105.0*576.0/12000.0)) m_bTxTime=true;
// Don't transmit another mode in the 30 m WSPR sub-band
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
Frequency onAirFreq = m_freqNominal + ui->TxFreqSpinBox->value();
if ((onAirFreq > 10139900 and onAirFreq < 10140320) and m_mode!="WSPR") {
m_bTxTime=false;
if (m_auto) auto_tx_mode (false);
if(onAirFreq!=m_onAirFreq0) {
m_onAirFreq0=onAirFreq;
auto const& message = tr ("Please choose another Tx frequency."
" WSJT-X will not knowingly transmit another"
" mode in the WSPR sub-band on 30m.");
QTimer::singleShot (0, [=] { // don't block guiUpdate
MessageBox::warning_message (this, tr ("WSPR Guard Band"), message);
});
}
}
if(m_mode=="FT8" and SpecOp::FOX==m_config.special_op_id()) {
// Don't allow Fox mode in any of the default FT8 sub-bands.
qint32 ft8Freq[]={1840,3573,7074,10136,14074,18100,21074,24915,28074,50313,70100};
for(int i=0; i<11; i++) {
int kHzdiff=m_freqNominal/1000 - ft8Freq[i];
if(qAbs(kHzdiff) < 4) {
m_bTxTime=false;
if (m_auto) auto_tx_mode (false);
auto const& message = tr ("Please choose another dial frequency."
" WSJT-X will not operate in Fox mode"
" in the standard FT8 sub-bands.");
QTimer::singleShot (0, [=] { // don't block guiUpdate
MessageBox::warning_message (this, tr ("Fox Mode warning"), message);
});
break;
}
}
}
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if (m_config.watchdog() && m_mode!="WSPR" && m_mode!="FST4W"
&& m_idleMinutes >= m_config.watchdog ()) {
tx_watchdog (true); // disable transmit
}
float fTR=float((ms%int(1000.0*m_TRperiod)))/int(1000.0*m_TRperiod);
QString txMsg;
if(m_ntx == 1) txMsg=ui->tx1->text();
if(m_ntx == 2) txMsg=ui->tx2->text();
if(m_ntx == 3) txMsg=ui->tx3->text();
if(m_ntx == 4) txMsg=ui->tx4->text();
if(m_ntx == 5) txMsg=ui->tx5->currentText();
if(m_ntx == 6) txMsg=ui->tx6->text();
int msgLength=txMsg.trimmed().length();
if(msgLength==0 and !m_tune) on_stopTxButton_clicked();
if(g_iptt==0 and ((m_bTxTime and fTR<0.75 and msgLength>0) or m_tune)) {
//### Allow late starts
icw[0]=m_ncw;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
g_iptt = 1;
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
setRig ();
if(m_mode=="FT8") {
if (SpecOp::FOX == m_config.special_op_id()) {
if (ui->TxFreqSpinBox->value() > 900) {
ui->TxFreqSpinBox->setValue(300);
}
}
else if (SpecOp::HOUND == m_config.special_op_id()) {
if(m_auto && !m_tune) {
if (ui->TxFreqSpinBox->value() < 999 && m_ntx != 3) {
2020-06-13 11:04:41 -04:00
// Hound randomized range: 1000-3000 Hz
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
ui->TxFreqSpinBox->setValue (QRandomGenerator::global ()->bounded (1000, 2999));
#else
ui->TxFreqSpinBox->setValue ((qrand () % 2000) + 1000);
#endif
}
}
if (m_nSentFoxRrpt==2 and m_ntx==3) {
// move off the original Fox frequency on subsequent tries of Tx3
int nfreq=m_nFoxFreq + 300;
if(m_nFoxFreq>600) nfreq=m_nFoxFreq - 300; //keep nfreq below 900 Hz
ui->TxFreqSpinBox->setValue(nfreq);
}
if (m_nSentFoxRrpt == 1) {
++m_nSentFoxRrpt;
}
}
}
// If HoldTxFreq is not checked, randomize Fox's Tx Freq
// NB: Maybe this should be done no more than once every 5 minutes or so ?
if(m_mode=="FT8" and SpecOp::FOX==m_config.special_op_id() and !ui->cbHoldTxFreq->isChecked()) {
2020-06-13 11:04:41 -04:00
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
ui->TxFreqSpinBox->setValue (QRandomGenerator::global ()->bounded (300, 599));
#else
ui->TxFreqSpinBox->setValue(300.0 + 300.0*double(qrand())/RAND_MAX);
#endif
}
setXIT (ui->TxFreqSpinBox->value ());
2020-09-08 07:54:19 -04:00
m_config.transceiver_ptt (true); //Assert the PTT
m_tx_when_ready = true;
}
// if(!m_bTxTime and !m_tune and m_mode!="FT4") m_btxok=false; //Time to stop transmitting
if(!m_bTxTime and !m_tune) m_btxok=false; //Time to stop transmitting
}
2020-07-23 13:51:05 -04:00
if((m_mode=="WSPR" or m_mode=="FST4W") and
((m_ntr==1 and m_rxDone) or (m_ntr==-1 and m_nseq>tx2))) {
if(m_monitoring) {
m_rxDone=false;
}
if(m_transmitting) {
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
WSPR_history(m_freqNominal,-1);
2020-07-23 13:51:05 -04:00
m_bTxTime=false; //Time to stop a WSPR or FST4W transmission
m_btxok=false;
}
else if (m_ntr != -1) {
WSPR_scheduling ();
2020-07-23 13:51:05 -04:00
m_ntr=0; //This WSPR or FST4W Rx sequence is complete
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// Calculate Tx tones when needed
if((g_iptt==1 && m_iptt0==0) || m_restart) {
//----------------------------------------------------------------------
QByteArray ba;
QByteArray ba0;
if(m_mode=="WSPR") {
ba=WSPR_message().toLatin1();
} else {
if(SpecOp::HOUND == m_config.special_op_id() and m_ntx!=3) { //Hound transmits only Tx1 or Tx3
m_ntx=1;
ui->txrb1->setChecked(true);
}
if(m_mode=="FT4" and m_bBestSPArmed) {
m_BestCQpriority="";
m_bBestSPArmed=false;
ui->pbBestSP->setStyleSheet ("");
}
if(m_ntx == 1) ba=ui->tx1->text().toLocal8Bit();
if(m_ntx == 2) ba=ui->tx2->text().toLocal8Bit();
if(m_ntx == 3) ba=ui->tx3->text().toLocal8Bit();
if(m_ntx == 4) ba=ui->tx4->text().toLocal8Bit();
if(m_ntx == 5) ba=ui->tx5->currentText().toLocal8Bit();
if(m_ntx == 6) ba=ui->tx6->text().toLocal8Bit();
}
ba2msg(ba,message);
int ichk=0;
if (m_lastMessageSent != m_currentMessage
|| m_lastMessageType != m_currentMessageType)
{
m_lastMessageSent = m_currentMessage;
m_lastMessageType = m_currentMessageType;
}
m_currentMessageType = 0;
if(m_tune or m_mode=="Echo") {
itone[0]=0;
} else {
if(m_mode=="ISCAT") {
geniscat_(message, msgsent, const_cast<int *> (itone), 28, 28);
msgsent[28]=0;
} else {
if(m_modeTx=="JT4") gen4_(message, &ichk , msgsent, const_cast<int *> (itone),
&m_currentMessageType, 22, 22);
if(m_modeTx=="JT9") gen9_(message, &ichk, msgsent, const_cast<int *> (itone),
&m_currentMessageType, 22, 22);
if(m_modeTx=="JT65") gen65_(message, &ichk, msgsent, const_cast<int *> (itone),
&m_currentMessageType, 22, 22);
if(m_modeTx=="QRA64") genqra64_(message, &ichk, msgsent, const_cast<int *> (itone),
&m_currentMessageType, 22, 22);
if(m_modeTx=="WSPR") genwspr_(message, msgsent, const_cast<int *> (itone),
22, 22);
if(m_modeTx=="MSK144" or m_modeTx=="FT8" or m_modeTx=="FT4"
2020-07-23 13:51:05 -04:00
or m_modeTx=="FST4" or m_modeTx=="FST4W") {
char MyCall[6];
char MyGrid[6];
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::memcpy(MyCall, (m_config.my_callsign()+" ").toLatin1(), sizeof MyCall);
::memcpy(MyGrid, (m_config.my_grid()+" ").toLatin1(), sizeof MyGrid);
if(m_modeTx=="MSK144") {
genmsk_128_90_(message, &ichk, msgsent, const_cast<int *> (itone),
&m_currentMessageType, 37, 37);
if(m_restart) {
int nsym=144;
if(itone[40]==-40) nsym=40;
m_modulator->set_nsym(nsym);
}
}
if(m_modeTx=="FT8") {
if(SpecOp::FOX==m_config.special_op_id() and ui->tabWidget->currentIndex()==1) {
foxTxSequencer();
} else {
int i3=0;
int n3=0;
char ft8msgbits[77];
genft8_(message, &i3, &n3, msgsent, const_cast<char *> (ft8msgbits),
const_cast<int *> (itone), 37, 37);
int nsym=79;
int nsps=4*1920;
float fsample=48000.0;
float bt=2.0;
float f0=ui->TxFreqSpinBox->value() - m_XIT;
int icmplx=0;
int nwave=nsym*nsps;
gen_ft8wave_(const_cast<int *>(itone),&nsym,&nsps,&bt,&fsample,&f0,foxcom_.wave,
foxcom_.wave,&icmplx,&nwave);
if(SpecOp::FOX == m_config.special_op_id()) {
//Fox must generate the full Tx waveform, not just an itone[] array.
QString fm = QString::fromStdString(message).trimmed();
foxGenWaveform(0,fm);
foxcom_.nslots=1;
foxcom_.nfreq=ui->TxFreqSpinBox->value();
if(m_config.split_mode()) foxcom_.nfreq = foxcom_.nfreq - m_XIT; //Fox Tx freq
QString foxCall=m_config.my_callsign() + " ";
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::memcpy(foxcom_.mycall, foxCall.toLatin1(), sizeof foxcom_.mycall); //Copy Fox callsign into foxcom_
foxgen_();
}
}
}
if(m_modeTx=="FT4") {
int ichk=0;
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char ft4msgbits[77];
genft4_(message, &ichk, msgsent, const_cast<char *> (ft4msgbits),
const_cast<int *>(itone), 37, 37);
int nsym=103;
int nsps=4*576;
float fsample=48000.0;
float f0=ui->TxFreqSpinBox->value() - m_XIT;
int nwave=(nsym+2)*nsps;
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int icmplx=0;
gen_ft4wave_(const_cast<int *>(itone),&nsym,&nsps,&fsample,&f0,foxcom_.wave,
foxcom_.wave,&icmplx,&nwave);
}
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if(m_modeTx=="FST4" or m_modeTx=="FST4W") {
int ichk=0;
int iwspr=0;
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char fst4msgbits[101];
QString wmsg;
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if(m_mode=="FST4W") {
iwspr = 1;
wmsg=WSPR_message();
ba=wmsg.toLatin1();
ba2msg(ba,message);
}
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genfst4_(message,&ichk,msgsent,const_cast<char *> (fst4msgbits),
const_cast<int *>(itone), &iwspr, 37, 37);
int hmod=1;
if(m_config.x2ToneSpacing()) hmod=2;
if(m_config.x4ToneSpacing()) hmod=4;
int nsps=720;
if(m_TRperiod==30) nsps=1680;
if(m_TRperiod==60) nsps=3888;
if(m_TRperiod==120) nsps=8200;
if(m_TRperiod==300) nsps=21504;
if(m_TRperiod==900) nsps=66560;
if(m_TRperiod==1800) nsps=134400;
nsps=4*nsps; //48000 Hz sampling
int nsym=160;
float fsample=48000.0;
float dfreq=hmod*fsample/nsps;
float f0=ui->TxFreqSpinBox->value() - m_XIT + 1.5*dfreq;
if(m_mode=="FST4W") f0=ui->WSPRfreqSpinBox->value() - m_XIT + 1.5*dfreq;
int nwave=(nsym+2)*nsps;
int icmplx=0;
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gen_fst4wave_(const_cast<int *>(itone),&nsym,&nsps,&nwave,
&fsample,&hmod,&f0,&icmplx,foxcom_.wave,foxcom_.wave);
QString t = QString::fromStdString(message).trimmed();
}
if(SpecOp::EU_VHF==m_config.special_op_id()) {
if(m_ntx==2) m_xSent=ui->tx2->text().right(13);
if(m_ntx==3) m_xSent=ui->tx3->text().right(13);
}
if(SpecOp::FIELD_DAY==m_config.special_op_id() or SpecOp::RTTY==m_config.special_op_id()) {
if(m_ntx==2 or m_ntx==3) {
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QStringList t=ui->tx2->text().split(' ', SkipEmptyParts);
int n=t.size();
m_xSent=t.at(n-2) + " " + t.at(n-1);
}
}
}
msgsent[37]=0;
}
}
m_currentMessage = QString::fromLatin1(msgsent);
m_bCallingCQ = CALLING == m_QSOProgress
|| m_currentMessage.contains (QRegularExpression {"^(CQ|QRZ) "});
if(m_mode=="FT8" or m_mode=="FT4") {
if(m_bCallingCQ && ui->cbFirst->isVisible () && ui->cbFirst->isChecked ()) {
ui->cbFirst->setStyleSheet("QCheckBox{color:red}");
} else {
ui->cbFirst->setStyleSheet("");
}
}
if (m_tune) {
m_currentMessage = "TUNE";
m_currentMessageType = -1;
}
if(m_restart) {
write_all("Tx",m_currentMessage);
if (m_config.TX_messages ()) {
ui->decodedTextBrowser2->displayTransmittedText(m_currentMessage,m_modeTx,
ui->TxFreqSpinBox->value(),m_bFastMode,m_TRperiod);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
auto t2 = QDateTime::currentDateTimeUtc ().toString ("hhmm");
icw[0] = 0;
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auto msg_parts = m_currentMessage.split (' ', SkipEmptyParts);
if (msg_parts.size () > 2) {
// clean up short code forms
msg_parts[0].remove (QChar {'<'});
msg_parts[0].remove (QChar {'>'});
msg_parts[1].remove (QChar {'<'});
msg_parts[1].remove (QChar {'>'});
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
auto is_73 = m_QSOProgress >= ROGER_REPORT
&& message_is_73 (m_currentMessageType, msg_parts);
m_sentFirst73 = is_73
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&& !message_is_73 (m_lastMessageType, m_lastMessageSent.split (' ', SkipEmptyParts));
if (m_sentFirst73) {
m_qsoStop=t2;
if(m_config.id_after_73 ()) {
icw[0] = m_ncw;
}
if((m_config.prompt_to_log() or m_config.autoLog()) && !m_tune) logQSOTimer.start(0);
}
bool b=(m_mode=="FT8" or m_mode=="FT4") and ui->cbAutoSeq->isChecked();
if(is_73 and (m_config.disable_TX_on_73() or b)) {
m_nextCall=""; //### Temporary: disable use of "TU;" messages;
if(m_nextCall!="") {
useNextCall();
} else {
auto_tx_mode (false);
if(b) {
m_ntx=6;
ui->txrb6->setChecked(true);
m_QSOProgress = CALLING;
}
}
}
if(m_config.id_interval () >0) {
int nmin=(m_sec0-m_secID)/60;
if(m_sec0<m_secID) nmin=m_config.id_interval();
if(nmin >= m_config.id_interval()) {
icw[0]=m_ncw;
m_secID=m_sec0;
}
}
if ((m_currentMessageType < 6 || 7 == m_currentMessageType)
&& msg_parts.length() >= 3
&& (msg_parts[1] == m_config.my_callsign () ||
msg_parts[1] == m_baseCall))
{
int i1;
bool ok;
i1 = msg_parts[2].toInt(&ok);
if(ok and i1>=-50 and i1<50)
{
m_rptSent = msg_parts[2];
m_qsoStart = t2;
} else {
if (msg_parts[2].mid (0, 1) == "R")
{
i1 = msg_parts[2].mid (1).toInt (&ok);
if (ok and i1 >= -50 and i1 < 50)
{
m_rptSent = msg_parts[2].mid (1);
m_qsoStart = t2;
}
}
}
}
m_restart=false;
//----------------------------------------------------------------------
} else {
if (!m_auto && m_sentFirst73) {
m_sentFirst73 = false;
}
}
if (g_iptt == 1 && m_iptt0 == 0) {
auto const& current_message = QString::fromLatin1 (msgsent);
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if(m_config.watchdog () && m_mode!="WSPR" && m_mode!="FST4W"
&& current_message != m_msgSent0) {
tx_watchdog (false); // in case we are auto sequencing
m_msgSent0 = current_message;
}
if (m_mode != "FST4W" && m_mode != "WSPR")
{
if(!m_tune) write_all("Tx",m_currentMessage);
if (m_config.TX_messages () && !m_tune && SpecOp::FOX!=m_config.special_op_id())
{
ui->decodedTextBrowser2->displayTransmittedText(current_message, m_modeTx,
ui->TxFreqSpinBox->value(),m_bFastMode,m_TRperiod);
}
}
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switch (m_ntx)
{
case 1: m_QSOProgress = REPLYING; break;
case 2: m_QSOProgress = REPORT; break;
case 3: m_QSOProgress = ROGER_REPORT; break;
case 4: m_QSOProgress = ROGERS; break;
case 5: m_QSOProgress = SIGNOFF; break;
case 6: m_QSOProgress = CALLING; break;
default: break; // determined elsewhere
}
2019-03-07 11:21:17 -05:00
m_transmitting = true;
transmitDisplay (true);
statusUpdate ();
}
if(!m_btxok && m_btxok0 && g_iptt==1)
{
stopTx();
if ("1" == m_env.value ("WSJT_TX_BOTH", "0"))
{
m_txFirst = !m_txFirst;
ui->txFirstCheckBox->setChecked (m_txFirst);
}
}
if(m_startAnother) {
if(m_mode=="MSK144") {
m_wait++;
}
if(m_mode!="MSK144" or m_wait>=4) {
m_wait=0;
m_startAnother=false;
on_actionOpen_next_in_directory_triggered();
}
}
if(m_mode=="FT8" or m_mode=="MSK144" or m_mode=="FT4") {
if(ui->txrb1->isEnabled() and
(SpecOp::NA_VHF==m_config.special_op_id() or
SpecOp::FIELD_DAY==m_config.special_op_id() or
SpecOp::RTTY==m_config.special_op_id() or
SpecOp::WW_DIGI==m_config.special_op_id()) ) {
//We're in a contest-like mode other than EU_VHF: start QSO with Tx2.
ui->tx1->setEnabled(false);
ui->txb1->setEnabled(false);
}
if(!ui->tx1->isEnabled() and SpecOp::EU_VHF==m_config.special_op_id()) {
//We're in EU_VHF mode: start QSO with Tx1.
ui->tx1->setEnabled(true);
ui->txb1->setEnabled(true);
}
}
//Once per second (onesec)
if(nsec != m_sec0) {
// qDebug() << "AAA" << nsec;
if(m_mode=="FST4") chk_FST4_freq_range();
m_currentBand=m_config.bands()->find(m_freqNominal);
if( SpecOp::HOUND == m_config.special_op_id() ) {
qint32 tHound=QDateTime::currentMSecsSinceEpoch()/1000 - m_tAutoOn;
//To keep calling Fox, Hound must reactivate Enable Tx at least once every 2 minutes
if(tHound >= 120 and m_ntx==1) auto_tx_mode(false);
}
progressBar.setVisible(true);
progressBar.setFormat ("%v/%m");
if(m_auto and m_mode=="Echo" and m_bEchoTxOK) {
progressBar.setMaximum(3);
progressBar.setValue(int(m_s6));
}
if(m_mode!="Echo") {
if(m_monitoring or m_transmitting) {
progressBar.setMaximum(m_TRperiod);
int isec=int(fmod(tsec,m_TRperiod));
if(m_TRperiod-int(m_TRperiod)>0.0) {
QString progBarLabel;
2020-05-06 21:56:57 -04:00
progBarLabel = progBarLabel.asprintf("%d/%3.1f",isec,m_TRperiod);
progressBar.setFormat (progBarLabel);
}
progressBar.setValue(isec);
} else {
progressBar.setValue(0);
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
astroUpdate ();
if(m_transmitting) {
char s[42];
if(SpecOp::FOX==m_config.special_op_id() and ui->tabWidget->currentIndex()==1) {
sprintf(s,"Tx: %d Slots",foxcom_.nslots);
} else {
sprintf(s,"Tx: %s",msgsent);
}
m_nsendingsh=0;
if(s[4]==64) m_nsendingsh=1;
if(m_nsendingsh==1 or m_currentMessageType==7) {
tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #66ffff}");
} else if(m_nsendingsh==-1 or m_currentMessageType==6) {
tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #ffccff}");
} else {
tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #ffff33}");
}
if(m_tune) {
tx_status_label.setText("Tx: TUNE");
} else {
if(m_mode=="Echo") {
tx_status_label.setText("Tx: ECHO");
} else {
s[40]=0;
QString t{QString::fromLatin1(s)};
if(SpecOp::FOX==m_config.special_op_id() and ui->tabWidget->currentIndex()==1 and foxcom_.nslots==1) {
t=m_fm1.trimmed();
}
if(m_mode=="FT4") t="Tx: "+ m_currentMessage;
tx_status_label.setText(t.trimmed());
}
}
} else if(m_monitoring) {
if (!m_tx_watchdog) {
tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #00ff00}");
2020-05-19 07:15:58 -04:00
auto t = tr ("Receiving");
if(m_mode=="MSK144") {
int npct=int(100.0*m_fCPUmskrtd/0.298667);
if(npct>90) tx_status_label.setStyleSheet("QLabel{color: #000000; background-color: #ff0000}");
2020-05-19 07:15:58 -04:00
t += QString {" %1%"}.arg (npct, 2);
}
tx_status_label.setText (t);
}
transmitDisplay(false);
} else if (!m_diskData && !m_tx_watchdog) {
tx_status_label.setStyleSheet("");
tx_status_label.setText("");
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
QDateTime t = QDateTime::currentDateTimeUtc();
QString utc = t.date().toString("yyyy MMM dd") + "\n " +
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
t.time().toString() + " ";
ui->labUTC->setText(utc);
if(m_bBestSPArmed and (m_dateTimeBestSP.secsTo(t) >= 120)) on_pbBestSP_clicked(); //BestSP timeout
if(!m_monitoring and !m_diskData) ui->signal_meter_widget->setValue(0,0);
m_sec0=nsec;
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
displayDialFrequency ();
}
m_iptt0=g_iptt;
m_btxok0=m_btxok;
} //End of guiUpdate
void MainWindow::useNextCall()
{
ui->dxCallEntry->setText(m_nextCall);
m_nextCall="";
ui->labNextCall->setStyleSheet("");
ui->labNextCall->setText("");
if(m_nextGrid.contains(grid_regexp)) {
ui->dxGridEntry->setText(m_nextGrid);
m_ntx=2;
ui->txrb2->setChecked(true);
} else {
m_ntx=3;
ui->txrb3->setChecked(true);
}
genStdMsgs(m_nextRpt);
}
void MainWindow::startTx2()
{
if (!m_modulator->isActive ()) { // TODO - not thread safe
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
double fSpread=0.0;
double snr=99.0;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
QString t=ui->tx5->currentText();
if(t.mid(0,1)=="#") fSpread=t.mid(1,5).toDouble();
m_modulator->setSpread(fSpread); // TODO - not thread safe
t=ui->tx6->text();
if(t.mid(0,1)=="#") snr=t.mid(1,5).toDouble();
if(snr>0.0 or snr < -50.0) snr=99.0;
if((m_ntx==6 or m_ntx==7) and m_config.force_call_1st()) {
ui->cbAutoSeq->setChecked(true);
ui->cbFirst->setChecked(true);
}
transmit (snr);
ui->signal_meter_widget->setValue(0,0);
if(m_mode=="Echo" and !m_tune) m_bTransmittedEcho=true;
2020-07-23 13:51:05 -04:00
if((m_mode=="WSPR" or m_mode=="FST4W") and !m_tune) {
if (m_config.TX_messages ()) {
t = " Transmitting " + m_mode + " ----------------------- " +
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_config.bands ()->find (m_freqNominal);
t=beacon_start_time (m_TRperiod / 2) + ' ' + t.rightJustified (66, '-');
ui->decodedTextBrowser->appendText(t);
}
write_all("Tx",m_currentMessage);
}
}
}
void MainWindow::stopTx()
{
Qt 5 Audio replaces PortAudio. Currently only Qt5 or above is known to work with this code. It may be possible to backport it to Qt4 if required. Audio output goes back to a separate thread to try and minimize stutters in streaming on Windows particularly. A crash on Linux due to mishandling of stereo audio output has been fixed and both left and right channels are now correctly synthesised with identical contents. Rigs are enumerated directly from hamlib API rather than running a sub process reading output of rigctl -l. This was initially done to get rid of some GUI thread blocking in the configuration dialog, but is generally a better way of doing it anyway. Some refactoring in MainWindow to accomodate the audio streaming, modulation and detecting classes. Exit handling for application refactored to use signals rather than brute force event loop exit. This was required to get correct thread shutdown semantics. The GUI update timer is now stopped during application shutdown which is necessary to stop crashes when shutting down gracefully with signals and window close() calls. There is an outstanding issue with Linux audio streams; the QAudio Input/Output classes create a new stream name each time a stream is started. This doesn't play well with PulseAudio utilities such as pavucontrol to set stream volume as settings are lost every tx period. I have tried to keep a single stream for all output but there are problems restarting it that haven't been resolved yet. The QtCreator project file has been rearranged a little because it passes all the object files to the linker rather than using an archive library. Since the GNU linker is single pass; the object files need to be in a logical order with definitions appearing afer references to them. This was required to avoid a linking error. The lib/Makefile.linux has been enhanced to use the fortran compiler to locate the correct version of the Fortran library to use. This is necessary on the latest Linux distros because the unversioned symlink to compiler support libraries is no longer provided. This only an issue with mixed programming language links where the linker driver for one language has to link support libraraies for another language. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3532 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-07 19:09:13 -04:00
Q_EMIT endTransmitMessage ();
m_btxok = false;
m_transmitting = false;
g_iptt=0;
if (!m_tx_watchdog) {
tx_status_label.setStyleSheet("");
tx_status_label.setText("");
}
ptt0Timer.start(200); //end-of-transmission sequencer delay
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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monitor (true);
statusUpdate ();
}
void MainWindow::stopTx2()
{
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m_config.transceiver_ptt (false); //Lower PTT
if (m_mode == "JT9" && m_bFast9
&& ui->cbAutoSeq->isVisible () && ui->cbAutoSeq->isChecked()
&& m_ntx == 5 && m_nTx73 >= 5) {
on_stopTxButton_clicked ();
m_nTx73 = 0;
}
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if(((m_mode=="WSPR" or m_mode=="FST4W") and m_ntr==-1) and !m_tuneup) {
m_wideGraph->setWSPRtransmitted();
WSPR_scheduling ();
m_ntr=0;
}
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last_tx_label.setText(tr ("Last Tx: %1").arg (m_currentMessage.trimmed()));
}
void MainWindow::ba2msg(QByteArray ba, char message[]) //ba2msg()
{
int iz=ba.length();
for(int i=0; i<37; i++) {
if(i<iz) {
if(int(ba[i])>=97 and int(ba[i])<=122) ba[i]=int(ba[i])-32;
message[i]=ba[i];
} else {
message[i]=32;
}
}
message[37]=0;
}
void MainWindow::on_txFirstCheckBox_stateChanged(int nstate) //TxFirst
{
m_txFirst = (nstate==2);
}
void MainWindow::set_dateTimeQSO(int m_ntx)
{
// m_ntx = -1 resets to default time
// Our QSO start time can be fairly well determined from Tx 2 and Tx 3 -- the grid reports
// If we CQ'd and sending sigrpt then 2 minutes ago n=2
// If we're on msg 3 then 3 minutes ago n=3 -- might have sat on msg1 for a while
// If we've already set our time on just return.
// This should mean that Tx2 or Tx3 has been repeated so don't update the start time
// We reset it in several places
if (m_ntx == -1) { // we use a default date to detect change
m_dateTimeQSOOn = QDateTime {};
}
else if (m_dateTimeQSOOn.isValid ()) {
return;
}
else { // we also take of m_TRperiod/2 to allow for late clicks
auto now = QDateTime::currentDateTimeUtc();
m_dateTimeQSOOn = now.addSecs (-(m_ntx - 2) * int(m_TRperiod) -
int(fmod(double(now.time().second()),m_TRperiod)));
}
}
void MainWindow::set_ntx(int n) //set_ntx()
{
m_ntx=n;
}
void MainWindow::on_txrb1_toggled (bool status)
{
if (status) {
if (ui->tx1->isEnabled ()) {
m_ntx = 1;
set_dateTimeQSO (-1); // we reset here as tx2/tx3 is used for start times
}
else {
QTimer::singleShot (0, ui->txrb2, SLOT (click ()));
}
}
}
bool MainWindow::elide_tx1_not_allowed () const
{
auto const& my_callsign = m_config.my_callsign ();
return
(m_mode=="FT8" && SpecOp::HOUND == m_config.special_op_id())
|| ((m_mode.startsWith ("FT") || "MSK144" == m_mode || "Q65" == m_mode || "FST4" == m_mode)
&& Radio::is_77bit_nonstandard_callsign (my_callsign))
|| (my_callsign != m_baseCall && !shortList (my_callsign));
}
void MainWindow::on_txrb1_doubleClicked ()
{
ui->tx1->setEnabled (elide_tx1_not_allowed () || !ui->tx1->isEnabled ());
if (!ui->tx1->isEnabled ()) {
// leave time for clicks to complete before setting txrb2
QTimer::singleShot (500, ui->txrb2, SLOT (click ()));
}
}
void MainWindow::on_txrb2_toggled (bool status)
{
// Tx 2 means we already have CQ'd so good reference
if (status) {
m_ntx=2;
set_dateTimeQSO (m_ntx);
}
}
void MainWindow::on_txrb3_toggled(bool status)
{
// Tx 3 means we should have already have done Tx 1 so good reference
if (status) {
m_ntx=3;
set_dateTimeQSO(m_ntx);
}
}
void MainWindow::on_txrb4_toggled (bool status)
{
if (status) {
m_ntx=4;
}
}
void MainWindow::on_txrb4_doubleClicked ()
{
// RR73 only allowed if not a type 2 compound callsign
auto const& my_callsign = m_config.my_callsign ();
auto is_compound = my_callsign != m_baseCall;
m_send_RR73 = !((is_compound && !shortList (my_callsign)) || m_send_RR73);
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if(m_mode=="FT4") m_send_RR73=true;
genStdMsgs (m_rpt);
}
void MainWindow::on_txrb5_toggled (bool status)
{
if (status) {
m_ntx = 5;
}
}
void MainWindow::on_txrb5_doubleClicked ()
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
{
genStdMsgs (m_rpt, true);
}
void MainWindow::on_txrb6_toggled(bool status)
{
if (status) {
m_ntx=6;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (ui->txrb6->text().contains (QRegularExpression {"^(CQ|QRZ) "})) set_dateTimeQSO(-1);
}
}
void MainWindow::on_txb1_clicked()
{
if (ui->tx1->isEnabled ()) {
m_ntx=1;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = REPLYING;
ui->txrb1->setChecked(true);
if(m_transmitting) m_restart=true;
}
else {
on_txb2_clicked ();
}
}
void MainWindow::on_txb1_doubleClicked()
{
ui->tx1->setEnabled (elide_tx1_not_allowed () || !ui->tx1->isEnabled ());
}
void MainWindow::on_txb2_clicked()
{
m_ntx=2;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = REPORT;
ui->txrb2->setChecked(true);
if(m_transmitting) m_restart=true;
}
void MainWindow::on_txb3_clicked()
{
m_ntx=3;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = ROGER_REPORT;
ui->txrb3->setChecked(true);
if(m_transmitting) m_restart=true;
}
void MainWindow::on_txb4_clicked()
{
m_ntx=4;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = ROGERS;
ui->txrb4->setChecked(true);
if(m_transmitting) m_restart=true;
}
void MainWindow::on_txb4_doubleClicked()
{
// RR73 only allowed if not a type 2 compound callsign
auto const& my_callsign = m_config.my_callsign ();
auto is_compound = my_callsign != m_baseCall;
m_send_RR73 = !((is_compound && !shortList (my_callsign)) || m_send_RR73);
if(m_mode=="FT4") m_send_RR73=true;
genStdMsgs (m_rpt);
}
void MainWindow::on_txb5_clicked()
{
m_ntx=5;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = SIGNOFF;
ui->txrb5->setChecked(true);
if(m_transmitting) m_restart=true;
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
void MainWindow::on_txb5_doubleClicked()
{
genStdMsgs (m_rpt, true);
}
void MainWindow::on_txb6_clicked()
{
m_ntx=6;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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m_QSOProgress = CALLING;
set_dateTimeQSO(-1);
ui->txrb6->setChecked(true);
if(m_transmitting) m_restart=true;
}
void MainWindow::doubleClickOnCall2(Qt::KeyboardModifiers modifiers)
{
//Confusing: come here after double-click on left text window, not right window.
set_dateTimeQSO(-1); // reset our QSO start time
m_decodedText2=true;
doubleClickOnCall(modifiers);
m_decodedText2=false;
}
void MainWindow::doubleClickOnCall(Qt::KeyboardModifiers modifiers)
{
QTextCursor cursor;
if(m_mode=="ISCAT" or m_mode=="FST4W") {
MessageBox::information_message (this,
"Double-click not available for ISCAT or FST4W mode");
return;
}
if(m_decodedText2) {
cursor=ui->decodedTextBrowser->textCursor();
} else {
cursor=ui->decodedTextBrowser2->textCursor();
}
if(modifiers==(Qt::ShiftModifier + Qt::ControlModifier + Qt::AltModifier)) {
//### What was the purpose of this ??? ###
cursor.setPosition(0);
} else {
cursor.setPosition(cursor.selectionStart());
}
if(SpecOp::FOX==m_config.special_op_id() and m_decodedText2) {
if(m_houndQueue.count()<10 and m_nSortedHounds>0) {
QString t=cursor.block().text();
selectHound(t);
}
return;
}
DecodedText message {cursor.block().text().trimmed().left(61).remove("TU; ")};
m_bDoubleClicked = true;
processMessage (message, modifiers);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
}
void MainWindow::processMessage (DecodedText const& message, Qt::KeyboardModifiers modifiers)
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
{
// decode keyboard modifiers we are interested in
auto shift = modifiers.testFlag (Qt::ShiftModifier);
auto ctrl = modifiers.testFlag (Qt::ControlModifier);
// auto alt = modifiers.testFlag (Qt::AltModifier);
// basic mode sanity checks
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auto const& parts = message.string ().split (' ', SkipEmptyParts);
if (parts.size () < 5) return;
auto const& mode = parts.at (4).left (1);
if (("JT9+JT65" == m_mode && !("@" == mode || "#" == mode))
|| ("JT65" == m_mode && mode != "#")
|| ("JT9" == m_mode && mode != "@")
|| ("MSK144" == m_mode && !("&" == mode || "^" == mode))
|| ("QRA64" == m_mode && mode.left (1) != ":")) {
2020-07-23 13:51:05 -04:00
return; //Currently we do auto-sequencing only in FT4, FT8, MSK144, and FST4
}
//Skip the rest if no decoded text extracted
int frequency = message.frequencyOffset();
if (message.isTX()) {
if (!m_config.enable_VHF_features()) {
if(!shift) ui->RxFreqSpinBox->setValue(frequency); //Set Rx freq
if((ctrl or shift) and !ui->cbHoldTxFreq->isChecked ()) {
ui->TxFreqSpinBox->setValue(frequency); //Set Tx freq
}
}
return;
}
// check for CQ with listening frequency
if (parts.size () >= 7
&& (m_bFastMode || m_mode=="FT8")
&& "CQ" == parts[5]
&& m_config.is_transceiver_online ()) {
bool ok;
auto kHz = parts[6].toUInt (&ok);
if (ok && kHz >= 10 && 3 == parts[6].size ()) {
// QSY Freq for answering CQ nnn
setRig (m_freqNominal / 1000000 * 1000000 + 1000 * kHz);
ui->decodedTextBrowser2->displayQSY (QString {"QSY %1"}.arg (m_freqNominal / 1e6, 7, 'f', 3));
}
}
int nmod = fmod(double(message.timeInSeconds()),2.0*m_TRperiod);
m_txFirst=(nmod!=0);
if( SpecOp::HOUND == m_config.special_op_id() ) m_txFirst=false; //Hound must not transmit first
if( SpecOp::FOX == m_config.special_op_id() ) m_txFirst=true; //Fox must always transmit first
ui->txFirstCheckBox->setChecked(m_txFirst);
auto const& message_words = message.messageWords ();
if (message_words.size () < 2) return;
QString hiscall;
QString hisgrid;
message.deCallAndGrid(/*out*/hiscall,hisgrid);
if(message.string().contains(hiscall+"/R")) {
hiscall+="/R";
ui->dxCallEntry->setText(hiscall);
}
if(message.string().contains(hiscall+"/P")) {
hiscall+="/P";
ui->dxCallEntry->setText(hiscall);
}
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QStringList w=message.string().mid(22).remove("<").remove(">").split(" ",SkipEmptyParts);
int nw=w.size();
if(nw>=4) {
if(message_words.size()<3) return;
int n=w.at(nw-2).toInt();
if(n>=520001 and n<=592047) {
hiscall=w.at(1);
hisgrid=w.at(nw-1);
}
}
bool is_73 = message_words.filter (QRegularExpression {"^(73|RR73)$"}).size ();
if (!is_73 and !message.isStandardMessage() and !message.string().contains("<")) {
qDebug () << "Not processing message - hiscall:" << hiscall << "hisgrid:" << hisgrid
<< message.string() << message.isStandardMessage();
return;
}
// only allow automatic mode changes between JT9 and JT65, and when not transmitting
if (!m_transmitting and m_mode == "JT9+JT65") {
if (message.isJT9())
{
m_modeTx="JT9";
ui->pbTxMode->setText("Tx JT9 @");
m_wideGraph->setModeTx(m_modeTx);
} else if (message.isJT65()) {
m_modeTx="JT65";
ui->pbTxMode->setText("Tx JT65 #");
m_wideGraph->setModeTx(m_modeTx);
}
} else if ((message.isJT9 () and m_modeTx != "JT9" and m_mode != "JT4") or
(message.isJT65 () and m_modeTx != "JT65" and m_mode != "JT4")) {
// if we are not allowing mode change then don't process decode
return;
}
// ignore calls by other hounds
if (SpecOp::HOUND == m_config.special_op_id()
&& message.messageWords ().indexOf (QRegularExpression {R"(R\+-[0-9]+)"}) >= 0)
{
return;
}
QString firstcall = message.call();
if(firstcall.length()==5 and firstcall.mid(0,3)=="CQ ") firstcall="CQ";
if(!m_bFastMode and (!m_config.enable_VHF_features() or m_mode=="FT8")) {
// Don't change Tx freq if in a fast mode, or VHF features enabled; also not if a
// station is calling me, unless CTRL or SHIFT is held down.
if ((Radio::is_callsign (firstcall)
&& firstcall != m_config.my_callsign () && firstcall != m_baseCall
&& firstcall != "DE")
|| "CQ" == firstcall || "QRZ" == firstcall || ctrl || shift) {
if (((SpecOp::HOUND != m_config.special_op_id()) || m_mode != "FT8")
&& (!ui->cbHoldTxFreq->isChecked () || shift || ctrl)) {
ui->TxFreqSpinBox->setValue(frequency);
}
if(m_mode != "JT4" && m_mode != "JT65" && !m_mode.startsWith ("JT9") &&
m_mode != "QRA64" && m_mode!="FT8" && m_mode!="FT4" && m_mode!="FST4") {
return;
}
}
}
------------------------------------------------------------------------ r5297 | bsomervi | 2015-04-26 17:26:54 +0100 (Sun, 26 Apr 2015) | 49 lines Various defect repairs and ambigous behaviour clarifications A regression introduced in v1.5.0-rc1 where PTT on an alternate serial port when using no CAT control is resolved. A regression introduced in v1.5.0-rc1 where the network server field was not being restored in the settings dialog has been resolved. In settings the "Test PTT" button is now styled by checked state. The "Test PTT" button is enabled without needing click "Test CAT" first when no CAT rig control is selected. Various parts of the settings dialog are now disabled when no CAT rig control is selected. These are the "Mode" group, the "Split Operation" group and the "Monitor returns to last used frequency" check box. None of these have any visible impact nor make sense without CAT rig control. Initialization and teardown of rig control internals has been revised to avoid several problems related to timing and when switching between different CAT settings. This includes improvements in having the operating frequency restored between sessions when not using CAT rig control. The initialization of OmniRig connections has been improved, unfortunately it is still possible to get an exception when clicking the "Test CAT" button where just clicking "OK" and leaving the settings dialog will probably work. Some unnecessary CAT commands output during direct rig control have been elided to reduce the level of traffic a little. The handling of some automatically generated free text messages used when the station is a type 2 compound callsign or is working a type 2 compound callsign has been improved. This is related to how a double click on a message of the form "DE TI4/N0URE 73" is double clicked. The new behaviour depends on whether the current "DX Call" matches the call in the message. This resolves the ambiguity as to whether this message is a sign off at the end of a QSO with current operator (a 73 message is generated) or a tail end opportunity where the message should be treated the same as a CQ or QRZ message (WSJT-X QSYs to the frequency, generates messages and selects message one ready to call). This still leaves some potential ambiguous behaviors in this complex area but selecting "Clear DX call and grid after logging" should resolve most of them. Rig control trace messages have been cleaned up and are now more helpful, less verbose and, tidier in the source code. ------------------------------------------------------------------------ Merged from the wsjtx-1.5 branch. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5298 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-26 12:41:12 -04:00
// prior DX call (possible QSO partner)
auto qso_partner_base_call = Radio::base_callsign (ui->dxCallEntry->text ());
auto base_call = Radio::base_callsign (hiscall);
// Determine appropriate response to received message
auto dtext = " " + message.string () + " ";
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dtext=dtext.remove("<").remove(">");
if(dtext.contains (" " + m_baseCall + " ")
|| dtext.contains ("<" + m_baseCall + "> ")
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//###??? || dtext.contains ("<" + m_baseCall + " " + hiscall + "> ")
|| dtext.contains ("/" + m_baseCall + " ")
|| dtext.contains (" " + m_baseCall + "/")
|| (firstcall == "DE")) {
QString w2;
int nw=w.size();
if(nw>=3) w2=w.at(2);
int nrpt=w2.toInt();
QString w34;
if(nw>=4) {
// w34=w.at(nw-2);
nrpt=w.at(nw-2).toInt();
w34=w.at(nw-1);
}
bool bRTTY = (nrpt>=529 and nrpt<=599);
bool bEU_VHF_w2=(nrpt>=520001 and nrpt<=594000);
if(bEU_VHF_w2 and SpecOp::EU_VHF!=m_config.special_op_id()) {
auto const& msg = tr("Should you switch to EU VHF Contest mode?\n\n"
"To do so, check 'Special operating activity' and\n"
"'EU VHF Contest' on the Settings | Advanced tab.");
MessageBox::information_message (this, msg);
}
2020-06-13 11:04:41 -04:00
QStringList t=message.string().split(' ', SkipEmptyParts);
int n=t.size();
QString t0=t.at(n-2);
QString t1=t0.right(1);
bool bFieldDay_msg = (t1>="A" and t1<="F" and t0.size()<=3 and n>=9);
int m=t0.remove(t1).toInt();
if(m < 1) bFieldDay_msg=false;
if(bFieldDay_msg) {
m_xRcvd=t.at(n-2) + " " + t.at(n-1);
t0=t.at(n-3);
}
if(bFieldDay_msg and SpecOp::FIELD_DAY!=m_config.special_op_id()) {
// ### Should be in ARRL Field Day mode ??? ###
MessageBox::information_message (this, tr ("Should you switch to ARRL Field Day mode?"));
}
if(bRTTY and SpecOp::RTTY != m_config.special_op_id()) {
// ### Should be in RTTY contest mode ??? ###
MessageBox::information_message (this, tr ("Should you switch to RTTY contest mode?"));
}
if(SpecOp::EU_VHF==m_config.special_op_id() and message_words.at(1).contains(m_baseCall) and
(!message_words.at(2).contains(qso_partner_base_call)) and (!m_bDoubleClicked)) {
return;
}
if(message_words.size () > 3 // enough fields for a normal message
&& (message_words.at(1).contains(m_baseCall) || "DE" == message_words.at(1))
&& (message_words.at(2).contains(qso_partner_base_call) or m_bDoubleClicked
or bEU_VHF_w2 or (m_QSOProgress==CALLING))) {
if(message_words.at(3).contains(grid_regexp) and SpecOp::EU_VHF!=m_config.special_op_id()) {
if(SpecOp::NA_VHF==m_config.special_op_id() or SpecOp::WW_DIGI==m_config.special_op_id()){
setTxMsg(3);
m_QSOProgress=ROGER_REPORT;
} else {
if(m_mode=="JT65" and message_words.size()>4 and message_words.at(4)=="OOO") {
setTxMsg(3);
m_QSOProgress=ROGER_REPORT;
} else {
setTxMsg(2);
m_QSOProgress=REPORT;
}
------------------------------------------------------------------------ r5297 | bsomervi | 2015-04-26 17:26:54 +0100 (Sun, 26 Apr 2015) | 49 lines Various defect repairs and ambigous behaviour clarifications A regression introduced in v1.5.0-rc1 where PTT on an alternate serial port when using no CAT control is resolved. A regression introduced in v1.5.0-rc1 where the network server field was not being restored in the settings dialog has been resolved. In settings the "Test PTT" button is now styled by checked state. The "Test PTT" button is enabled without needing click "Test CAT" first when no CAT rig control is selected. Various parts of the settings dialog are now disabled when no CAT rig control is selected. These are the "Mode" group, the "Split Operation" group and the "Monitor returns to last used frequency" check box. None of these have any visible impact nor make sense without CAT rig control. Initialization and teardown of rig control internals has been revised to avoid several problems related to timing and when switching between different CAT settings. This includes improvements in having the operating frequency restored between sessions when not using CAT rig control. The initialization of OmniRig connections has been improved, unfortunately it is still possible to get an exception when clicking the "Test CAT" button where just clicking "OK" and leaving the settings dialog will probably work. Some unnecessary CAT commands output during direct rig control have been elided to reduce the level of traffic a little. The handling of some automatically generated free text messages used when the station is a type 2 compound callsign or is working a type 2 compound callsign has been improved. This is related to how a double click on a message of the form "DE TI4/N0URE 73" is double clicked. The new behaviour depends on whether the current "DX Call" matches the call in the message. This resolves the ambiguity as to whether this message is a sign off at the end of a QSO with current operator (a 73 message is generated) or a tail end opportunity where the message should be treated the same as a CQ or QRZ message (WSJT-X QSYs to the frequency, generates messages and selects message one ready to call). This still leaves some potential ambiguous behaviors in this complex area but selecting "Clear DX call and grid after logging" should resolve most of them. Rig control trace messages have been cleaned up and are now more helpful, less verbose and, tidier in the source code. ------------------------------------------------------------------------ Merged from the wsjtx-1.5 branch. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5298 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-26 12:41:12 -04:00
}
} else if(w34.contains(grid_regexp) and SpecOp::EU_VHF==m_config.special_op_id()) {
if(nrpt==0) {
setTxMsg(2);
m_QSOProgress=REPORT;
} else {
if(w2=="R") {
setTxMsg(4);
m_QSOProgress=ROGERS;
} else {
setTxMsg(3);
m_QSOProgress=ROGER_REPORT;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
------------------------------------------------------------------------ r5297 | bsomervi | 2015-04-26 17:26:54 +0100 (Sun, 26 Apr 2015) | 49 lines Various defect repairs and ambigous behaviour clarifications A regression introduced in v1.5.0-rc1 where PTT on an alternate serial port when using no CAT control is resolved. A regression introduced in v1.5.0-rc1 where the network server field was not being restored in the settings dialog has been resolved. In settings the "Test PTT" button is now styled by checked state. The "Test PTT" button is enabled without needing click "Test CAT" first when no CAT rig control is selected. Various parts of the settings dialog are now disabled when no CAT rig control is selected. These are the "Mode" group, the "Split Operation" group and the "Monitor returns to last used frequency" check box. None of these have any visible impact nor make sense without CAT rig control. Initialization and teardown of rig control internals has been revised to avoid several problems related to timing and when switching between different CAT settings. This includes improvements in having the operating frequency restored between sessions when not using CAT rig control. The initialization of OmniRig connections has been improved, unfortunately it is still possible to get an exception when clicking the "Test CAT" button where just clicking "OK" and leaving the settings dialog will probably work. Some unnecessary CAT commands output during direct rig control have been elided to reduce the level of traffic a little. The handling of some automatically generated free text messages used when the station is a type 2 compound callsign or is working a type 2 compound callsign has been improved. This is related to how a double click on a message of the form "DE TI4/N0URE 73" is double clicked. The new behaviour depends on whether the current "DX Call" matches the call in the message. This resolves the ambiguity as to whether this message is a sign off at the end of a QSO with current operator (a 73 message is generated) or a tail end opportunity where the message should be treated the same as a CQ or QRZ message (WSJT-X QSYs to the frequency, generates messages and selects message one ready to call). This still leaves some potential ambiguous behaviors in this complex area but selecting "Clear DX call and grid after logging" should resolve most of them. Rig control trace messages have been cleaned up and are now more helpful, less verbose and, tidier in the source code. ------------------------------------------------------------------------ Merged from the wsjtx-1.5 branch. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5298 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-26 12:41:12 -04:00
}
} else if(SpecOp::RTTY == m_config.special_op_id() and bRTTY) {
if(w2=="R") {
setTxMsg(4);
m_QSOProgress=ROGERS;
} else {
setTxMsg(3);
m_QSOProgress=ROGER_REPORT;
}
m_xRcvd=t[n-2] + " " + t[n-1];
} else if(SpecOp::FIELD_DAY==m_config.special_op_id() and bFieldDay_msg) {
if(t0=="R") {
setTxMsg(4);
m_QSOProgress=ROGERS;
} else {
setTxMsg(3);
m_QSOProgress=ROGER_REPORT;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
} else { // no grid on end of msg
auto const& word_3 = message_words.at (3);
bool word_3_is_int;
auto word_3_as_number = word_3.toInt (&word_3_is_int);
if(m_QSOProgress >= ROGER_REPORT && ("RRR" == word_3
|| (word_3_is_int && word_3_as_number == 73)
|| "RR73" == word_3)) {
if(m_mode=="FT4" and "RR73" == word_3) m_dateTimeRcvdRR73=QDateTime::currentDateTimeUtc();
m_bTUmsg=false;
m_nextCall=""; //### Temporary: disable use of "TU;" message
if(SpecOp::RTTY == m_config.special_op_id() and m_nextCall!="") {
// We're in RTTY contest and have "nextCall" queued up: send a "TU; ..." message
logQSOTimer.start(0);
ui->tx3->setText(ui->tx3->text().remove("TU; "));
useNextCall();
QString t="TU; " + ui->tx3->text();
ui->tx3->setText(t);
m_bTUmsg=true;
} else {
if(SpecOp::RTTY == m_config.special_op_id()) {
logQSOTimer.start(0);
m_ntx=6;
ui->txrb6->setChecked(true);
} else {
m_ntx=5;
ui->txrb5->setChecked(true);
}
}
m_QSOProgress = SIGNOFF;
} else if((m_QSOProgress >= REPORT
|| (m_QSOProgress >= REPLYING &&
(m_mode=="MSK144" or m_mode=="FT8" or m_mode=="FT4")))
&& word_3.startsWith ('R')) {
m_ntx=4;
m_QSOProgress = ROGERS;
if(SpecOp::RTTY == m_config.special_op_id()) {
int n=t.size();
int nRpt=t[n-2].toInt();
if(nRpt>=529 and nRpt<=599) m_xRcvd=t[n-2] + " " + t[n-1];
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
ui->txrb4->setChecked(true);
} else if (m_QSOProgress >= CALLING)
{
if (word_3_is_int
&& ((word_3_as_number >= -50 && word_3_as_number <= 49)
|| (word_3_as_number >= 529 && word_3_as_number <= 599))) {
if(SpecOp::EU_VHF==m_config.special_op_id() or
SpecOp::FIELD_DAY==m_config.special_op_id() or
SpecOp::RTTY==m_config.special_op_id()) {
setTxMsg(2);
m_QSOProgress=REPORT;
}
else {
setTxMsg (3);
m_QSOProgress = ROGER_REPORT;
}
} else {
if (word_3.startsWith ("R-") || word_3.startsWith ("R+")) {
setTxMsg(4);
m_QSOProgress=ROGERS;
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
}
else
{ // nothing for us
return;
}
}
}
else if (m_QSOProgress >= ROGERS
&& message_words.size () > 2 && message_words.at (1).contains (m_baseCall)
&& message_words.at (2) == "73") {
// 73 back to compound call holder
m_ntx=5;
ui->txrb5->setChecked(true);
m_QSOProgress = SIGNOFF;
}
else if (!(m_bAutoReply && (m_QSOProgress > CALLING))) {
if ((message_words.size () > 4 && message_words.at (1).contains (m_baseCall)
&& message_words.at (4) == "OOO")) {
// EME short code report or MSK144/FT8 contest mode reply, send back Tx3
m_ntx=3;
m_QSOProgress = ROGER_REPORT;
ui->txrb3->setChecked (true);
} else if (!is_73) { // don't respond to sign off messages
m_ntx=2;
m_QSOProgress = REPORT;
ui->txrb2->setChecked(true);
if (m_bDoubleClickAfterCQnnn and m_transmitting) {
on_stopTxButton_clicked();
TxAgainTimer.start(1500);
}
m_bDoubleClickAfterCQnnn=false;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
else {
return; // nothing we need to respond to
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
else { // nothing for us
// if(message_words.size () > 3 // enough fields for a normal message
// && SpecOp::RTTY == m_config.special_op_id()
// && (message_words.at(1).contains(m_baseCall) || "DE" == message_words.at(1))
// && (!message_words.at(2).contains(qso_partner_base_call) and !bEU_VHF_w2)) {
//// Queue up the next QSO partner
// m_nextCall=message_words.at(2);
// m_nextGrid=message_words.at(3);
// m_nextRpt=message.report();
// ui->labNextCall->setText("Next: " + m_nextCall);
// ui->labNextCall->setStyleSheet("QLabel {color: #000000; background-color: #66ff66}");
// }
return;
}
}
else if (firstcall == "DE" && message_words.size () > 3 && message_words.at (3) == "73") {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (m_QSOProgress >= ROGERS && base_call == qso_partner_base_call && m_currentMessageType) {
------------------------------------------------------------------------ r5297 | bsomervi | 2015-04-26 17:26:54 +0100 (Sun, 26 Apr 2015) | 49 lines Various defect repairs and ambigous behaviour clarifications A regression introduced in v1.5.0-rc1 where PTT on an alternate serial port when using no CAT control is resolved. A regression introduced in v1.5.0-rc1 where the network server field was not being restored in the settings dialog has been resolved. In settings the "Test PTT" button is now styled by checked state. The "Test PTT" button is enabled without needing click "Test CAT" first when no CAT rig control is selected. Various parts of the settings dialog are now disabled when no CAT rig control is selected. These are the "Mode" group, the "Split Operation" group and the "Monitor returns to last used frequency" check box. None of these have any visible impact nor make sense without CAT rig control. Initialization and teardown of rig control internals has been revised to avoid several problems related to timing and when switching between different CAT settings. This includes improvements in having the operating frequency restored between sessions when not using CAT rig control. The initialization of OmniRig connections has been improved, unfortunately it is still possible to get an exception when clicking the "Test CAT" button where just clicking "OK" and leaving the settings dialog will probably work. Some unnecessary CAT commands output during direct rig control have been elided to reduce the level of traffic a little. The handling of some automatically generated free text messages used when the station is a type 2 compound callsign or is working a type 2 compound callsign has been improved. This is related to how a double click on a message of the form "DE TI4/N0URE 73" is double clicked. The new behaviour depends on whether the current "DX Call" matches the call in the message. This resolves the ambiguity as to whether this message is a sign off at the end of a QSO with current operator (a 73 message is generated) or a tail end opportunity where the message should be treated the same as a CQ or QRZ message (WSJT-X QSYs to the frequency, generates messages and selects message one ready to call). This still leaves some potential ambiguous behaviors in this complex area but selecting "Clear DX call and grid after logging" should resolve most of them. Rig control trace messages have been cleaned up and are now more helpful, less verbose and, tidier in the source code. ------------------------------------------------------------------------ Merged from the wsjtx-1.5 branch. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5298 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-26 12:41:12 -04:00
// 73 back to compound call holder
m_ntx=5;
ui->txrb5->setChecked(true);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = SIGNOFF;
} else {
------------------------------------------------------------------------ r5297 | bsomervi | 2015-04-26 17:26:54 +0100 (Sun, 26 Apr 2015) | 49 lines Various defect repairs and ambigous behaviour clarifications A regression introduced in v1.5.0-rc1 where PTT on an alternate serial port when using no CAT control is resolved. A regression introduced in v1.5.0-rc1 where the network server field was not being restored in the settings dialog has been resolved. In settings the "Test PTT" button is now styled by checked state. The "Test PTT" button is enabled without needing click "Test CAT" first when no CAT rig control is selected. Various parts of the settings dialog are now disabled when no CAT rig control is selected. These are the "Mode" group, the "Split Operation" group and the "Monitor returns to last used frequency" check box. None of these have any visible impact nor make sense without CAT rig control. Initialization and teardown of rig control internals has been revised to avoid several problems related to timing and when switching between different CAT settings. This includes improvements in having the operating frequency restored between sessions when not using CAT rig control. The initialization of OmniRig connections has been improved, unfortunately it is still possible to get an exception when clicking the "Test CAT" button where just clicking "OK" and leaving the settings dialog will probably work. Some unnecessary CAT commands output during direct rig control have been elided to reduce the level of traffic a little. The handling of some automatically generated free text messages used when the station is a type 2 compound callsign or is working a type 2 compound callsign has been improved. This is related to how a double click on a message of the form "DE TI4/N0URE 73" is double clicked. The new behaviour depends on whether the current "DX Call" matches the call in the message. This resolves the ambiguity as to whether this message is a sign off at the end of a QSO with current operator (a 73 message is generated) or a tail end opportunity where the message should be treated the same as a CQ or QRZ message (WSJT-X QSYs to the frequency, generates messages and selects message one ready to call). This still leaves some potential ambiguous behaviors in this complex area but selecting "Clear DX call and grid after logging" should resolve most of them. Rig control trace messages have been cleaned up and are now more helpful, less verbose and, tidier in the source code. ------------------------------------------------------------------------ Merged from the wsjtx-1.5 branch. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5298 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-26 12:41:12 -04:00
// treat like a CQ/QRZ
if (ui->tx1->isEnabled ()) {
m_ntx = 1;
m_QSOProgress = REPLYING;
ui->txrb1->setChecked (true);
} else {
m_ntx=2;
m_QSOProgress = REPORT;
ui->txrb2->setChecked (true);
}
------------------------------------------------------------------------ r5297 | bsomervi | 2015-04-26 17:26:54 +0100 (Sun, 26 Apr 2015) | 49 lines Various defect repairs and ambigous behaviour clarifications A regression introduced in v1.5.0-rc1 where PTT on an alternate serial port when using no CAT control is resolved. A regression introduced in v1.5.0-rc1 where the network server field was not being restored in the settings dialog has been resolved. In settings the "Test PTT" button is now styled by checked state. The "Test PTT" button is enabled without needing click "Test CAT" first when no CAT rig control is selected. Various parts of the settings dialog are now disabled when no CAT rig control is selected. These are the "Mode" group, the "Split Operation" group and the "Monitor returns to last used frequency" check box. None of these have any visible impact nor make sense without CAT rig control. Initialization and teardown of rig control internals has been revised to avoid several problems related to timing and when switching between different CAT settings. This includes improvements in having the operating frequency restored between sessions when not using CAT rig control. The initialization of OmniRig connections has been improved, unfortunately it is still possible to get an exception when clicking the "Test CAT" button where just clicking "OK" and leaving the settings dialog will probably work. Some unnecessary CAT commands output during direct rig control have been elided to reduce the level of traffic a little. The handling of some automatically generated free text messages used when the station is a type 2 compound callsign or is working a type 2 compound callsign has been improved. This is related to how a double click on a message of the form "DE TI4/N0URE 73" is double clicked. The new behaviour depends on whether the current "DX Call" matches the call in the message. This resolves the ambiguity as to whether this message is a sign off at the end of a QSO with current operator (a 73 message is generated) or a tail end opportunity where the message should be treated the same as a CQ or QRZ message (WSJT-X QSYs to the frequency, generates messages and selects message one ready to call). This still leaves some potential ambiguous behaviors in this complex area but selecting "Clear DX call and grid after logging" should resolve most of them. Rig control trace messages have been cleaned up and are now more helpful, less verbose and, tidier in the source code. ------------------------------------------------------------------------ Merged from the wsjtx-1.5 branch. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5298 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-26 12:41:12 -04:00
}
}
else if (is_73 && !message.isStandardMessage ()) {
m_ntx=5;
ui->txrb5->setChecked(true);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = SIGNOFF;
} else {
// just work them
if (ui->tx1->isEnabled ()) {
m_ntx = 1;
m_QSOProgress = REPLYING;
ui->txrb1->setChecked (true);
} else {
m_ntx=2;
m_QSOProgress = REPORT;
ui->txrb2->setChecked (true);
}
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
// if we get here then we are reacting to the message
if (m_bAutoReply) m_bCallingCQ = CALLING == m_QSOProgress;
if (ui->RxFreqSpinBox->isEnabled () and m_mode != "MSK144" and !shift) {
ui->RxFreqSpinBox->setValue (frequency); //Set Rx freq
}
QString s1 = m_QSOText.trimmed ();
QString s2 = message.string ().trimmed();
if (s1!=s2 and !message.isTX()) {
if (!s2.contains(m_baseCall) or m_mode=="MSK144") { // Taken care of elsewhere if for_us and slow mode
ui->decodedTextBrowser2->displayDecodedText(message, m_baseCall,m_mode,m_config.DXCC(),
m_logBook,m_currentBand,m_config.ppfx());
}
m_QSOText = s2;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
if (Radio::is_callsign (hiscall)
&& (base_call != qso_partner_base_call || base_call != hiscall)) {
if (qso_partner_base_call != base_call) {
// clear the DX grid if the base call of his call is different
// from the current DX call
ui->dxGridEntry->clear ();
}
// his base call different or his call more qualified
// i.e. compound version of same base call
ui->dxCallEntry->setText (hiscall);
}
if (hisgrid.contains (grid_regexp)) {
if(ui->dxGridEntry->text().mid(0,4) != hisgrid) ui->dxGridEntry->setText(hisgrid);
}
lookup();
m_hisGrid = ui->dxGridEntry->text();
QString rpt = message.report();
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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int n=rpt.toInt();
if(m_mode=="MSK144" and m_bShMsgs) {
int n=rpt.toInt();
if(n<=-2) n=-3;
if(n>=-1 and n<=1) n=0;
if(n>=2 and n<=4) n=3;
if(n>=5 and n<=7) n=6;
if(n>=8 and n<=11) n=10;
if(n>=12 and n<=14) n=13;
if(n>=15) n=16;
rpt=QString::number(n);
}
ui->rptSpinBox->setValue(n);
// Don't genStdMsgs if we're already sending 73, or a "TU; " msg is queued.
m_bTUmsg=false; //### Temporary: disable use of "TU;" messages
if (!m_nTx73 and !m_bTUmsg) {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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genStdMsgs(rpt);
}
if(m_transmitting) m_restart=true;
2019-01-24 11:58:57 -05:00
if (ui->cbAutoSeq->isVisible () && ui->cbAutoSeq->isChecked ()
&& !m_bDoubleClicked && m_mode!="FT4") {
return;
}
if(m_config.quick_call() && m_bDoubleClicked) auto_tx_mode(true);
m_bDoubleClicked=false;
}
void MainWindow::setTxMsg(int n)
{
m_ntx=n;
if(n==1) ui->txrb1->setChecked(true);
if(n==2) ui->txrb2->setChecked(true);
if(n==3) ui->txrb3->setChecked(true);
if(n==4) ui->txrb4->setChecked(true);
if(n==5) ui->txrb5->setChecked(true);
2019-01-28 14:20:32 -05:00
if(n==6) ui->txrb6->setChecked(true);
}
void MainWindow::genCQMsg ()
{
if(m_config.my_callsign().size () && m_config.my_grid().size ()) {
QString grid{m_config.my_grid()};
if (ui->cbCQTx->isEnabled () && ui->cbCQTx->isVisible () && ui->cbCQTx->isChecked ()) {
if(stdCall(m_config.my_callsign())) {
msgtype (QString {"CQ %1 %2 %3"}
.arg (m_freqNominal / 1000 - m_freqNominal / 1000000 * 1000, 3, 10, QChar {'0'})
.arg (m_config.my_callsign())
.arg (grid.left (4)),
ui->tx6);
} else {
msgtype (QString {"CQ %1 %2"}
.arg (m_freqNominal / 1000 - m_freqNominal / 1000000 * 1000, 3, 10, QChar {'0'})
.arg (m_config.my_callsign()),
ui->tx6);
}
} else {
if(stdCall(m_config.my_callsign())) {
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msgtype (QString {"%1 %2 %3"}.arg(m_CQtype).arg(m_config.my_callsign())
.arg(grid.left(4)),ui->tx6);
} else {
msgtype (QString {"%1 %2"}.arg(m_CQtype).arg(m_config.my_callsign()),ui->tx6);
}
}
if ((m_mode=="JT4" or m_mode=="QRA64") and ui->cbShMsgs->isChecked()) {
if (ui->cbTx6->isChecked ()) {
msgtype ("@1250 (SEND MSGS)", ui->tx6);
} else {
msgtype ("@1000 (TUNE)", ui->tx6);
}
}
2018-07-31 11:39:25 -04:00
2018-09-27 14:28:17 -04:00
QString t=ui->tx6->text();
QStringList tlist=t.split(" ");
if((m_mode=="FT4" or m_mode=="FT8" or m_mode=="MSK144") and
SpecOp::NONE != m_config.special_op_id() and
( tlist.at(1)==m_config.my_callsign() or
tlist.at(2)==m_config.my_callsign() ) and
stdCall(m_config.my_callsign())) {
if(SpecOp::NA_VHF == m_config.special_op_id()) m_cqStr="TEST";
if(SpecOp::EU_VHF == m_config.special_op_id()) m_cqStr="TEST";
if(SpecOp::FIELD_DAY == m_config.special_op_id()) m_cqStr="FD";
if(SpecOp::RTTY == m_config.special_op_id()) m_cqStr="RU";
if(SpecOp::WW_DIGI == m_config.special_op_id()) m_cqStr="WW";
if( tlist.at(1)==m_config.my_callsign() ) {
t="CQ " + m_cqStr + " " + tlist.at(1) + " " + tlist.at(2);
} else {
t="CQ " + m_cqStr + " " + tlist.at(2) + " " + tlist.at(3);
}
ui->tx6->setText(t);
}
} else {
ui->tx6->clear ();
}
}
void MainWindow::abortQSO()
{
bool b=m_auto;
clearDX();
if(b) auto_tx_mode(false);
ui->txrb6->setChecked(true);
}
bool MainWindow::stdCall(QString const& w)
{
static QRegularExpression standard_call_re {
R"(
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^\s* # optional leading spaces
( [A-Z]{0,2} | [A-Z][0-9] | [0-9][A-Z] ) # part 1
( [0-9][A-Z]{0,3} ) # part 2
2020-08-13 05:30:49 -04:00
(/R | /P)? # optional suffix
\s*$ # optional trailing spaces
)", QRegularExpression::CaseInsensitiveOption | QRegularExpression::ExtendedPatternSyntaxOption};
return standard_call_re.match (w).hasMatch ();
}
void MainWindow::genStdMsgs(QString rpt, bool unconditional)
{
genCQMsg ();
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
auto const& hisCall=ui->dxCallEntry->text();
if(!hisCall.size ()) {
ui->labAz->clear ();
ui->tx1->clear ();
ui->tx2->clear ();
ui->tx3->clear ();
ui->tx4->clear ();
if(unconditional) ui->tx5->lineEdit ()->clear (); //Test if it needs sending again
m_gen_message_is_cq = false;
return;
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
auto const& my_callsign = m_config.my_callsign ();
auto is_compound = my_callsign != m_baseCall;
auto is_type_one = is_compound && shortList (my_callsign);
auto const& my_grid = m_config.my_grid ().left (4);
auto const& hisBase = Radio::base_callsign (hisCall);
auto eme_short_codes = m_config.enable_VHF_features () && ui->cbShMsgs->isChecked ()
&& m_mode == "JT65";
bool bMyCall=stdCall(my_callsign);
bool bHisCall=stdCall(hisCall);
QString t0=hisBase + " " + m_baseCall + " ";
QString t0s=hisCall + " " + my_callsign + " ";
QString t0a,t0b;
if(bHisCall and bMyCall) t0=hisCall + " " + my_callsign + " ";
t0a="<"+hisCall + "> " + my_callsign + " ";
t0b=hisCall + " <" + my_callsign + "> ";
QString t00=t0;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
QString t {t0 + my_grid};
if(!bMyCall) t=t0a;
msgtype(t, ui->tx1);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (eme_short_codes) {
t=t+" OOO";
msgtype(t, ui->tx2);
msgtype("RO", ui->tx3);
msgtype("RRR", ui->tx4);
msgtype("73", ui->tx5->lineEdit());
} else {
int n=rpt.toInt();
2020-05-06 21:56:57 -04:00
rpt = rpt.asprintf("%+2.2d",n);
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if(m_mode=="MSK144" or m_mode=="FT8" or m_mode=="FT4" || m_mode=="FST4") {
QString t2,t3;
QString sent=rpt;
QString rs,rst;
int nn=(n+36)/6;
if(nn<2) nn=2;
if(nn>9) nn=9;
2020-05-06 21:56:57 -04:00
rst = rst.asprintf("5%1d9 ",nn);
rs=rst.mid(0,2);
t=t0;
if(!bMyCall) {
t=t0b;
msgtype(t0a, ui->tx1);
}
if(!bHisCall) {
t=t0a;
msgtype(t0a + my_grid, ui->tx1);
}
if(SpecOp::NA_VHF==m_config.special_op_id()) sent=my_grid;
if(SpecOp::WW_DIGI==m_config.special_op_id()) sent=my_grid;
if(SpecOp::FIELD_DAY==m_config.special_op_id()) sent=m_config.Field_Day_Exchange();
if(SpecOp::RTTY==m_config.special_op_id()) {
sent=rst + m_config.RTTY_Exchange();
QString t1=m_config.RTTY_Exchange();
if(t1=="DX" or t1=="#") {
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t1 = t1.asprintf("%4.4d",ui->sbSerialNumber->value());
sent=rst + t1;
}
}
if(SpecOp::EU_VHF==m_config.special_op_id()) {
QString a;
t="<" + t0s.split(" ").at(0) + "> <" + t0s.split(" ").at(1) + "> ";
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a = a.asprintf("%4.4d ",ui->sbSerialNumber->value());
sent=rs + a + m_config.my_grid();
}
msgtype(t + sent, ui->tx2);
if(sent==rpt) msgtype(t + "R" + sent, ui->tx3);
if(sent!=rpt) msgtype(t + "R " + sent, ui->tx3);
if(m_mode=="FT4" and SpecOp::RTTY==m_config.special_op_id()) {
QDateTime now=QDateTime::currentDateTimeUtc();
int sinceTx3 = m_dateTimeSentTx3.secsTo(now);
int sinceRR73 = m_dateTimeRcvdRR73.secsTo(now);
if(m_bDoubleClicked and (sinceTx3 < 15) and (sinceRR73 < 3)) {
t="TU; " + ui->tx3->text();
ui->tx3->setText(t);
}
}
}
if(m_mode=="MSK144" and m_bShMsgs) {
int i=t0s.length()-1;
t0="<" + t0s.mid(0,i) + "> ";
if(SpecOp::NA_VHF != m_config.special_op_id()) {
if(n<=-2) n=-3;
if(n>=-1 and n<=1) n=0;
if(n>=2 and n<=4) n=3;
if(n>=5 and n<=7) n=6;
if(n>=8 and n<=11) n=10;
if(n>=12 and n<=14) n=13;
if(n>=15) n=16;
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rpt = rpt.asprintf("%+2.2d",n);
}
}
if((m_mode!="MSK144" and m_mode!="FT8" and m_mode!="FT4" && m_mode != "FST4")) {
t=t00 + rpt;
msgtype(t, ui->tx2);
t=t0 + "R" + rpt;
msgtype(t, ui->tx3);
}
if(m_mode=="MSK144" and m_bShMsgs) {
if(m_config.special_op_id()==SpecOp::NONE) {
t=t0 + "R" + rpt;
msgtype(t, ui->tx3);
}
m_send_RR73=false;
}
t=t0 + (m_send_RR73 ? "RR73" : "RRR");
2020-07-23 13:51:05 -04:00
if((m_mode=="MSK144" and !m_bShMsgs) or m_mode=="FT8" or m_mode=="FT4" || m_mode == "FST4") {
if(!bHisCall and bMyCall) t=hisCall + " <" + my_callsign + "> " + (m_send_RR73 ? "RR73" : "RRR");
if(bHisCall and !bMyCall) t="<" + hisCall + "> " + my_callsign + " " + (m_send_RR73 ? "RR73" : "RRR");
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if ((m_mode=="JT4" || m_mode=="QRA64") && m_bShMsgs) t="@1500 (RRR)";
msgtype(t, ui->tx4);
t=t0 + "73";
2020-07-23 13:51:05 -04:00
if((m_mode=="MSK144" and !m_bShMsgs) or m_mode=="FT8" or m_mode=="FT4" || m_mode == "FST4") {
if(!bHisCall and bMyCall) t=hisCall + " <" + my_callsign + "> 73";
if(bHisCall and !bMyCall) t="<" + hisCall + "> " + my_callsign + " 73";
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (m_mode=="JT4" || m_mode=="QRA64") {
if (m_bShMsgs) t="@1750 (73)";
msgtype(t, ui->tx5->lineEdit());
} else if ("MSK144" == m_mode && m_bShMsgs) {
msgtype(t, ui->tx5->lineEdit());
} else if(unconditional || hisBase != m_lastCallsign || !m_lastCallsign.size ()) {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
// only update tx5 when forced or callsign changes
msgtype(t, ui->tx5->lineEdit());
m_lastCallsign = hisBase;
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
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if(m_mode=="FT8" or m_mode=="FT4" or m_mode=="MSK144" || m_mode == "FST4") return;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (is_compound) {
if (is_type_one) {
t=hisBase + " " + my_callsign;
msgtype(t, ui->tx1);
} else {
t = "DE " + my_callsign + " ";
switch (m_config.type_2_msg_gen ())
{
case Configuration::type_2_msg_1_full:
msgtype(t + my_grid, ui->tx1);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (!eme_short_codes) {
if((m_mode=="MSK144" || m_mode=="FT8" || m_mode=="FT4" || m_mode == "FST4") &&
SpecOp::NA_VHF == m_config.special_op_id()) {
msgtype(t + "R " + my_grid, ui->tx3); // #### Unreachable code
} else {
msgtype(t + "R" + rpt, ui->tx3);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if ((m_mode != "JT4" && m_mode != "QRA64") || !m_bShMsgs) {
msgtype(t + "73", ui->tx5->lineEdit ());
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
}
break;
case Configuration::type_2_msg_3_full:
if ((m_mode=="MSK144" || m_mode=="FT8" || m_mode=="FT4" || m_mode == "FST4") &&
SpecOp::NA_VHF == m_config.special_op_id()) {
msgtype(t + "R " + my_grid, ui->tx3);
msgtype(t + "RRR", ui->tx4);
} else {
msgtype(t00 + my_grid, ui->tx1);
msgtype(t + "R" + rpt, ui->tx3);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (!eme_short_codes && ((m_mode != "JT4" && m_mode != "QRA64") || !m_bShMsgs)) {
msgtype(t + "73", ui->tx5->lineEdit ());
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
break;
case Configuration::type_2_msg_5_only:
msgtype(t00 + my_grid, ui->tx1);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (!eme_short_codes) {
if ((m_mode=="MSK144" || m_mode=="FT8" || m_mode=="FT4" || m_mode == "FST4") &&
SpecOp::NA_VHF == m_config.special_op_id()) {
msgtype(t + "R " + my_grid, ui->tx3); // #### Unreachable code
msgtype(t + "RRR", ui->tx4);
} else {
msgtype(t0 + "R" + rpt, ui->tx3);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
// don't use short codes here as in a sked with a type 2
// prefix we would never send out prefix/suffix
msgtype(t + "73", ui->tx5->lineEdit ());
break;
}
}
if (hisCall != hisBase
&& m_config.type_2_msg_gen () != Configuration::type_2_msg_5_only
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
&& !eme_short_codes) {
// cfm we have his full call copied as we could not do this earlier
t = hisCall + " 73";
msgtype(t, ui->tx5->lineEdit ());
}
} else {
if (hisCall != hisBase and SpecOp::HOUND != m_config.special_op_id()) {
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if (shortList(hisCall)) {
// cfm we know his full call with a type 1 tx1 message
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
t = hisCall + " " + my_callsign;
msgtype(t, ui->tx1);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
else if (!eme_short_codes
&& ("MSK144" != m_mode || !m_bShMsgs)) {
t=hisCall + " 73";
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
msgtype(t, ui->tx5->lineEdit ());
}
}
}
m_rpt=rpt;
if(SpecOp::HOUND == m_config.special_op_id() and is_compound) ui->tx1->setText("DE " + m_config.my_callsign());
}
void MainWindow::TxAgain()
{
auto_tx_mode(true);
}
void MainWindow::clearDX ()
{
set_dateTimeQSO (-1);
if (m_QSOProgress != CALLING) {
auto_tx_mode (false);
}
ui->dxCallEntry->clear ();
ui->dxGridEntry->clear ();
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_lastCallsign.clear ();
m_rptSent.clear ();
m_rptRcvd.clear ();
m_qsoStart.clear ();
m_qsoStop.clear ();
m_inQSOwith.clear();
genStdMsgs (QString {});
if (m_mode=="FT8" and SpecOp::HOUND == m_config.special_op_id()) {
m_ntx=1;
ui->txrb1->setChecked(true);
} else {
m_ntx=6;
ui->txrb6->setChecked(true);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = CALLING;
}
void MainWindow::lookup()
{
QString hisCall {ui->dxCallEntry->text()};
QString hisgrid0 {ui->dxGridEntry->text()};
if (!hisCall.size ()) return;
QFile f {m_config.writeable_data_dir ().absoluteFilePath ("CALL3.TXT")};
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
if (f.open (QIODevice::ReadOnly | QIODevice::Text))
{
char c[132];
qint64 n=0;
for(int i=0; i<999999; i++) {
n=f.readLine(c,sizeof(c));
if(n <= 0) {
if(!hisgrid0.contains(grid_regexp)) {
ui->dxGridEntry->clear();
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
break;
}
QString t=QString(c);
if(t.indexOf(hisCall)==0) {
int i1=t.indexOf(",");
QString hisgrid=t.mid(i1+1,6);
i1=hisgrid.indexOf(",");
if(i1>0) {
hisgrid=hisgrid.mid(0,4);
} else {
hisgrid=hisgrid.mid(0,6).toUpper();
}
if(hisgrid.left(4)==hisgrid0.left(4) or (hisgrid0.size()==0)) {
ui->dxGridEntry->setText(hisgrid);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
break;
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
f.close();
}
}
void MainWindow::on_lookupButton_clicked() //Lookup button
{
lookup();
}
void MainWindow::on_addButton_clicked() //Add button
{
if(!ui->dxGridEntry->text ().size ()) {
MessageBox::warning_message (this, tr ("Add to CALL3.TXT")
, tr ("Please enter a valid grid locator"));
return;
}
m_call3Modified=false;
QString hisCall=ui->dxCallEntry->text();
QString hisgrid=ui->dxGridEntry->text();
QString newEntry=hisCall + "," + hisgrid;
// int ret = MessageBox::query_message(this, tr ("Add to CALL3.TXT"),
// tr ("Is %1 known to be active on EME?").arg (newEntry));
// if(ret==MessageBox::Yes) {
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// newEntry += ",EME,,";
// } else {
newEntry += ",,,";
// }
QFile f1 {m_config.writeable_data_dir ().absoluteFilePath ("CALL3.TXT")};
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
if(!f1.open(QIODevice::ReadWrite | QIODevice::Text)) {
MessageBox::warning_message (this, tr ("Add to CALL3.TXT")
, tr ("Cannot open \"%1\" for read/write: %2")
.arg (f1.fileName ()).arg (f1.errorString ()));
return;
}
if(f1.size()==0) {
QTextStream out(&f1);
2020-06-13 11:04:41 -04:00
out << "ZZZZZZ"
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f1.close();
f1.open(QIODevice::ReadOnly | QIODevice::Text);
}
QFile f2 {m_config.writeable_data_dir ().absoluteFilePath ("CALL3.TMP")};
if(!f2.open(QIODevice::WriteOnly | QIODevice::Text)) {
MessageBox::warning_message (this, tr ("Add to CALL3.TXT")
, tr ("Cannot open \"%1\" for writing: %2")
.arg (f2.fileName ()).arg (f2.errorString ()));
return;
}
QTextStream in(&f1); //Read from CALL3.TXT
QTextStream out(&f2); //Copy into CALL3.TMP
QString hc=hisCall;
QString hc1="";
QString hc2="000000";
QString s;
do {
s=in.readLine();
hc1=hc2;
if(s.mid(0,2)=="//") {
out << s + QChar::LineFeed; //Copy all comment lines
} else {
int i1=s.indexOf(",");
hc2=s.mid(0,i1);
if(hc>hc1 && hc<hc2) {
out << newEntry + QChar::LineFeed;
out << s + QChar::LineFeed;
m_call3Modified=true;
} else if(hc==hc2) {
QString t {tr ("%1\nis already in CALL3.TXT"
", do you wish to replace it?").arg (s)};
int ret = MessageBox::query_message (this, tr ("Add to CALL3.TXT"), t);
if(ret==MessageBox::Yes) {
out << newEntry + QChar::LineFeed;
m_call3Modified=true;
}
} else {
if(s!="") out << s + QChar::LineFeed;
}
}
} while(!s.isNull());
f1.close();
if(hc>hc1 && !m_call3Modified) out << newEntry + QChar::LineFeed;
if(m_call3Modified) {
QFile f0 {m_config.writeable_data_dir ().absoluteFilePath ("CALL3.OLD")};
if(f0.exists()) f0.remove();
QFile f1 {m_config.writeable_data_dir ().absoluteFilePath ("CALL3.TXT")};
f1.rename(m_config.writeable_data_dir ().absoluteFilePath ("CALL3.OLD"));
f2.rename(m_config.writeable_data_dir ().absoluteFilePath ("CALL3.TXT"));
f2.close();
}
}
void MainWindow::msgtype(QString t, QLineEdit* tx) //msgtype()
{
// Set background colors of the Tx message boxes, depending on message type
char message[38];
char msgsent[38];
QByteArray s=t.toUpper().toLocal8Bit();
ba2msg(s,message);
int ichk=1,itype=0;
2018-07-10 09:04:01 -04:00
gen65_(message,&ichk,msgsent,const_cast<int*>(itone0),&itype,22,22);
msgsent[22]=0;
bool text=false;
bool shortMsg=false;
if(itype==6) text=true;
//### Check this stuff ###
if(itype==7 and m_config.enable_VHF_features() and m_mode=="JT65") shortMsg=true;
if(m_mode=="MSK144" and t.mid(0,1)=="<") text=false;
if((m_mode=="MSK144" or m_mode=="FT8" or m_mode=="FT4") and
SpecOp::NA_VHF==m_config.special_op_id()) {
int i0=t.trimmed().length()-7;
if(t.mid(i0,3)==" R ") text=false;
}
text=false;
//### ... to here ...
QPalette p(tx->palette());
if(text) {
p.setColor(QPalette::Base,"#ffccff"); //pink
} else {
if(shortMsg) {
p.setColor(QPalette::Base,"#66ffff"); //light blue
} else {
p.setColor(QPalette::Base,Qt::transparent);
if(m_mode=="MSK144" and t.mid(0,1)=="<") {
p.setColor(QPalette::Base,"#00ffff"); //another light blue
}
}
}
tx->setPalette(p);
auto pos = tx->cursorPosition ();
tx->setText(t.toUpper());
tx->setCursorPosition (pos);
}
void MainWindow::on_tx1_editingFinished() //tx1 edited
{
QString t=ui->tx1->text();
msgtype(t, ui->tx1);
}
void MainWindow::on_tx2_editingFinished() //tx2 edited
{
QString t=ui->tx2->text();
msgtype(t, ui->tx2);
}
void MainWindow::on_tx3_editingFinished() //tx3 edited
{
QString t=ui->tx3->text();
msgtype(t, ui->tx3);
}
void MainWindow::on_tx4_editingFinished() //tx4 edited
{
QString t=ui->tx4->text();
msgtype(t, ui->tx4);
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::on_tx5_currentTextChanged (QString const& text) //tx5 edited
{
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
msgtype(text, ui->tx5->lineEdit ());
}
void MainWindow::on_tx6_editingFinished() //tx6 edited
{
QString t=ui->tx6->text().toUpper();
if(t.indexOf(" ")>0) {
QString t1=t.split(" ").at(1);
QRegExp AZ4("^[A-Z]{1,4}$");
QRegExp NN3("^[0-9]{1,3}$");
m_CQtype="CQ";
if(t1.size()<=4 and t1.contains(AZ4)) m_CQtype="CQ " + t1;
if(t1.size()<=3 and t1.contains(NN3)) m_CQtype="CQ " + t1;
}
msgtype(t, ui->tx6);
}
2020-07-03 14:17:13 -04:00
void MainWindow::on_RoundRobin_currentTextChanged(QString text)
{
2020-08-08 16:25:32 -04:00
ui->sbTxPercent->setEnabled (text == tr ("Random"));
2020-07-03 14:17:13 -04:00
}
void MainWindow::on_dxCallEntry_textChanged (QString const& call)
{
m_hisCall = call;
ui->dxGridEntry->clear();
statusChanged();
statusUpdate ();
}
void MainWindow::on_dxCallEntry_returnPressed ()
{
on_lookupButton_clicked();
}
void MainWindow::on_dxGridEntry_textChanged (QString const& grid)
{
if (ui->dxGridEntry->hasAcceptableInput ()) {
if (grid != m_hisGrid) {
m_hisGrid = grid;
statusUpdate ();
}
qint64 nsec = (QDateTime::currentMSecsSinceEpoch()/1000) % 86400;
double utch=nsec/3600.0;
int nAz,nEl,nDmiles,nDkm,nHotAz,nHotABetter;
azdist_(const_cast <char *> ((m_config.my_grid () + " ").left (6).toLatin1().constData()),
const_cast <char *> ((m_hisGrid + " ").left (6).toLatin1().constData()),&utch,
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
&nAz,&nEl,&nDmiles,&nDkm,&nHotAz,&nHotABetter,6,6);
QString t;
int nd=nDkm;
if(m_config.miles()) nd=nDmiles;
if(m_mode=="MSK144") {
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if(nHotABetter==0)t = t.asprintf("Az: %d B: %d El: %d %d",nAz,nHotAz,nEl,nd);
if(nHotABetter!=0)t = t.asprintf("Az: %d A: %d El: %d %d",nAz,nHotAz,nEl,nd);
} else {
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t = t.asprintf("Az: %d %d",nAz,nd);
}
if(m_config.miles()) t += " mi";
if(!m_config.miles()) t += " km";
ui->labAz->setText (t);
} else {
if (m_hisGrid.size ()) {
m_hisGrid.clear ();
ui->labAz->clear ();
statusUpdate ();
}
}
}
void MainWindow::on_genStdMsgsPushButton_clicked() //genStdMsgs button
{
genStdMsgs(m_rpt);
}
void MainWindow::on_logQSOButton_clicked() //Log QSO button
{
if (SpecOp::FOX != m_config.special_op_id ()
&& ui->cbAutoSeq->isVisible () && ui->cbAutoSeq->isEnabled () && ui->cbAutoSeq->isChecked ())
{
// ensure that auto Tx is disabled even if clear DX call & grid
// on 73 is not checked, unless in Fox mode where it is allowed
// to be a robot.
auto_tx_mode (false);
}
if (!m_hisCall.size ()) {
MessageBox::warning_message (this, tr ("Warning: DX Call field is empty."));
}
// m_dateTimeQSOOn should really already be set but we'll ensure it gets set to something just in case
if (!m_dateTimeQSOOn.isValid ()) {
m_dateTimeQSOOn = QDateTime::currentDateTimeUtc();
}
auto dateTimeQSOOff = QDateTime::currentDateTimeUtc();
if (dateTimeQSOOff < m_dateTimeQSOOn) dateTimeQSOOff = m_dateTimeQSOOn;
QString grid=m_hisGrid;
if(grid=="....") grid="";
switch( m_config.special_op_id() )
{
case SpecOp::NA_VHF:
m_xSent=m_config.my_grid().left(4);
m_xRcvd=m_hisGrid;
break;
case SpecOp::EU_VHF:
m_rptSent=m_xSent.split(" ").at(0).left(2);
m_rptRcvd=m_xRcvd.split(" ").at(0).left(2);
if(m_xRcvd.split(" ").size()>=2) m_hisGrid=m_xRcvd.split(" ").at(1);
grid=m_hisGrid;
ui->dxGridEntry->setText(grid);
break;
case SpecOp::FIELD_DAY:
m_rptSent=m_xSent.split(" ").at(0);
m_rptRcvd=m_xRcvd.split(" ").at(0);
break;
case SpecOp::RTTY:
m_rptSent=m_xSent.split(" ").at(0);
m_rptRcvd=m_xRcvd.split(" ").at(0);
break;
case SpecOp::WW_DIGI:
m_xSent=m_config.my_grid().left(4);
m_xRcvd=m_hisGrid;
break;
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default: break;
}
m_logDlg->initLogQSO (m_hisCall, grid, m_modeTx, m_rptSent, m_rptRcvd,
m_dateTimeQSOOn, dateTimeQSOOff, m_freqNominal +
ui->TxFreqSpinBox->value(), m_noSuffix, m_xSent, m_xRcvd);
m_inQSOwith="";
}
void MainWindow::acceptQSO (QDateTime const& QSO_date_off, QString const& call, QString const& grid
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
, Frequency dial_freq, QString const& mode
, QString const& rpt_sent, QString const& rpt_received
, QString const& tx_power, QString const& comments
, QString const& name, QDateTime const& QSO_date_on, QString const& operator_call
, QString const& my_call, QString const& my_grid
, QString const& exchange_sent, QString const& exchange_rcvd
, QString const& propmode, QByteArray const& ADIF)
{
QString date = QSO_date_on.toString("yyyyMMdd");
if (!m_logBook.add (call, grid, m_config.bands()->find(dial_freq), mode, ADIF))
{
MessageBox::warning_message (this, tr ("Log file error"),
tr ("Cannot open \"%1\"").arg (m_logBook.path ()));
}
m_messageClient->qso_logged (QSO_date_off, call, grid, dial_freq, mode, rpt_sent, rpt_received
, tx_power, comments, name, QSO_date_on, operator_call, my_call, my_grid
, exchange_sent, exchange_rcvd, propmode);
m_messageClient->logged_ADIF (ADIF);
// Log to N1MM Logger
if (m_config.broadcast_to_n1mm () && m_config.valid_n1mm_info ())
{
QUdpSocket sock;
if (-1 == sock.writeDatagram (ADIF + " <eor>"
, QHostAddress {m_config.n1mm_server_name ()}
, m_config.n1mm_server_port ()))
{
MessageBox::warning_message (this, tr ("Error sending log to N1MM"),
tr ("Write returned \"%1\"").arg (sock.errorString ()));
}
}
if(m_config.clear_DX () and SpecOp::HOUND != m_config.special_op_id()) clearDX ();
m_dateTimeQSOOn = QDateTime {};
auto special_op = m_config.special_op_id ();
if (SpecOp::NONE < special_op && special_op < SpecOp::FOX) {
ui->sbSerialNumber->setValue(ui->sbSerialNumber->value() + 1);
}
m_xSent.clear ();
m_xRcvd.clear ();
}
qint64 MainWindow::nWidgets(QString t)
{
Q_ASSERT(t.length()==N_WIDGETS);
qint64 n=0;
for(int i=0; i<N_WIDGETS; i++) {
n=n + n + t.mid(i,1).toInt();
}
return n;
}
void MainWindow::displayWidgets(qint64 n)
{
/* See text file "displayWidgets.txt" for widget numbers */
qint64 j=qint64(1)<<(N_WIDGETS-1);
bool b;
for(int i=0; i<N_WIDGETS; i++) {
b=(n&j) != 0;
if(i==0) ui->txFirstCheckBox->setVisible(b);
if(i==1) ui->TxFreqSpinBox->setVisible(b);
if(i==2) ui->RxFreqSpinBox->setVisible(b);
if(i==3) ui->sbFtol->setVisible(b);
if(i==4) ui->rptSpinBox->setVisible(b);
if(i==5) ui->sbTR->setVisible(b);
if(i==6) {
ui->sbCQTxFreq->setVisible (b);
ui->cbCQTx->setVisible (b);
auto is_compound = m_config.my_callsign () != m_baseCall;
ui->cbCQTx->setEnabled (b && (!is_compound || shortList (m_config.my_callsign ())));
}
if(i==7) ui->cbShMsgs->setVisible(b);
if(i==8) ui->cbFast9->setVisible(b);
if(i==9) ui->cbAutoSeq->setVisible(b);
if(i==10) ui->cbTx6->setVisible(b);
if(i==11) ui->pbTxMode->setVisible(b);
if(i==12) ui->pbR2T->setVisible(b);
if(i==13) ui->pbT2R->setVisible(b);
if(i==14) ui->cbHoldTxFreq->setVisible(b);
if(i==15) ui->sbSubmode->setVisible(b);
if(i==16) ui->syncSpinBox->setVisible(b);
if(i==17) ui->WSPR_controls_widget->setVisible(b);
if(i==18) ui->ClrAvgButton->setVisible(b);
if(i==19) ui->actionQuickDecode->setEnabled(b);
if(i==19) ui->actionMediumDecode->setEnabled(b);
if(i==19) ui->actionDeepestDecode->setEnabled(b);
if(i==20) ui->actionInclude_averaging->setVisible (b);
if(i==21) ui->actionInclude_correlation->setVisible (b);
if(i==22) {
if(!b && m_echoGraph->isVisible()) m_echoGraph->hide();
}
if(i==23) ui->cbSWL->setVisible(b);
if(i==24) ui->actionEnable_AP_FT8->setVisible (b);
if(i==25) ui->actionEnable_AP_JT65->setVisible (b);
if(i==26) ui->actionEnable_AP_DXcall->setVisible (b);
if(i==27) ui->cbFirst->setVisible(b);
if(i==28) ui->labNextCall->setVisible(b);
if(i==29) ui->measure_check_box->setVisible(b);
if(i==30) ui->labDXped->setVisible(b);
if(i==31) ui->cbRxAll->setVisible(b);
if(i==32) ui->cbCQonly->setVisible(b);
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if(i==33) ui->sbTR_FST4W->setVisible(b);
if (34 == i) // adjust the stacked widget
{
ui->opt_controls_stack->setCurrentIndex (b ? 1 : 0);
ui->sbF_Low->setVisible(b);
}
if(i==35) ui->sbF_High->setVisible(b);
j=j>>1;
}
ui->pbBestSP->setVisible(m_mode=="FT4");
b=false;
if(m_mode=="FT4" or m_mode=="FT8") {
b=SpecOp::EU_VHF==m_config.special_op_id() or
( SpecOp::RTTY==m_config.special_op_id() and
(m_config.RTTY_Exchange()=="DX" or m_config.RTTY_Exchange()=="#") );
}
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if(m_mode=="MSK144") b=SpecOp::EU_VHF==m_config.special_op_id();
ui->sbSerialNumber->setVisible(b);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_lastCallsign.clear (); // ensures Tx5 is updated for new modes
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b=m_mode.startsWith("FST4");
ui->sbNB->setVisible(b);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
genStdMsgs (m_rpt, true);
}
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void MainWindow::on_actionFST4_triggered()
{
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m_mode="FST4";
m_modeTx="FST4";
ui->actionFST4->setChecked(true);
m_bFast9=false;
m_bFastMode=false;
m_fastGraph->hide();
m_wideGraph->show();
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize(m_FFTSize);
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->rh_decodes_title_label->setText(tr ("Rx Frequency"));
WSPR_config(false);
if(m_config.single_decode()) {
// 012345678901234567890123456789012345
displayWidgets(nWidgets("111111000100111000010000000100000000"));
m_wideGraph->setSingleDecode(true);
} else {
displayWidgets(nWidgets("111011000100111000010000000100000011"));
m_wideGraph->setSingleDecode(false);
ui->sbFtol->setValue(20);
}
setup_status_bar(false);
ui->cbAutoSeq->setChecked(true);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
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m_wideGraph->setPeriod(m_TRperiod,6912);
m_wideGraph->setRxFreq(ui->RxFreqSpinBox->value());
m_wideGraph->setTol(ui->sbFtol->value());
m_wideGraph->setTxFreq(ui->TxFreqSpinBox->value());
m_wideGraph->setFST4_FreqRange(ui->sbF_Low->value(),ui->sbF_High->value());
chk_FST4_freq_range();
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switch_mode (Modes::FST4);
m_wideGraph->setMode(m_mode);
ui->sbTR->values ({15, 30, 60, 120, 300, 900, 1800});
on_sbTR_valueChanged (ui->sbTR->value());
statusChanged();
m_bOK_to_chk=true;
chk_FST4_freq_range();
}
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void MainWindow::on_actionFST4W_triggered()
{
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m_mode="FST4W";
m_modeTx="FST4W";
ui->actionFST4W->setChecked(true);
m_bFast9=false;
m_bFastMode=false;
m_fastGraph->hide();
m_wideGraph->show();
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize(m_FFTSize);
WSPR_config(true);
// 012345678901234567890123456789012345
displayWidgets(nWidgets("000000000000000001010000000000000100"));
setup_status_bar(false);
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ui->band_hopping_group_box->setChecked(false);
ui->band_hopping_group_box->setVisible(false);
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on_sbTR_FST4W_valueChanged (ui->sbTR_FST4W->value ());
ui->WSPRfreqSpinBox->setMinimum(100);
ui->WSPRfreqSpinBox->setMaximum(5000);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
m_wideGraph->setPeriod(m_TRperiod,6912);
m_wideGraph->setTxFreq(ui->WSPRfreqSpinBox->value());
m_wideGraph->setRxFreq(ui->sbFST4W_RxFreq->value());
m_wideGraph->setTol(ui->sbFST4W_FTol->value());
ui->sbFtol->setValue(100);
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switch_mode (Modes::FST4W);
statusChanged();
}
void MainWindow::on_actionFT4_triggered()
{
m_mode="FT4";
m_modeTx="FT4";
m_TRperiod=7.5;
bool bVHF=m_config.enable_VHF_features();
m_bFast9=false;
m_bFastMode=false;
WSPR_config(false);
switch_mode (Modes::FT4);
m_nsps=6912;
m_FFTSize = m_nsps/2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=21;
setup_status_bar (bVHF);
m_toneSpacing=12000.0/576.0;
ui->actionFT4->setChecked(true);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
m_send_RR73=true;
VHF_features_enabled(bVHF);
m_fastGraph->hide();
m_wideGraph->show();
ui->rh_decodes_headings_label->setText(" UTC dB DT Freq " + tr ("Message"));
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
ui->rh_decodes_title_label->setText(tr ("Rx Frequency"));
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->lh_decodes_headings_label->setText( " UTC dB DT Freq " + tr ("Message"));
displayWidgets(nWidgets("111010000100111000010000000110001000"));
ui->txrb2->setEnabled(true);
ui->txrb4->setEnabled(true);
ui->txrb5->setEnabled(true);
ui->txrb6->setEnabled(true);
ui->txb2->setEnabled(true);
ui->txb4->setEnabled(true);
ui->txb5->setEnabled(true);
ui->txb6->setEnabled(true);
ui->txFirstCheckBox->setEnabled(true);
chkFT4();
statusChanged();
}
void MainWindow::on_actionFT8_triggered()
{
m_mode="FT8";
bool bVHF=m_config.enable_VHF_features();
m_bFast9=false;
m_bFastMode=false;
WSPR_config(false);
switch_mode (Modes::FT8);
m_modeTx="FT8";
m_nsps=6912;
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=50;
setup_status_bar (bVHF);
m_toneSpacing=0.0; //???
ui->actionFT8->setChecked(true); //???
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
VHF_features_enabled(bVHF);
ui->cbAutoSeq->setChecked(true);
m_TRperiod=15.0;
m_fastGraph->hide();
m_wideGraph->show();
ui->rh_decodes_headings_label->setText(" UTC dB DT Freq " + tr ("Message"));
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
ui->rh_decodes_title_label->setText(tr ("Rx Frequency"));
if(SpecOp::FOX==m_config.special_op_id()) {
ui->lh_decodes_title_label->setText(tr ("Stations calling DXpedition %1").arg (m_config.my_callsign()));
ui->lh_decodes_headings_label->setText( "Call Grid dB Freq Dist Age Continent");
} else {
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->lh_decodes_headings_label->setText( " UTC dB DT Freq " + tr ("Message"));
}
displayWidgets(nWidgets("111010000100111000010000100110001000"));
ui->txrb2->setEnabled(true);
ui->txrb4->setEnabled(true);
ui->txrb5->setEnabled(true);
ui->txrb6->setEnabled(true);
ui->txb2->setEnabled(true);
ui->txb4->setEnabled(true);
ui->txb5->setEnabled(true);
ui->txb6->setEnabled(true);
ui->txFirstCheckBox->setEnabled(true);
ui->cbAutoSeq->setEnabled(true);
if(SpecOp::FOX==m_config.special_op_id()) {
ui->txFirstCheckBox->setChecked(true);
ui->txFirstCheckBox->setEnabled(false);
ui->cbHoldTxFreq->setChecked(true);
ui->cbAutoSeq->setEnabled(false);
ui->tabWidget->setCurrentIndex(1);
ui->TxFreqSpinBox->setValue(300);
displayWidgets(nWidgets("111010000100111000010000000000100000"));
2020-05-19 06:26:24 -04:00
ui->labDXped->setText(tr ("Fox"));
on_fox_log_action_triggered();
}
if(SpecOp::HOUND == m_config.special_op_id()) {
ui->txFirstCheckBox->setChecked(false);
ui->txFirstCheckBox->setEnabled(false);
ui->cbAutoSeq->setEnabled(false);
ui->tabWidget->setCurrentIndex(0);
ui->cbHoldTxFreq->setChecked(true);
displayWidgets(nWidgets("111010000100110000010000000000110000"));
2020-05-19 06:26:24 -04:00
ui->labDXped->setText(tr ("Hound"));
ui->txrb1->setChecked(true);
ui->txrb2->setEnabled(false);
ui->txrb4->setEnabled(false);
ui->txrb5->setEnabled(false);
ui->txrb6->setEnabled(false);
ui->txb2->setEnabled(false);
ui->txb4->setEnabled(false);
ui->txb5->setEnabled(false);
ui->txb6->setEnabled(false);
}
if (SpecOp::NONE < m_config.special_op_id () && SpecOp::FOX > m_config.special_op_id ()) {
QString t0="";
if(SpecOp::NA_VHF==m_config.special_op_id()) t0+="NA VHF";
if(SpecOp::EU_VHF==m_config.special_op_id()) t0+="EU VHF";
if(SpecOp::FIELD_DAY==m_config.special_op_id()) t0+="Field Day";
if(SpecOp::RTTY==m_config.special_op_id()) t0+="RTTY";
if(SpecOp::WW_DIGI==m_config.special_op_id()) t0+="WW_DIGI";
if(t0=="") {
ui->labDXped->setVisible(false);
} else {
ui->labDXped->setVisible(true);
ui->labDXped->setText(t0);
}
on_contest_log_action_triggered();
}
if((SpecOp::FOX==m_config.special_op_id() or SpecOp::HOUND==m_config.special_op_id()) and !m_config.split_mode() and !m_bWarnedSplit) {
QString errorMsg;
MessageBox::critical_message (this,
"Operation in FT8 DXpedition mode normally requires\n"
" *Split* rig control (either *Rig* or *Fake It* on\n"
"the *Settings | Radio* tab.)", errorMsg);
m_bWarnedSplit=true;
}
statusChanged();
}
void MainWindow::on_actionJT4_triggered()
{
m_mode="JT4";
bool bVHF=m_config.enable_VHF_features();
WSPR_config(false);
switch_mode (Modes::JT4);
m_modeTx="JT4";
m_TRperiod=60.0;
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=176;
if(m_config.decode_at_52s()) m_hsymStop=184;
m_toneSpacing=0.0;
ui->actionJT4->setChecked(true);
VHF_features_enabled(true);
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
m_bFastMode=false;
m_bFast9=false;
setup_status_bar (bVHF);
ui->sbSubmode->setMaximum(6);
ui->lh_decodes_title_label->setText(tr ("Single-Period Decodes"));
ui->rh_decodes_title_label->setText(tr ("Average Decodes"));
ui->lh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
ui->rh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
if(bVHF) {
ui->sbSubmode->setValue(m_nSubMode);
} else {
ui->sbSubmode->setValue(0);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if(bVHF) {
displayWidgets(nWidgets("111110010010110110111100000000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
} else {
displayWidgets(nWidgets("111010000000110000110000000000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
fast_config(false);
statusChanged();
}
void MainWindow::on_actionJT9_triggered()
{
m_mode="JT9";
bool bVHF=m_config.enable_VHF_features();
m_bFast9=ui->cbFast9->isChecked();
m_bFastMode=m_bFast9;
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
WSPR_config(false);
switch_mode (Modes::JT9);
m_modeTx="JT9";
m_nsps=6912;
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=173;
if(m_config.decode_at_52s()) m_hsymStop=179;
setup_status_bar (bVHF);
m_toneSpacing=0.0;
ui->actionJT9->setChecked(true);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
VHF_features_enabled(bVHF);
if(m_nSubMode>=4 and bVHF) {
ui->cbFast9->setEnabled(true);
} else {
ui->cbFast9->setEnabled(false);
ui->cbFast9->setChecked(false);
}
ui->sbSubmode->setMaximum(7);
if(m_bFast9) {
ui->sbTR->values ({5, 10, 15, 30});
on_sbTR_valueChanged (ui->sbTR->value());
m_wideGraph->hide();
m_fastGraph->showNormal();
ui->TxFreqSpinBox->setValue(700);
ui->RxFreqSpinBox->setValue(700);
ui->lh_decodes_headings_label->setText(" UTC dB T Freq " + tr ("Message"));
ui->rh_decodes_headings_label->setText(" UTC dB T Freq " + tr ("Message"));
} else {
ui->cbAutoSeq->setChecked(false);
2020-07-23 13:51:05 -04:00
if (m_mode != "FST4")
{
m_TRperiod=60.0;
ui->lh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
ui->rh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
}
}
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->rh_decodes_title_label->setText(tr ("Rx Frequency"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if(bVHF) {
displayWidgets(nWidgets("111110101000111110010000000000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
} else {
displayWidgets(nWidgets("111010000000111000010000000000001000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
fast_config(m_bFastMode);
ui->cbAutoSeq->setVisible(m_bFast9);
statusChanged();
}
void MainWindow::on_actionJT9_JT65_triggered()
{
m_mode="JT9+JT65";
WSPR_config(false);
switch_mode (Modes::JT65);
if(m_modeTx != "JT65") {
ui->pbTxMode->setText("Tx JT9 @");
m_modeTx="JT9";
}
m_nSubMode=0; //Dual-mode always means JT9 and JT65A
m_TRperiod=60.0;
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_nsps=6912;
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=174;
if(m_config.decode_at_52s()) m_hsymStop=183;
m_toneSpacing=0.0;
setup_status_bar (false);
ui->actionJT9_JT65->setChecked(true);
VHF_features_enabled(false);
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
m_bFastMode=false;
m_bFast9=false;
ui->sbSubmode->setValue(0);
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->rh_decodes_title_label->setText(tr ("Rx Frequency"));
ui->lh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
ui->rh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
displayWidgets(nWidgets("111010000001111000010000000000001000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
fast_config(false);
statusChanged();
}
void MainWindow::on_actionJT65_triggered()
{
2020-07-23 13:51:05 -04:00
if(m_mode=="JT4" or m_mode=="WSPR" or m_mode=="FST4W") {
// If coming from JT4, WSPR, or FST4W mode, pretend temporarily that we're coming
// from JT9 and click the pbTxMode button
m_modeTx="JT9";
on_pbTxMode_clicked();
}
on_actionJT9_triggered();
m_mode="JT65";
m_modeTx="JT65";
bool bVHF=m_config.enable_VHF_features();
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
WSPR_config(false);
switch_mode (Modes::JT65);
if(m_modeTx!="JT65") on_pbTxMode_clicked();
m_TRperiod=60.0;
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=174;
if(m_config.decode_at_52s()) m_hsymStop=183;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_toneSpacing=0.0;
ui->actionJT65->setChecked(true);
VHF_features_enabled(bVHF);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
m_wideGraph->setRxFreq(ui->RxFreqSpinBox->value());
m_wideGraph->setTol(ui->sbFtol->value());
m_wideGraph->setTxFreq(ui->TxFreqSpinBox->value());
setup_status_bar (bVHF);
m_bFastMode=false;
m_bFast9=false;
ui->sbSubmode->setMaximum(2);
if(bVHF) {
ui->sbSubmode->setValue(m_nSubMode);
ui->lh_decodes_title_label->setText(tr ("Single-Period Decodes"));
ui->rh_decodes_title_label->setText(tr ("Average Decodes"));
} else {
ui->sbSubmode->setValue(0);
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->rh_decodes_title_label->setText(tr ("Rx Frequency"));
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
if(bVHF) {
displayWidgets(nWidgets("111110010000110110101100010000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
} else {
displayWidgets(nWidgets("111010000000111000010000000000001000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
}
fast_config(false);
if(ui->cbShMsgs->isChecked()) {
ui->cbAutoSeq->setChecked(false);
ui->cbAutoSeq->setVisible(false);
}
statusChanged();
}
void MainWindow::on_actionQRA64_triggered()
{
int n=m_nSubMode;
on_actionJT65_triggered();
m_nSubMode=n;
m_mode="QRA64";
m_modeTx="QRA64";
ui->actionQRA64->setChecked(true);
switch_mode (Modes::QRA64);
setup_status_bar (true);
m_hsymStop=180;
if(m_config.decode_at_52s()) m_hsymStop=188;
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
ui->sbSubmode->setMaximum(4);
ui->sbSubmode->setValue(m_nSubMode);
ui->actionInclude_averaging->setVisible (false);
ui->actionInclude_correlation->setVisible (false);
ui->RxFreqSpinBox->setValue(1000);
ui->TxFreqSpinBox->setValue(1000);
QString fname {QDir::toNativeSeparators(m_config.temp_dir ().absoluteFilePath ("red.dat"))};
m_wideGraph->setRedFile(fname);
displayWidgets(nWidgets("111110010010110110000000001000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
statusChanged();
}
void MainWindow::on_actionISCAT_triggered()
{
m_mode="ISCAT";
m_modeTx="ISCAT";
ui->actionISCAT->setChecked(true);
ui->sbTR->values ({5, 10, 15, 30});
on_sbTR_valueChanged (ui->sbTR->value ());
m_modulator->setTRPeriod(m_TRperiod);
m_detector->setTRPeriod(m_TRperiod);
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=103;
m_toneSpacing=11025.0/256.0;
WSPR_config(false);
ui->rh_decodes_widget->setVisible (false);
switch_mode(Modes::ISCAT);
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
statusChanged();
if(!m_fastGraph->isVisible()) m_fastGraph->showNormal();
if(m_wideGraph->isVisible()) m_wideGraph->hide();
setup_status_bar (true);
ui->cbShMsgs->setChecked(false);
ui->lh_decodes_headings_label->setText(
" UTC Sync dB DT DF F1 M N C T ");
ui->tabWidget->setCurrentIndex(0);
ui->sbSubmode->setMaximum(1);
if(m_nSubMode==0) ui->TxFreqSpinBox->setValue(1012);
if(m_nSubMode==1) ui->TxFreqSpinBox->setValue(560);
displayWidgets(nWidgets("100111000000000110000000000000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
fast_config(true);
statusChanged ();
}
void MainWindow::on_actionMSK144_triggered()
{
if(SpecOp::EU_VHF < m_config.special_op_id()) {
// We are rejecting the requested mode change, so re-check the old mode
if("FT8"==m_mode) ui->actionFT8->setChecked(true);
if("JT4"==m_mode) ui->actionJT4->setChecked(true);
if("JT9"==m_mode) ui->actionJT9->setChecked(true);
if("JT65"==m_mode) ui->actionJT65->setChecked(true);
if("JT9_JT65"==m_mode) ui->actionJT9_JT65->setChecked(true);
if("ISCAT"==m_mode) ui->actionISCAT->setChecked(true);
if("QRA64"==m_mode) ui->actionQRA64->setChecked(true);
if("WSPR"==m_mode) ui->actionWSPR->setChecked(true);
if("Echo"==m_mode) ui->actionEcho->setChecked(true);
if("FreqCal"==m_mode) ui->actionFreqCal->setChecked(true);
2020-07-23 13:51:05 -04:00
if("FST4"==m_mode) ui->actionFST4->setChecked(true);
if("FST4W"==m_mode) ui->actionFST4W->setChecked(true);
// Make sure that MSK144 is not checked.
ui->actionMSK144->setChecked(false);
MessageBox::warning_message (this, tr ("Improper mode"),
"MSK144 not available if Fox, Hound, Field Day, RTTY, or WW Digi contest is selected.");
return;
}
m_mode="MSK144";
m_modeTx="MSK144";
ui->actionMSK144->setChecked(true);
switch_mode (Modes::MSK144);
m_nsps=6;
m_FFTSize = 7 * 512;
Q_EMIT FFTSize (m_FFTSize);
setup_status_bar (true);
m_toneSpacing=0.0;
WSPR_config(false);
VHF_features_enabled(true);
m_bFastMode=true;
m_bFast9=false;
ui->sbTR->values ({5, 10, 15, 30});
on_sbTR_valueChanged (ui->sbTR->value());
m_wideGraph->hide();
m_fastGraph->showNormal();
ui->TxFreqSpinBox->setValue(1500);
ui->RxFreqSpinBox->setValue(1500);
ui->RxFreqSpinBox->setMinimum(1400);
ui->RxFreqSpinBox->setMaximum(1600);
ui->RxFreqSpinBox->setSingleStep(10);
ui->lh_decodes_headings_label->setText(" UTC dB T Freq " + tr ("Message"));
ui->rh_decodes_headings_label->setText(" UTC dB T Freq " + tr ("Message"));
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_fastGraph->setTRPeriod(m_TRperiod);
ui->lh_decodes_title_label->setText(tr ("Band Activity"));
ui->rh_decodes_title_label->setText(tr ("Tx Messages"));
ui->actionMSK144->setChecked(true);
ui->rptSpinBox->setMinimum(-8);
ui->rptSpinBox->setMaximum(24);
ui->rptSpinBox->setValue(0);
ui->rptSpinBox->setSingleStep(1);
ui->sbFtol->values ({20, 50, 100, 200});
displayWidgets(nWidgets("101111110100000000010001000010000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
fast_config(m_bFastMode);
statusChanged();
QString t0="";
if(SpecOp::NA_VHF==m_config.special_op_id()) t0+="NA VHF";
if(SpecOp::EU_VHF==m_config.special_op_id()) t0+="EU VHF";
if(t0=="") {
ui->labDXped->setVisible(false);
} else {
ui->labDXped->setVisible(true);
ui->labDXped->setText(t0);
}
}
void MainWindow::on_actionWSPR_triggered()
{
m_mode="WSPR";
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
WSPR_config(true);
switch_mode (Modes::WSPR);
m_modeTx="WSPR";
m_TRperiod=120.0;
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=396;
m_toneSpacing=12000.0/8192.0;
setup_status_bar (false);
ui->actionWSPR->setChecked(true);
VHF_features_enabled(false);
ui->WSPRfreqSpinBox->setMinimum(1400);
ui->WSPRfreqSpinBox->setMaximum(1600);
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
m_bFastMode=false;
m_bFast9=false;
ui->TxFreqSpinBox->setValue(ui->WSPRfreqSpinBox->value());
displayWidgets(nWidgets("000000000000000001010000000000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
fast_config(false);
statusChanged();
}
void MainWindow::on_actionEcho_triggered()
{
on_actionJT4_triggered();
m_mode="Echo";
ui->actionEcho->setChecked(true);
m_TRperiod=3.0;
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=9;
m_toneSpacing=1.0;
switch_mode(Modes::Echo);
m_modeTx="Echo";
setup_status_bar (true);
m_wideGraph->setMode(m_mode);
m_wideGraph->setModeTx(m_modeTx);
ui->TxFreqSpinBox->setValue(1500);
ui->TxFreqSpinBox->setEnabled (false);
if(!m_echoGraph->isVisible()) m_echoGraph->show();
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (!ui->actionAstronomical_data->isChecked ()) {
ui->actionAstronomical_data->setChecked (true);
}
m_bFastMode=false;
m_bFast9=false;
WSPR_config(true);
ui->lh_decodes_headings_label->setText(" UTC N Level Sig DF Width Q");
displayWidgets(nWidgets("000000000000000000000010000000000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
fast_config(false);
statusChanged();
}
void MainWindow::on_actionFreqCal_triggered()
{
on_actionJT9_triggered();
m_mode="FreqCal";
ui->actionFreqCal->setChecked(true);
switch_mode(Modes::FreqCal);
m_wideGraph->setMode(m_mode);
ui->sbTR->values ({5, 10, 15, 30});
on_sbTR_valueChanged (ui->sbTR->value());
m_modulator->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_detector->setTRPeriod(m_TRperiod); // TODO - not thread safe
m_nsps=6912; //For symspec only
m_FFTSize = m_nsps / 2;
Q_EMIT FFTSize (m_FFTSize);
m_hsymStop=((int(m_TRperiod/0.288))/8)*8;
m_frequency_list_fcal_iter = m_config.frequencies ()->begin ();
ui->RxFreqSpinBox->setValue(1500);
setup_status_bar (true);
// 18:15:47 0 1 1500 1550.349 0.100 3.5 10.2
ui->lh_decodes_headings_label->setText(" UTC Freq CAL Offset fMeas DF Level S/N");
ui->measure_check_box->setChecked (false);
displayWidgets(nWidgets("001101000000000000000000000001000000"));
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
statusChanged();
}
void MainWindow::switch_mode (Mode mode)
{
m_fastGraph->setMode(m_mode);
m_config.frequencies ()->filter (m_config.region (), mode);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
auto const& row = m_config.frequencies ()->best_working_frequency (m_freqNominal);
ui->bandComboBox->setCurrentIndex (row);
if (row >= 0) {
on_bandComboBox_activated (row);
}
ui->rptSpinBox->setSingleStep(1);
ui->rptSpinBox->setMinimum(-50);
ui->rptSpinBox->setMaximum(49);
ui->sbFtol->values ({1, 2, 5, 10, 20, 50, 100, 200, 300, 400, 500, 1000});
ui->sbFST4W_FTol->values({1, 2, 5, 10, 20, 50, 100});
if(m_mode=="MSK144") {
ui->RxFreqSpinBox->setMinimum(1400);
ui->RxFreqSpinBox->setMaximum(1600);
ui->RxFreqSpinBox->setSingleStep(25);
} else {
ui->RxFreqSpinBox->setMinimum(200);
ui->RxFreqSpinBox->setMaximum(5000);
ui->RxFreqSpinBox->setSingleStep(1);
}
bool b=m_mode=="FreqCal";
ui->tabWidget->setVisible(!b);
if(b) {
ui->DX_controls_widget->setVisible(false);
ui->rh_decodes_widget->setVisible (false);
ui->lh_decodes_title_label->setVisible(false);
}
}
void MainWindow::WSPR_config(bool b)
{
ui->rh_decodes_widget->setVisible(!b);
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
ui->controls_stack_widget->setCurrentIndex (b && m_mode != "Echo" ? 1 : 0);
ui->QSO_controls_widget->setVisible (!b);
ui->DX_controls_widget->setVisible (!b);
ui->WSPR_controls_widget->setVisible (b);
ui->lh_decodes_title_label->setVisible(!b and ui->cbMenus->isChecked());
ui->logQSOButton->setVisible(!b);
ui->DecodeButton->setEnabled(!b);
bool bFST4W=(m_mode=="FST4W");
ui->sbTxPercent->setEnabled(!bFST4W or (tr("Random") == ui->RoundRobin->currentText()));
ui->band_hopping_group_box->setVisible(true);
ui->RoundRobin->setVisible(bFST4W);
ui->sbFST4W_RxFreq->setVisible(bFST4W);
ui->sbFST4W_FTol->setVisible(bFST4W);
2020-07-03 14:17:13 -04:00
ui->RoundRobin->lineEdit()->setAlignment(Qt::AlignCenter);
2020-07-23 13:51:05 -04:00
if(b and m_mode!="Echo" and m_mode!="FST4W") {
QString t="UTC dB DT Freq Drift Call Grid dBm ";
if(m_config.miles()) t += " mi";
if(!m_config.miles()) t += " km";
ui->lh_decodes_headings_label->setText(t);
if (m_config.is_transceiver_online ()) {
2020-09-08 07:54:19 -04:00
m_config.transceiver_tx_frequency (0); // turn off split
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
m_bSimplex = true;
} else
{
m_bSimplex = false;
}
enable_DXCC_entity (m_config.DXCC ()); // sets text window proportions and (re)inits the logbook
}
void MainWindow::fast_config(bool b)
{
m_bFastMode=b;
ui->TxFreqSpinBox->setEnabled(!b);
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
ui->sbTR->setVisible(b);
if(b and (m_bFast9 or m_mode=="MSK144" or m_mode=="ISCAT")) {
m_wideGraph->hide();
m_fastGraph->showNormal();
} else {
m_wideGraph->showNormal();
m_fastGraph->hide();
}
}
void MainWindow::on_TxFreqSpinBox_valueChanged(int n)
{
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_wideGraph->setTxFreq(n);
// if (ui->cbHoldTxFreq->isChecked ()) ui->RxFreqSpinBox->setValue(n);
if(m_mode!="MSK144") {
Q_EMIT transmitFrequency (n - m_XIT);
}
statusUpdate ();
}
void MainWindow::on_RxFreqSpinBox_valueChanged(int n)
{
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
m_wideGraph->setRxFreq(n);
if (m_mode == "FreqCal") {
setRig ();
}
statusUpdate ();
}
void MainWindow::on_sbF_Low_valueChanged(int n)
{
m_wideGraph->setFST4_FreqRange(n,ui->sbF_High->value());
chk_FST4_freq_range();
}
void MainWindow::on_sbF_High_valueChanged(int n)
{
m_wideGraph->setFST4_FreqRange(ui->sbF_Low->value(),n);
chk_FST4_freq_range();
}
void MainWindow::chk_FST4_freq_range()
{
if(!m_bOK_to_chk) return;
if(ui->sbF_Low->value() < m_wideGraph->nStartFreq()) ui->sbF_Low->setValue(m_wideGraph->nStartFreq());
if(ui->sbF_High->value() > m_wideGraph->Fmax()) {
int n=m_wideGraph->Fmax()/100;
ui->sbF_High->setValue(100*n);
}
int maxDiff=2000;
if(m_TRperiod==120) maxDiff=1000;
if(m_TRperiod==300) maxDiff=400;
if(m_TRperiod>=900) maxDiff=200;
int diff=ui->sbF_High->value() - ui->sbF_Low->value();
if(diff<100 or diff>maxDiff) {
ui->sbF_Low->setStyleSheet("QSpinBox { color: white; background-color: red; }");
ui->sbF_High->setStyleSheet("QSpinBox { color: white; background-color: red; }");
} else {
ui->sbF_Low->setStyleSheet("");
ui->sbF_High->setStyleSheet("");
}
}
void MainWindow::on_actionQuickDecode_toggled (bool checked)
{
m_ndepth ^= (-checked ^ m_ndepth) & 0x00000001;
}
void MainWindow::on_actionMediumDecode_toggled (bool checked)
{
m_ndepth ^= (-checked ^ m_ndepth) & 0x00000002;
}
void MainWindow::on_actionDeepestDecode_toggled (bool checked)
{
m_ndepth ^= (-checked ^ m_ndepth) & 0x00000003;
}
void MainWindow::on_actionInclude_averaging_toggled (bool checked)
{
m_ndepth ^= (-checked ^ m_ndepth) & 0x00000010;
}
void MainWindow::on_actionInclude_correlation_toggled (bool checked)
{
m_ndepth ^= (-checked ^ m_ndepth) & 0x00000020;
}
void MainWindow::on_actionEnable_AP_DXcall_toggled (bool checked)
{
m_ndepth ^= (-checked ^ m_ndepth) & 0x00000040;
}
void MainWindow::on_actionErase_ALL_TXT_triggered() //Erase ALL.TXT
{
int ret = MessageBox::query_message (this, tr ("Confirm Erase"),
tr ("Are you sure you want to erase file ALL.TXT?"));
if(ret==MessageBox::Yes) {
QFile f {m_config.writeable_data_dir ().absoluteFilePath ("ALL.TXT")};
f.remove();
m_RxLog=1;
}
}
void MainWindow::on_reset_cabrillo_log_action_triggered ()
2018-08-01 15:52:35 -04:00
{
if (MessageBox::Yes == MessageBox::query_message (this, tr ("Confirm Reset"),
tr ("Are you sure you want to erase your contest log?"),
tr ("Doing this will remove all QSO records for the current contest. "
"They will be kept in the ADIF log file but will not be available "
"for export in your Cabrillo log.")))
{
if(m_config.RTTY_Exchange()!="SCC") ui->sbSerialNumber->setValue(1);
m_logBook.contest_log ()->reset ();
}
}
void MainWindow::on_actionExport_Cabrillo_log_triggered()
{
if (QDialog::Accepted == ExportCabrillo {m_settings, &m_config, m_logBook.contest_log ()}.exec())
{
MessageBox::information_message (this, tr ("Cabrillo Log saved"));
}
}
void MainWindow::on_actionErase_wsjtx_log_adi_triggered()
{
int ret = MessageBox::query_message (this, tr ("Confirm Erase"),
tr ("Are you sure you want to erase file wsjtx_log.adi?"));
if(ret==MessageBox::Yes) {
QFile f {m_config.writeable_data_dir ().absoluteFilePath ("wsjtx_log.adi")};
f.remove();
}
}
void MainWindow::on_actionErase_WSPR_hashtable_triggered()
{
int ret = MessageBox::query_message(this, tr ("Confirm Erase"),
tr ("Are you sure you want to erase the WSPR hashtable?"));
if(ret==MessageBox::Yes) {
QFile f {m_config.writeable_data_dir().absoluteFilePath("hashtable.txt")};
f.remove();
}
}
void MainWindow::on_actionOpen_log_directory_triggered ()
{
QDesktopServices::openUrl (QUrl::fromLocalFile (m_config.writeable_data_dir ().absolutePath ()));
}
void MainWindow::on_bandComboBox_currentIndexChanged (int index)
{
auto const& frequencies = m_config.frequencies ();
auto const& source_index = frequencies->mapToSource (frequencies->index (index, FrequencyList_v2::frequency_column));
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
Frequency frequency {m_freqNominal};
if (source_index.isValid ())
{
frequency = frequencies->frequency_list ()[source_index.row ()].frequency_;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// Lookup band
auto const& band = m_config.bands ()->find (frequency);
ui->bandComboBox->setCurrentText (band.size () ? band : m_config.bands ()->oob ());
displayDialFrequency ();
}
void MainWindow::on_bandComboBox_editTextChanged (QString const& text)
{
if (text.size () && m_config.bands ()->oob () != text)
{
ui->bandComboBox->lineEdit ()->setStyleSheet ({});
}
else
{
ui->bandComboBox->lineEdit ()->setStyleSheet ("QLineEdit {color: yellow; background-color : red;}");
}
}
void MainWindow::on_bandComboBox_activated (int index)
{
auto const& frequencies = m_config.frequencies ();
auto const& source_index = frequencies->mapToSource (frequencies->index (index, FrequencyList_v2::frequency_column));
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
Frequency frequency {m_freqNominal};
if (source_index.isValid ())
{
frequency = frequencies->frequency_list ()[source_index.row ()].frequency_;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_bandEdited = true;
band_changed (frequency);
m_wideGraph->setRxBand (m_config.bands ()->find (frequency));
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::band_changed (Frequency f)
{
// Set the attenuation value if options are checked
QString curBand = ui->bandComboBox->currentText();
if (m_config.pwrBandTxMemory() && !m_tune) {
if (m_pwrBandTxMemory.contains(curBand)) {
ui->outAttenuation->setValue(m_pwrBandTxMemory[curBand].toInt());
}
else {
m_pwrBandTxMemory[curBand] = ui->outAttenuation->value();
}
}
if (m_bandEdited) {
if (m_mode!="WSPR") { // band hopping preserves auto Tx
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (f + m_wideGraph->nStartFreq () > m_freqNominal + ui->TxFreqSpinBox->value ()
|| f + m_wideGraph->nStartFreq () + m_wideGraph->fSpan () <=
m_freqNominal + ui->TxFreqSpinBox->value ()) {
// qDebug () << "start f:" << m_wideGraph->nStartFreq () << "span:" << m_wideGraph->fSpan () << "DF:" << ui->TxFreqSpinBox->value ();
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
// disable auto Tx if "blind" QSY outside of waterfall
ui->stopTxButton->click (); // halt any transmission
auto_tx_mode (false); // disable auto Tx
// m_send_RR73 = false; // force user to reassess on new band
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_lastBand.clear ();
m_bandEdited = false;
if (m_config.spot_to_psk_reporter ())
{
// Upload any queued spots before changing band
m_psk_Reporter.sendReport();
}
if (!m_transmitting) monitor (true);
if ("FreqCal" == m_mode)
{
m_frequency_list_fcal_iter = m_config.frequencies ()->find (f);
}
setRig (f);
setXIT (ui->TxFreqSpinBox->value ());
}
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::enable_DXCC_entity (bool on)
{
2020-07-23 13:51:05 -04:00
if (on and m_mode!="WSPR" and m_mode!="FST4W" and m_mode!="Echo") {
//m_logBook.init(); // re-read the log and cty.dat files
// ui->gridLayout->setColumnStretch(0,55); // adjust proportions of text displays
// ui->gridLayout->setColumnStretch(1,45);
} else {
// ui->gridLayout->setColumnStretch(0,0);
// ui->gridLayout->setColumnStretch(1,0);
}
updateGeometry ();
}
void MainWindow::on_rptSpinBox_valueChanged(int n)
{
int step=ui->rptSpinBox->singleStep();
if(n%step !=0) {
n++;
ui->rptSpinBox->setValue(n);
}
m_rpt=QString::number(n);
int ntx0=m_ntx;
genStdMsgs(m_rpt);
m_ntx=ntx0;
if(m_ntx==1) ui->txrb1->setChecked(true);
if(m_ntx==2) ui->txrb2->setChecked(true);
if(m_ntx==3) ui->txrb3->setChecked(true);
if(m_ntx==4) ui->txrb4->setChecked(true);
if(m_ntx==5) ui->txrb5->setChecked(true);
if(m_ntx==6) ui->txrb6->setChecked(true);
statusChanged();
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::on_tuneButton_clicked (bool checked)
{
static bool lastChecked = false;
if (lastChecked == checked) return;
lastChecked = checked;
QString curBand = ui->bandComboBox->currentText();
if (checked && m_tune==false) { // we're starting tuning so remember Tx and change pwr to Tune value
if (m_config.pwrBandTuneMemory ()) {
m_pwrBandTxMemory[curBand] = ui->outAttenuation->value(); // remember our Tx pwr
m_PwrBandSetOK = false;
if (m_pwrBandTuneMemory.contains(curBand)) {
ui->outAttenuation->setValue(m_pwrBandTuneMemory[curBand].toInt()); // set to Tune pwr
}
m_PwrBandSetOK = true;
}
}
else { // we're turning off so remember our Tune pwr setting and reset to Tx pwr
if (m_config.pwrBandTuneMemory() || m_config.pwrBandTxMemory()) {
stopTx();
m_pwrBandTuneMemory[curBand] = ui->outAttenuation->value(); // remember our Tune pwr
m_PwrBandSetOK = false;
ui->outAttenuation->setValue(m_pwrBandTxMemory[curBand].toInt()); // set to Tx pwr
m_PwrBandSetOK = true;
}
}
if (m_tune) {
tuneButtonTimer.start(250);
} else {
m_sentFirst73=false;
itone[0]=0;
on_monitorButton_clicked (true);
m_tune=true;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
Q_EMIT tune (checked);
}
void MainWindow::stop_tuning ()
{
on_tuneButton_clicked(false);
ui->tuneButton->setChecked (false);
m_bTxTime=false;
m_tune=false;
}
void MainWindow::stopTuneATU()
{
on_tuneButton_clicked(false);
m_bTxTime=false;
}
void MainWindow::on_stopTxButton_clicked() //Stop Tx
{
if (m_tune) stop_tuning ();
if (m_auto and !m_tuneup) auto_tx_mode (false);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
m_btxok=false;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_bCallingCQ = false;
m_bAutoReply = false; // ready for next
ui->cbFirst->setStyleSheet ("");
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::rigOpen ()
{
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
update_dynamic_property (ui->readFreq, "state", "warning");
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
ui->readFreq->setText ("");
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
ui->readFreq->setEnabled (true);
m_config.transceiver_online ();
2020-09-08 07:54:19 -04:00
m_config.sync_transceiver (true, true);
}
void MainWindow::on_pbR2T_clicked()
{
ui->TxFreqSpinBox->setValue(ui->RxFreqSpinBox->value ());
}
void MainWindow::on_pbT2R_clicked()
{
if (ui->RxFreqSpinBox->isEnabled ())
{
ui->RxFreqSpinBox->setValue (ui->TxFreqSpinBox->value ());
}
}
void MainWindow::on_readFreq_clicked()
{
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
if (m_transmitting) return;
if (m_config.transceiver_online ())
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
2020-09-08 07:54:19 -04:00
m_config.sync_transceiver (true, true);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
}
void MainWindow::on_pbTxMode_clicked()
{
if(m_mode=="JT9+JT65") {
if(m_modeTx=="JT9") {
m_modeTx="JT65";
ui->pbTxMode->setText("Tx JT65 #");
} else {
m_modeTx="JT9";
ui->pbTxMode->setText("Tx JT9 @");
}
m_wideGraph->setModeTx(m_modeTx);
statusChanged();
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
void MainWindow::setXIT(int n, Frequency base)
{
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (m_transmitting && !m_config.tx_QSY_allowed ()) return;
// If "CQ nnn ..." feature is active, set the proper Tx frequency
if(m_config.split_mode () && ui->cbCQTx->isEnabled () && ui->cbCQTx->isVisible () &&
ui->cbCQTx->isChecked())
{
if (6 == m_ntx || (7 == m_ntx && m_gen_message_is_cq))
{
// All conditions are met, use calling frequency
base = m_freqNominal / 1000000 * 1000000 + 1000 * ui->sbCQTxFreq->value () + m_XIT;
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (!base) base = m_freqNominal;
m_XIT = 0;
if (!m_bSimplex) {
// m_bSimplex is false, so we can use split mode if requested
if (m_config.split_mode () && (!m_config.enable_VHF_features () || m_mode == "FT8" ||
m_mode=="FST4")) {
// Don't use XIT for VHF & up
m_XIT=(n/500)*500 - 1500;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if ((m_monitoring || m_transmitting)
&& m_config.is_transceiver_online ()
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
&& m_config.split_mode ())
{
// All conditions are met, reset the transceiver Tx dial
// frequency
m_freqTxNominal = base + m_XIT;
if (m_astroWidget) m_astroWidget->nominal_frequency (m_freqNominal, m_freqTxNominal);
2020-09-08 07:54:19 -04:00
m_config.transceiver_tx_frequency (m_freqTxNominal + m_astroCorrection.tx);
}
}
//Now set the audio Tx freq
Q_EMIT transmitFrequency (ui->TxFreqSpinBox->value () - m_XIT);
}
void MainWindow::setFreq4(int rxFreq, int txFreq)
{
if (ui->RxFreqSpinBox->isEnabled ()) ui->RxFreqSpinBox->setValue(rxFreq);
2020-07-23 13:51:05 -04:00
if(m_mode=="WSPR" or m_mode=="FST4W") {
ui->WSPRfreqSpinBox->setValue(txFreq);
} else {
if (ui->TxFreqSpinBox->isEnabled ()) {
ui->TxFreqSpinBox->setValue(txFreq);
if ("FT8" == m_mode || "FT4" == m_mode || m_mode=="FST4")
{
// we need to regenerate the current transmit waveform for
// GFSK modulated modes
if (m_transmitting) m_restart = true;
}
}
else if (m_config.enable_VHF_features ()
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
&& (Qt::ControlModifier & QApplication::keyboardModifiers ())) {
// for VHF & up we adjust Tx dial frequency to equalize Tx to Rx
// when user CTRL+clicks on waterfall
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
auto temp = ui->TxFreqSpinBox->value ();
ui->RxFreqSpinBox->setValue (temp);
setRig (m_freqNominal + txFreq - temp);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
setXIT (ui->TxFreqSpinBox->value ());
}
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
void MainWindow::handle_transceiver_update (Transceiver::TransceiverState const& s)
{
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
Transceiver::TransceiverState old_state {m_rigState};
//transmitDisplay (s.ptt ());
if (s.ptt () // && !m_rigState.ptt ()
) { // safe to start audio
// (caveat - DX Lab Suite Commander)
if (m_tx_when_ready && g_iptt) { // waiting to Tx and still needed
int ms_delay=1000*m_config.txDelay();
if(m_mode=="FT4") ms_delay=20;
ptt1Timer.start(ms_delay); //Start-of-transmission sequencer delay
m_tx_when_ready = false;
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
m_rigState = s;
auto old_freqNominal = m_freqNominal;
if (!old_freqNominal)
{
// always take initial rig frequency to avoid start up problems
// with bogus Tx frequencies
m_freqNominal = s.frequency ();
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (old_state.online () == false && s.online () == true)
{
// initializing
on_monitorButton_clicked (!m_config.monitor_off_at_startup ());
}
if (s.frequency () != old_state.frequency () || s.split () != m_splitMode)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
m_splitMode = s.split ();
if (!s.ptt ())
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
{
m_freqNominal = s.frequency () - m_astroCorrection.rx;
if (old_freqNominal != m_freqNominal)
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
{
m_freqTxNominal = m_freqNominal;
genCQMsg ();
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
if (m_monitoring)
{
m_lastMonitoredFrequency = m_freqNominal;
}
if (m_lastDialFreq != m_freqNominal &&
(m_mode != "MSK144"
|| !(ui->cbCQTx->isEnabled () && ui->cbCQTx->isVisible () && ui->cbCQTx->isChecked()))) {
m_lastDialFreq = m_freqNominal;
m_secBandChanged=QDateTime::currentMSecsSinceEpoch()/1000;
pskSetLocal ();
statusChanged();
m_wideGraph->setDialFreq(m_freqNominal / 1.e6);
}
} else {
m_freqTxNominal = s.split () ? s.tx_frequency () - m_astroCorrection.tx : s.frequency ();
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (m_astroWidget) m_astroWidget->nominal_frequency (m_freqNominal, m_freqTxNominal);
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
// ensure frequency display is correct
if (m_astroWidget && old_state.ptt () != s.ptt ()) setRig ();
displayDialFrequency ();
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
update_dynamic_property (ui->readFreq, "state", "ok");
ui->readFreq->setEnabled (false);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
ui->readFreq->setText (s.split () ? "S" : "");
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
void MainWindow::handle_transceiver_failure (QString const& reason)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
Make the main window more portable and font change capable The Rx meter is now a better Qt citizen and can be resized. Added a more obvious peak signal indicator. It is now a custom widget derived from QFrame and is now directly added via promotion in Designer. Added a custom widget to act as a letter spin box, this is used for sub mode control. Switched the frequency tolerance widget to a combo box with preset values so that it is more uniform across systems and font sizes. Added container widgets for group control of various UI widgets such as QSO controls, DX call controls and WSPR controls. Introduced a stacked widget to allow the WSPR controls to be swapped in in place of the "QSO" controls. The "QSO" controls are are the Rx, Tx and related controls along with the main tab widget with the message buttons and fields. This means that the WSPR version of the main window (and EME Echo mode) are now much cleaner. Increased the size of the rig control widget and styled its colour using a dynamic property so that it can be defined in the Designer UI definition. Reinstated it as a push button to do a rig control reset and retry after an error. Reset most UI widgets to default properties, particularly removing any fixed sizes so that they can resize freely when fonts are changed. The overall layout is now controlled almost exclusively by stretch factors on some of the rows and columns of the various grid layout managers. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5630 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-06-25 18:41:13 -04:00
update_dynamic_property (ui->readFreq, "state", "error");
ui->readFreq->setEnabled (true);
on_stopTxButton_clicked ();
rigFailure (reason);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
void MainWindow::rigFailure (QString const& reason)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
if (m_first_error)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
{
// one automatic retry
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
QTimer::singleShot (0, this, SLOT (rigOpen ()));
m_first_error = false;
}
else
{
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
m_rigErrorMessageBox.setDetailedText (reason);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// don't call slot functions directly to avoid recursion
m_rigErrorMessageBox.exec ();
auto const clicked_button = m_rigErrorMessageBox.clickedButton ();
if (clicked_button == m_configurations_button)
{
ui->menuConfig->exec (QCursor::pos ());
}
else
{
switch (m_rigErrorMessageBox.standardButton (clicked_button))
{
case MessageBox::Ok:
m_config.select_tab (1);
QTimer::singleShot (0, this, SLOT (on_actionSettings_triggered ()));
break;
case MessageBox::Retry:
QTimer::singleShot (0, this, SLOT (rigOpen ()));
break;
case MessageBox::Cancel:
QTimer::singleShot (0, this, SLOT (close ()));
break;
default: break; // squashing compile warnings
}
}
m_first_error = true; // reset
}
}
void MainWindow::transmit (double snr)
{
double toneSpacing=0.0;
if (m_modeTx == "JT65") {
if(m_nSubMode==0) toneSpacing=11025.0/4096.0;
if(m_nSubMode==1) toneSpacing=2*11025.0/4096.0;
if(m_nSubMode==2) toneSpacing=4*11025.0/4096.0;
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_JT65_SYMBOLS,
4096.0*12000.0/11025.0, ui->TxFreqSpinBox->value () - m_XIT,
toneSpacing, m_soundOutput, m_config.audio_output_channel (),
true, false, snr, m_TRperiod);
}
if (m_modeTx == "FT8") {
// toneSpacing=12000.0/1920.0;
toneSpacing=-3;
if(m_config.x2ToneSpacing()) toneSpacing=2*12000.0/1920.0;
if(m_config.x4ToneSpacing()) toneSpacing=4*12000.0/1920.0;
if(SpecOp::FOX==m_config.special_op_id() and !m_tune) toneSpacing=-1;
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Q_EMIT sendMessage (m_mode, NUM_FT8_SYMBOLS,
1920.0, ui->TxFreqSpinBox->value () - m_XIT,
toneSpacing, m_soundOutput, m_config.audio_output_channel (),
true, false, snr, m_TRperiod);
}
if (m_modeTx == "FT4") {
m_dateTimeSentTx3=QDateTime::currentDateTimeUtc();
toneSpacing=-2.0; //Transmit a pre-computed, filtered waveform.
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_FT4_SYMBOLS,
576.0, ui->TxFreqSpinBox->value() - m_XIT,
toneSpacing, m_soundOutput, m_config.audio_output_channel(),
true, false, snr, m_TRperiod);
}
2020-07-23 13:51:05 -04:00
if (m_modeTx == "FST4" or m_modeTx == "FST4W") {
m_dateTimeSentTx3=QDateTime::currentDateTimeUtc();
toneSpacing=-2.0; //Transmit a pre-computed, filtered waveform.
int nsps=720;
if(m_TRperiod==30) nsps=1680;
if(m_TRperiod==60) nsps=3888;
if(m_TRperiod==120) nsps=8200;
if(m_TRperiod==300) nsps=21504;
if(m_TRperiod==900) nsps=66560;
if(m_TRperiod==1800) nsps=134400;
int hmod=1;
if(m_config.x2ToneSpacing()) hmod=2;
if(m_config.x4ToneSpacing()) hmod=4;
double dfreq=hmod*12000.0/nsps;
double f0=ui->WSPRfreqSpinBox->value() - m_XIT;
if(m_mode=="FST4") f0=ui->TxFreqSpinBox->value() - m_XIT;
if(!m_tune) f0 += 1.5*dfreq;
2020-07-23 13:51:05 -04:00
Q_EMIT sendMessage (m_mode, NUM_FST4_SYMBOLS,double(nsps),f0,toneSpacing,
m_soundOutput,m_config.audio_output_channel(),
true, false, snr, m_TRperiod);
}
if (m_modeTx == "QRA64") {
if(m_nSubMode==0) toneSpacing=12000.0/6912.0;
if(m_nSubMode==1) toneSpacing=2*12000.0/6912.0;
if(m_nSubMode==2) toneSpacing=4*12000.0/6912.0;
if(m_nSubMode==3) toneSpacing=8*12000.0/6912.0;
if(m_nSubMode==4) toneSpacing=16*12000.0/6912.0;
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_QRA64_SYMBOLS,
6912.0, ui->TxFreqSpinBox->value () - m_XIT,
toneSpacing, m_soundOutput, m_config.audio_output_channel (),
true, false, snr, m_TRperiod);
}
if (m_modeTx == "JT9") {
int nsub=pow(2,m_nSubMode);
int nsps[]={480,240,120,60};
double sps=m_nsps;
m_toneSpacing=nsub*12000.0/6912.0;
if(m_config.x2ToneSpacing()) m_toneSpacing=2.0*m_toneSpacing;
if(m_config.x4ToneSpacing()) m_toneSpacing=4.0*m_toneSpacing;
bool fastmode=false;
if(m_bFast9 and (m_nSubMode>=4)) {
fastmode=true;
sps=nsps[m_nSubMode-4];
m_toneSpacing=12000.0/sps;
}
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_JT9_SYMBOLS, sps,
ui->TxFreqSpinBox->value() - m_XIT, m_toneSpacing,
m_soundOutput, m_config.audio_output_channel (),
true, fastmode, snr, m_TRperiod);
}
if (m_modeTx == "MSK144") {
m_nsps=6;
double f0=1000.0;
if(!m_bFastMode) {
m_nsps=192;
f0=ui->TxFreqSpinBox->value () - m_XIT - 0.5*m_toneSpacing;
}
m_toneSpacing=6000.0/m_nsps;
m_FFTSize = 7 * 512;
Q_EMIT FFTSize (m_FFTSize);
int nsym;
nsym=NUM_MSK144_SYMBOLS;
if(itone[40] < 0) nsym=40;
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, nsym, double(m_nsps), f0, m_toneSpacing,
m_soundOutput, m_config.audio_output_channel (),
true, true, snr, m_TRperiod);
}
if (m_modeTx == "JT4") {
if(m_nSubMode==0) toneSpacing=4.375;
if(m_nSubMode==1) toneSpacing=2*4.375;
if(m_nSubMode==2) toneSpacing=4*4.375;
if(m_nSubMode==3) toneSpacing=9*4.375;
if(m_nSubMode==4) toneSpacing=18*4.375;
if(m_nSubMode==5) toneSpacing=36*4.375;
if(m_nSubMode==6) toneSpacing=72*4.375;
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_JT4_SYMBOLS,
2520.0*12000.0/11025.0, ui->TxFreqSpinBox->value () - m_XIT,
toneSpacing, m_soundOutput, m_config.audio_output_channel (),
true, false, snr, m_TRperiod);
}
if (m_mode=="WSPR") {
int nToneSpacing=1;
if(m_config.x2ToneSpacing()) nToneSpacing=2;
if(m_config.x4ToneSpacing()) nToneSpacing=4;
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_WSPR_SYMBOLS, 8192.0,
ui->TxFreqSpinBox->value() - 1.5 * 12000 / 8192,
m_toneSpacing*nToneSpacing, m_soundOutput,
m_config.audio_output_channel(),true, false, snr,
m_TRperiod);
}
2020-06-29 14:47:46 -04:00
if(m_mode=="Echo") {
//??? should use "fastMode = true" here ???
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, 27, 1024.0, 1500.0, 0.0, m_soundOutput,
m_config.audio_output_channel(),
false, false, snr, m_TRperiod);
}
if(m_mode=="ISCAT") {
double sps,f0;
if(m_nSubMode==0) {
sps=512.0*12000.0/11025.0;
toneSpacing=11025.0/512.0;
f0=47*toneSpacing;
} else {
sps=256.0*12000.0/11025.0;
toneSpacing=11025.0/256.0;
f0=13*toneSpacing;
}
2020-06-29 14:47:46 -04:00
Q_EMIT sendMessage (m_mode, NUM_ISCAT_SYMBOLS, sps, f0, toneSpacing, m_soundOutput,
m_config.audio_output_channel(),
true, true, snr, m_TRperiod);
}
// In auto-sequencing mode, stop after 5 transmissions of "73" message.
if (m_bFastMode || m_bFast9) {
if (ui->cbAutoSeq->isVisible () && ui->cbAutoSeq->isChecked ()) {
if(m_ntx==5) {
m_nTx73 += 1;
} else {
m_nTx73=0;
}
}
}
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
}
void MainWindow::on_outAttenuation_valueChanged (int a)
{
QString tt_str;
qreal dBAttn {a / 10.}; // slider interpreted as dB / 100
if (m_tune && m_config.pwrBandTuneMemory()) {
tt_str = tr ("Tune digital gain ");
} else {
tt_str = tr ("Transmit digital gain ");
}
tt_str += (a ? QString::number (-dBAttn, 'f', 1) : "0") + "dB";
if (!m_block_pwr_tooltip) {
QToolTip::showText (QCursor::pos (), tt_str, ui->outAttenuation);
}
QString curBand = ui->bandComboBox->currentText();
if (m_PwrBandSetOK && !m_tune && m_config.pwrBandTxMemory ()) {
m_pwrBandTxMemory[curBand] = a; // remember our Tx pwr
}
if (m_PwrBandSetOK && m_tune && m_config.pwrBandTuneMemory()) {
m_pwrBandTuneMemory[curBand] = a; // remember our Tune pwr
}
Added audio channel support. Audio input can be mono, left of stereo pair or, right of stereo pair. Audio output can be mono, left of stereo pair, right of stereo pair or, both of stereo pair (the same output goes to both channels in both mode). Settings are remembered between sessions. Stream channel suport is implemented mainly in the new AudioDevice class which is now the base class of Modulator and Detector. Audio channels are selected on the configuration screen. Only supported channel configurations per device can be selected. Audio output volume (actually attenuation) is now possible from the GUI. I have added a slider control to the main window; I don't necessarily propose this as a final release location for the widget as I understand that changes to the main screen are sensitive. This location is just a starting suggestion for a trial. The volume (attenuation) setting is remembered between sessions and is not device dependent. This addresses all issues of volume setting on *nix versions since there is no need to use pavucontrol to set audio levels. The volume (attenuation) action is logarithmic. Shaped CW keying has been implemented in Modulator although it is currently disabled as I am not 100% happy wth the implementation. If you want to try it define the C++ preprocessor macro WSJT_SOFT_KEYING in your build. The Modulator instance has been moved to the same thread as the SoundOutput instance as it should have been since the output callback already operates in that thread. Cross thread slots are now correctly called in a thread safe way as a result. A number of files where in the SVN repository with DOS line endings which I have removed. SVN users on Windows need set the config for native line endings so that DOS line endings are automatically stripped on checkin. The DevSetup class now holds it's UI o the heap to reduce imapact on build dependencies. The application settings are now passed to objects from the main.cpp file. Management of settings are moved to the responsible classes (top level windows). This has involved a few settings moving groups so users will see some settings reverting to default values on the first run of an update. Persistance of top level windows geometry and position is now handled in the recommened manner (constructor for load, closeEvent for store in modal windows and, hideEvent for store in modeless dialogs). The MainWindow class now holds its children as members rather than global variables. The LogQSO class now hides its implementation and takes responsibility for its own settings and widows rendering parameters. A new settings file group is implemented to persist the LogQSO class settings. The WideGraph class now hides its implementation and manages its own settings and window rendering parameters. --This line, and those below, will be ignored-- M Modulator.cpp M rigclass.cpp M widegraph.cpp M signalmeter.cpp M soundin.cpp M soundout.cpp M mainwindow.h M main.cpp M meterwidget.h M devsetup.cpp M mainwindow.ui M Detector.cpp M logqso.h M rigclass.h M mainwindow.cpp M meterwidget.cpp M soundin.h M devsetup.ui M wsjtx.pro M devsetup.h M logqso.cpp M Modulator.hpp M psk_reporter.cpp M killbyname.cpp M Detector.hpp M signalmeter.h M widegraph.h M psk_reporter.h M soundout.h M PSKReporter.h M lib/afc65b.f90 M lib/gran.c M lib/usleep.c M lib/afc9.f90 M lib/wrapkarn.c A AudioDevice.hpp git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3542 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2013-08-10 11:29:55 -04:00
Q_EMIT outAttenuationChanged (dBAttn);
}
void MainWindow::on_actionShort_list_of_add_on_prefixes_and_suffixes_triggered()
{
if (!m_prefixes) {
2020-07-29 13:44:34 -04:00
m_prefixes.reset (new HelpTextWindow {tr ("Prefixes")
, R"(Type 1 Prefixes:
1A 1S 3A 3B6 3B8 3B9 3C 3C0 3D2 3D2C 3D2R 3DA 3V 3W 3X
3Y 3YB 3YP 4J 4L 4S 4U1I 4U1U 4W 4X 5A 5B 5H 5N 5R
5T 5U 5V 5W 5X 5Z 6W 6Y 7O 7P 7Q 7X 8P 8Q 8R
9A 9G 9H 9J 9K 9L 9M2 9M6 9N 9Q 9U 9V 9X 9Y A2
A3 A4 A5 A6 A7 A9 AP BS7 BV BV9 BY C2 C3 C5 C6
C9 CE CE0X CE0Y CE0Z CE9 CM CN CP CT CT3 CU CX CY0 CY9
D2 D4 D6 DL DU E3 E4 EA EA6 EA8 EA9 EI EK EL EP
ER ES ET EU EX EY EZ F FG FH FJ FK FKC FM FO
FOA FOC FOM FP FR FRG FRJ FRT FT5W FT5X FT5Z FW FY M MD
MI MJ MM MU MW H4 H40 HA HB HB0 HC HC8 HH HI HK
HK0A HK0M HL HM HP HR HS HV HZ I IS IS0 J2 J3 J5
J6 J7 J8 JA JDM JDO JT JW JX JY K KG4 KH0 KH1 KH2
KH3 KH4 KH5 KH5K KH6 KH7 KH8 KH9 KL KP1 KP2 KP4 KP5 LA LU
LX LY LZ OA OD OE OH OH0 OJ0 OK OM ON OX OY OZ
P2 P4 PA PJ2 PJ7 PY PY0F PT0S PY0T PZ R1F R1M S0 S2 S5
S7 S9 SM SP ST SU SV SVA SV5 SV9 T2 T30 T31 T32 T33
T5 T7 T8 T9 TA TF TG TI TI9 TJ TK TL TN TR TT
TU TY TZ UA UA2 UA9 UK UN UR V2 V3 V4 V5 V6 V7
V8 VE VK VK0H VK0M VK9C VK9L VK9M VK9N VK9W VK9X VP2E VP2M VP2V VP5
VP6 VP6D VP8 VP8G VP8H VP8O VP8S VP9 VQ9 VR VU VU4 VU7 XE XF4
XT XU XW XX9 XZ YA YB YI YJ YK YL YN YO YS YU
YV YV0 Z2 Z3 ZA ZB ZC4 ZD7 ZD8 ZD9 ZF ZK1N ZK1S ZK2 ZK3
ZL ZL7 ZL8 ZL9 ZP ZS ZS8 KC4 E5
Type 1 Suffixes: /0 /1 /2 /3 /4 /5 /6 /7 /8 /9 /A /P)", {"Courier", 10}});
}
m_prefixes->showNormal();
m_prefixes->raise ();
}
bool MainWindow::shortList(QString callsign) const
{
int n=callsign.length();
int i1=callsign.indexOf("/");
Q_ASSERT(i1>0 and i1<n);
QString t1=callsign.mid(0,i1);
QString t2=callsign.mid(i1+1,n-i1-1);
bool b=(m_pfx.contains(t1) or m_sfx.contains(t2));
return b;
}
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
void MainWindow::pskSetLocal ()
{
if (!m_config.spot_to_psk_reporter ()) return;
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
// find the station row, if any, that matches the band we are on
auto stations = m_config.stations ();
auto matches = stations->match (stations->index (0, StationList::band_column)
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
, Qt::DisplayRole
, ui->bandComboBox->currentText ()
, 1
, Qt::MatchExactly);
QString antenna_description;
if (!matches.isEmpty ()) {
antenna_description = stations->index (matches.first ().row ()
, StationList::description_column).data ().toString ();
}
// qDebug() << "To PSKreporter: local station details";
m_psk_Reporter.setLocalStation(m_config.my_callsign (), m_config.my_grid (), antenna_description);
Added support for use of "Standard" locations for writable files. This allows writable files to be located in the "correct" location for each platform rather than in the directory of the executable which, in general, is not recommended or allowed in some cases. A preprocessor macro WSJT_STANDARD_FILE_LOCATIONS is used to switch be tween old and new functionality, currently it is on by default. It can be turned off by defining it to a false value (0) or more simply with cmake-gui setting the option with the same name. JTAlert can only work with the old non-standard file locations until Laurie VK3AMA chooses to support the new file locations. Even if the above is not enabled; the QSettings file is written to a user specific location so it will be shared by all instances of the program (i.e. across upgrades). See below for multiple concurrent instance support changes. Added a command line parser module for Fortran. Added 'lib/options.f90' to facilitate more complex argument passing to jt9 to cover explicit file locations. Changed the way multiple concurrent instances are handled. This is to allow the program to be run multiple times from the same installation directory. A new wsjtx command line optional argument is available "-r" or "--rig" which enables multiple concurrent instance support. The parameter of the new option is a unique name signifying a rig or equivalent. The name is used as the shared memory segment key and in window titles. The name is also used to access unique settings files and writable data files like ALL.TXT and log files. No attempt has been made to share these files between concurrent instances. If "-r" or "--rig" is used without a parameter it still enables multiple concurrent instance support for that instance. All instances must use a unique parameter, one of which may be empty. The rig name is appended the QCoreApplication::applicationName() for convenient usage like window titles. Set non Qt locale to "C". This ensures that C library functions give consistent results whatever the system locale is set to. QApplication follows the system locale as before. Thus using QApplication and its descendants like widgets and QString for all user visible formating will give correct l10n and using C/C++ library will give consistent formatting across locales. Added top level C++ exception handling to main.cpp. Because the new transceiver framework uses exceptions internally, the main function now handles any exceptions that aren't caught. Retired devsetup, replaced with Configuration. Configuration is a class that encapsulates most of the configuration behavior. Because rig configuration is so closely coupled with rig operation, Configuration serves as a proxy for access to the rig control functions. See Configuration.hpp for more details of the Configuration interface. Menu changes. Various checkable menu actions moved from main menu to the Configuration dialog. The whole settings menu has been retired with the single "Settings..." action moved to the file menu for consistency on Mac where it appears as "Preferences" in line with Mac guidelines. New data models for data used by the application. ADIF amateur band parameters, free text message macros, spot working frequencies and, station information (station descriptions and transverter offsets per band) each implement the QAbstractItemModel interface allowing them to be used directly with Qt view widgets (Bands.hpp, FrequencyList.hpp and, StationList.hpp). Configuration manages maintenance of an instance of all but the former of the above models. The ADIF band model is owned by Configuration but requires no user maintenance as it is immutable. Band combo box gets more functionality. This widget is now an editable QComboBox with some extra input capabilities. The popup list is still the list of spot working frequencies, now showing the actual frequency decorated with the band name. This allows multiple spot frequencies on a band if required. The line edit allows direct frequency entry in mega-Hertz with a completer built in to suggest the available spot working frequencies. It also allows band name entry where the first available spot working frequency is selected. Recognized band names are those that are defined by the ADIF specification and can be found in in the implementation of the ADIF bands model (Bands.cpp). If an out of band frequency is chosen, the line edit shows a warning red background and the text "OOB". Out of band is only defined by the ADIF band limits which in general are wider than any entities regulations. Qt 5.2 now supports default audio i/p and o/p devices. These devices are placeholders for whatever the user defines as the default device. Because of this they need special treatment as the actual device used is chosen at open time behind the scenes. Close-down behavior is simplified. The close-down semantics were broken such that some objects were not being shut down cleanly, this required amendments to facilitate correct close down of threads. User font selection added to Configuration UI. Buttons to set the application font and the font for the band and Rx frequency activity widgets have been added to the Configuration UI to replace the file based font size control. Free text macros now selected directly. The free text line edit widgets are now editable combo boxes that have the current free text macro definitions as their popup list. The old context menu to do this has been retired. Astronomical data window dynamically formatted and has font a chooser. This window is now autonomous, has its own font chooser and, dynamically resizes to cover the contents. Double click to Tx enabled now has its own widget in the status bar. QDir used for portable path and file name handling throughout. The "Monitor", "Decode", "Enable Tx" and, "Tune" buttons are now checkable. Being checkable allows these buttons control their own state and rendering. Calls to PSK Reporter interface simplified. In mainwindow.cpp the calls to this interface are rationalized to just 3 locations. Manipulation of ALL.TXT simplified. Moved, where possible, to common functions. Elevated frequency types to be Qt types. Frequency and FrequencyDelta defined as Qt types in their meta-type system (Radio.hpp). They are integral types for maximum accuracy. Re-factored rig control calls in mainwindow.cpp. The new Configuration proxy access to rig control required many changes (mostly simplifications) to the MainWindow rig control code. Some common code has been gathered in member functions like qsy(), monitor(), band_changed() and auto_tx_mode(). Rig control enhancements. The rig control for clients interface is declared as an abstract interface (See Transceiver.hpp). Concrete implementations of this interface are provided for the Hamlib rig control library, DX Lab Suite Commander via a TCP/IP command channel, Ham Radio Deluxe also via a TCP/IP command channel and, OmniRig via its Windows COM server interface. Concrete Transceiver implementations are expected to be moved to a separate thread after construction since many operations are blocking and not suitable for running in a GUI thread. To facilitate this all instantiation of concrete Transceiver instances are handled by Configuration using a factory class (TransceiverFactory) for configuration parameter based instantiation. Various common functionality shared by different rig interface implementations are factored out into helper base classes that implement or delegate parts of the Transceiver interface. They are TransceiverBase which caches state to minimize expensive rig commands, it also maps the Transceiver interface into a more convenient form for implementation (template methods). PollingTransceiver that provides a state polling mechanism that only reports actual changes. EmulateSplitTransceiver that provides split operation by QSYing on PTT state changes. EmulateSplitTransceiver can be used with any implementation as it follows the GoF Decorator pattern and can wrap any Transceiver implementation. OmniRigTransceiver is derived directly from TransceiverBase since it doesn't require polling due to its asynchronous nature. OmniRigTransceiver is only built on Windows as it is a COM server client. To build it you must first install the OmniRig client on the development machine (http://www.dxatlas.com/omnirig/). DXLabSuiteCommanderTransceiver derives from PollingTransceiver since it is a synchronous communications channel. No third party library is required for this interface. HRDTransceiver also derives from PollingTransceiver. The HRD interface library has been reverse engineered to provide functionality with all available versions of HRD. No third party libraries are required. HamlibTransceiver likewise derives from PollingTransceiver since the Hamlib asynchronous interface is non-functional. Although this class will interface with the release version of Hamlib (1.2.15.3); for correct operation on most rigs it needs to run with the latest master branch code of Hamlib. During development many changes to Hamlib have been submitted and accepted, hence this requirement. Hamlib source can be obtained from git://git.code.sf.net/p/hamlib/code and at the time of writing he master branch was at SHA 6e4432. The Hamlib interface directly calls the "C" interface and the modified rigclass.{h,cpp} files have been retired. There is a rig type selection of "None" which may be used for non-CAT rigs, this is actually a connection to the dummy Hamlib device. PollingTransvceiver derives from TransceiverBase and TransceiverBase derives from the Transceiver interface. Each interface implementation offers some possibility of PTT control via a different serial port than the CAT port. We also support PTT control directly via a second serial port. This is done by delegating to a dummy Hamlib instance which is only used for PTT control. This means that DXLabSuiteCommanderTransceiver, HRDTransceiver and OmniRigTransceiver always wrap a dummy HamlibTransceiver instance. The factory class TransceiverFactory manages all these constructional complexities. Serial port selection combo boxes are now editable with a manually entered value being saved to the settings file. This allows a non-standard port device to be used without having to edit the settings file manually. For TCP/IP network CAT interfaces; the network address and port may be specified allowing the target device to be located on a different machine from the one running wsjtx if required. The default used when the address field is left blank is the correct one for normal usage on the local host. Selecting a polling interval of zero is no longer possible, this is because the rig control capability can no longer support one way connection. This is in line with most other CAT control software. In the Configuration dialog there are options to select split mode control by the software and mode control by the software. For the former "None", "Rig" and "Fake it" are available, for the latter "None", "USB" and, "Data" are available. Because tone generation is implicitly linked to split mode operation; it is no longer possible to have the software in split mode and the rig not or vice versa. This may mean some rigs cannot be used in split mode and therefore not in dual JT65+JT9 until issues with CAT control with that rig are resolved. Single mode with VOX keying and no CAT control are still possible so even the most basic transceiver setup is supported as before. Configuration now supports a frequency offset suitable for transverter operation. The station details model (StationList.hpp) includes a column to store an offset for each band if required. CMake build script improvements. The CMakeLists.txt from the 'lib' directory has been retired with its contents merged into the top level CMakeLists.txt. Install target support has been greatly improved with the Release build configuration now building a fully standalone installation on Mac and Windows. The Debug configuration still builds an installation that has environment dependencies for external libraries, which is desirable for testing and debugging. Package target support is largely complete for Mac, Windows and, Linux, it should be possible to build release installers directly from CMake/CPack. Cmake FindXXXX.cmake modules have been added to improve the location of fftw-3 and Hamlib packages. Version numbers are now stored in Versions.cmake and work in concert with automatic svn revision lookup during build. The version string becomes 'rlocal'± if there are any uncommitted changes in the build source tree. Moved resource like files to Qt resources. Because location of resource files (when they cannot go into the installation directory because of packaging rules) is hard to standardize. I have used the Qt resource system for all ancillary data files. Some like kvasd.dat are dumped out to the temp (working directory) because they are accessed by an external program, others like the audio samples are copied out so they appear in the data directory under the default save directory. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@3929 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2014-03-26 09:21:00 -04:00
}
void MainWindow::transmitDisplay (bool transmitting)
{
if (transmitting == m_transmitting) {
if (transmitting) {
ui->signal_meter_widget->setValue(0,0);
if (m_monitoring) monitor (false);
m_btxok=true;
}
auto QSY_allowed = !transmitting or m_config.tx_QSY_allowed () or
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
!m_config.split_mode ();
if (ui->cbHoldTxFreq->isChecked ()) {
ui->TxFreqSpinBox->setEnabled (QSY_allowed);
ui->pbT2R->setEnabled (QSY_allowed);
}
2020-07-23 13:51:05 -04:00
if (m_mode!="WSPR" and m_mode!="FST4W") {
if(m_config.enable_VHF_features ()) {
ui->TxFreqSpinBox->setEnabled (true);
} else {
ui->TxFreqSpinBox->setEnabled (QSY_allowed and !m_bFastMode);
ui->pbR2T->setEnabled (QSY_allowed);
ui->cbHoldTxFreq->setEnabled (QSY_allowed);
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
// the following are always disallowed in transmit
ui->menuMode->setEnabled (!transmitting);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
//ui->bandComboBox->setEnabled (!transmitting);
if (!transmitting) {
if (m_mode == "JT9+JT65") {
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
// allow mode switch in Rx when in dual mode
ui->pbTxMode->setEnabled (true);
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
} else {
ui->pbTxMode->setEnabled (false);
}
}
}
void MainWindow::on_sbFtol_valueChanged(int value)
{
m_wideGraph->setTol (value);
statusUpdate ();
}
void::MainWindow::VHF_features_enabled(bool b)
{
if(m_mode!="JT4" and m_mode!="JT65") b=false;
if(b and (ui->actionInclude_averaging->isChecked() or
ui->actionInclude_correlation->isChecked())) {
ui->actionDeepestDecode->setChecked (true);
}
ui->actionInclude_averaging->setVisible (b);
ui->actionInclude_correlation->setVisible (b);
ui->actionMessage_averaging->setEnabled(b);
ui->actionEnable_AP_DXcall->setVisible (m_mode=="QRA64");
ui->actionEnable_AP_JT65->setVisible (b && m_mode=="JT65");
if(!b && m_msgAvgWidget and (SpecOp::FOX != m_config.special_op_id()) and !m_config.autoLog()) {
if(m_msgAvgWidget->isVisible() and m_mode!="JT4" and m_mode!="JT9" and m_mode!="JT65") {
m_msgAvgWidget->close();
}
}
}
void MainWindow::on_sbTR_valueChanged(int value)
{
// if(!m_bFastMode and n>m_nSubMode) m_MinW=m_nSubMode;
2020-07-23 13:51:05 -04:00
if(m_bFastMode or m_mode=="FreqCal" or m_mode=="FST4" or m_mode=="FST4W") {
m_TRperiod = value;
2020-07-23 13:51:05 -04:00
if (m_mode == "FST4" || m_mode == "FST4W")
{
if (m_TRperiod < 60)
{
ui->lh_decodes_headings_label->setText(" UTC dB DT Freq " + tr ("Message"));
2020-07-23 13:51:05 -04:00
if (m_mode != "FST4W")
{
ui->rh_decodes_headings_label->setText(" UTC dB DT Freq " + tr ("Message"));
}
}
else
{
ui->lh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
2020-07-23 13:51:05 -04:00
if (m_mode != "FST4W")
{
ui->rh_decodes_headings_label->setText("UTC dB DT Freq " + tr ("Message"));
}
}
}
m_fastGraph->setTRPeriod (value);
m_modulator->setTRPeriod (value); // TODO - not thread safe
m_detector->setTRPeriod (value); // TODO - not thread safe
m_wideGraph->setPeriod (value, m_nsps);
progressBar.setMaximum (value);
}
if(m_mode=="FST4") chk_FST4_freq_range();
if(m_monitoring) {
on_stopButton_clicked();
on_monitorButton_clicked(true);
}
if(m_transmitting) {
on_stopTxButton_clicked();
}
statusUpdate ();
}
2020-07-23 13:51:05 -04:00
void MainWindow::on_sbTR_FST4W_valueChanged(int value)
{
on_sbTR_valueChanged(value);
}
QChar MainWindow::current_submode () const
{
QChar submode {0};
if (m_mode.contains (QRegularExpression {R"(^(JT65|JT9|JT4|ISCAT|QRA64)$)"})
&& (m_config.enable_VHF_features () || "JT4" == m_mode || "ISCAT" == m_mode))
{
submode = m_nSubMode + 65;
}
return submode;
}
void MainWindow::on_sbSubmode_valueChanged(int n)
{
m_nSubMode=n;
m_wideGraph->setSubMode(m_nSubMode);
auto submode = current_submode ();
if (submode != QChar::Null)
{
mode_label.setText (m_mode + " " + submode);
}
else
{
mode_label.setText (m_mode);
}
if(m_mode=="ISCAT") {
if(m_nSubMode==0) ui->TxFreqSpinBox->setValue(1012);
if(m_nSubMode==1) ui->TxFreqSpinBox->setValue(560);
}
if(m_mode=="JT9") {
if(m_nSubMode<4) {
ui->cbFast9->setChecked(false);
on_cbFast9_clicked(false);
ui->cbFast9->setEnabled(false);
ui->sbTR->setVisible(false);
m_TRperiod=60.0;
} else {
ui->cbFast9->setEnabled(true);
}
ui->sbTR->setVisible(m_bFast9);
if(m_bFast9) ui->TxFreqSpinBox->setValue(700);
}
if(m_transmitting and m_bFast9 and m_nSubMode>=4) transmit (99.0);
statusUpdate ();
}
void MainWindow::on_cbFast9_clicked(bool b)
{
if(m_mode=="JT9") {
m_bFast9=b;
// ui->cbAutoSeq->setVisible(b);
on_actionJT9_triggered();
}
if(b) {
m_TRperiod = ui->sbTR->value ();
} else {
m_TRperiod=60.0;
}
progressBar.setMaximum(int(m_TRperiod));
m_wideGraph->setPeriod(m_TRperiod,m_nsps);
fast_config(b);
statusChanged ();
}
void MainWindow::on_cbShMsgs_toggled(bool b)
{
ui->cbTx6->setEnabled(b);
m_bShMsgs=b;
if(b) ui->cbSWL->setChecked(false);
if(m_bShMsgs and (m_mode=="MSK144")) ui->rptSpinBox->setValue(1);
int it0=itone[0];
int ntx=m_ntx;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_lastCallsign.clear (); // ensure Tx5 gets updated
genStdMsgs(m_rpt);
itone[0]=it0;
if(ntx==1) ui->txrb1->setChecked(true);
if(ntx==2) ui->txrb2->setChecked(true);
if(ntx==3) ui->txrb3->setChecked(true);
if(ntx==4) ui->txrb4->setChecked(true);
if(ntx==5) ui->txrb5->setChecked(true);
if(ntx==6) ui->txrb6->setChecked(true);
}
void MainWindow::on_cbSWL_toggled(bool b)
{
if(b) ui->cbShMsgs->setChecked(false);
}
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
void MainWindow::on_cbTx6_toggled(bool)
{
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
genCQMsg ();
}
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
// Takes a decoded CQ line and sets it up for reply
void MainWindow::replyToCQ (QTime time, qint32 snr, float delta_time, quint32 delta_frequency
, QString const& mode, QString const& message_text
, bool /*low_confidence*/, quint8 modifiers)
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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{
QString format_string {"%1 %2 %3 %4 %5 %6"};
auto const& time_string = time.toString ("~" == mode || "&" == mode
|| "+" == mode ? "hhmmss" : "hhmm");
auto text = message_text;
auto ap_pos = text.lastIndexOf (QRegularExpression {R"((?:\?\s)?a[0-9]$)"});
if (ap_pos >= 0)
{
// beware of decodes ending on shorter version of wanted call so
// add a space
text = text.left (ap_pos).trimmed () + ' ';
}
auto message_line = format_string
.arg (time_string)
.arg (snr, 3)
.arg (delta_time, 4, 'f', 1)
.arg (delta_frequency, 4)
.arg (mode, -2)
.arg (text);
QTextCursor start {ui->decodedTextBrowser->document ()};
start.movePosition (QTextCursor::End);
auto cursor = ui->decodedTextBrowser->document ()->find (message_line, start, QTextDocument::FindBackward);
if (cursor.isNull ())
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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{
// try again with with -0.0 delta time
cursor = ui->decodedTextBrowser->document ()->find (format_string
.arg (time_string)
.arg (snr, 3)
.arg ('-' + QString::number (delta_time, 'f', 1), 4)
.arg (delta_frequency, 4)
.arg (mode, -2)
.arg (text), start, QTextDocument::FindBackward);
}
if (!cursor.isNull ())
{
if (m_config.udpWindowToFront ())
{
show ();
raise ();
activateWindow ();
}
if (m_config.udpWindowRestore () && isMinimized ())
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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{
showNormal ();
raise ();
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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}
if (text.contains (QRegularExpression {R"(^(CQ |CQDX |QRZ ))"})) {
// a message we are willing to accept and auto reply to
m_bDoubleClicked = true;
}
DecodedText message {message_line};
Qt::KeyboardModifiers kbmod {modifiers << 24};
processMessage (message, kbmod);
tx_watchdog (false);
QApplication::alert (this);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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}
else
{
qDebug () << "process reply message ignored, decode not found:" << message_line;
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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}
}
void MainWindow::locationChange (QString const& location)
{
QString grid {location.trimmed ()};
int len;
// string 6 chars or fewer, interpret as a grid, or use with a 'GRID:' prefix
if (grid.size () > 6) {
if (grid.toUpper ().startsWith ("GRID:")) {
grid = grid.mid (5).trimmed ();
}
else {
// TODO - support any other formats, e.g. latlong? Or have that conversion done external to wsjtx
return;
}
}
if (MaidenheadLocatorValidator::Acceptable == MaidenheadLocatorValidator ().validate (grid, len)) {
qDebug() << "locationChange: Grid supplied is " << grid;
if (m_config.my_grid () != grid) {
m_config.set_location (grid);
genStdMsgs (m_rpt, false);
statusUpdate ();
}
} else {
qDebug() << "locationChange: Invalid grid " << grid;
}
}
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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void MainWindow::replayDecodes ()
{
// we accept this request even if the setting to accept UDP requests
// is not checked
// attempt to parse the decoded text
for (QTextBlock block = ui->decodedTextBrowser->document ()->firstBlock (); block.isValid (); block = block.next ())
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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{
auto message = block.text ();
message = message.left (message.indexOf (QChar::Nbsp)); // discard
// any
// appended info
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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if (message.size() >= 4 && message.left (4) != "----")
{
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auto const& parts = message.split (' ', SkipEmptyParts);
if (parts.size () >= 5 && parts[3].contains ('.')) //
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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{
postWSPRDecode (false, parts);
}
else
{
// TODO - how to skip ISCAT decodes
postDecode (false, message);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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}
}
}
statusChanged ();
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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}
void MainWindow::postDecode (bool is_new, QString const& message)
{
auto const& decode = message.trimmed ();
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auto const& parts = decode.left (22).split (' ', SkipEmptyParts);
if (parts.size () >= 5)
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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{
auto has_seconds = parts[0].size () > 4;
m_messageClient->decode (is_new
, QTime::fromString (parts[0], has_seconds ? "hhmmss" : "hhmm")
, parts[1].toInt ()
, parts[2].toFloat (), parts[3].toUInt (), parts[4]
, decode.mid (has_seconds ? 24 : 22)
, QChar {'?'} == decode.mid (has_seconds ? 24 + 21 : 22 + 21, 1)
, m_diskData);
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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}
}
void MainWindow::postWSPRDecode (bool is_new, QStringList parts)
{
if (parts.size () < 8)
{
parts.insert (6, "");
}
m_messageClient->WSPR_decode (is_new, QTime::fromString (parts[0], "hhmm"), parts[1].toInt ()
, parts[2].toFloat (), Radio::frequency (parts[3].toFloat (), 6)
, parts[4].toInt (), parts[5], parts[6], parts[7].toInt ()
, m_diskData);
}
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
void MainWindow::networkError (QString const& e)
{
if (m_splash && m_splash->isVisible ()) m_splash->hide ();
if (MessageBox::Retry == MessageBox::warning_message (this, tr ("Network Error")
, tr ("Error: %1\nUDP server %2:%3")
.arg (e)
.arg (m_config.udp_server_name ())
.arg (m_config.udp_server_port ())
, QString {}
, MessageBox::Cancel | MessageBox::Retry
, MessageBox::Cancel))
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
{
// retry server lookup
m_messageClient->set_server (m_config.udp_server_name (), m_config.udp_interface_names ());
Send status information to UDP server To facilitate interaction with other applications WSJT-X now sends status updates to a predefined UDP server or multicast group address. The status updates include the information currently posted to the decodes.txt and wsjtx_status.txt files. An optional back communications channel is also implemented allowing the UDP server application to control some basic actions in WSJT-X. A reference implementaion of a typical UDP server written in C++ using Qt is provided to demonstrate these facilities. This application is not intended as a user tool but only as an example of how a third party application may interact with WSJT-X. The UDP messages Use QDataStream based serialization. Messages are documented in NetworkMessage.hpp along with some helper classes that simplify the building and decoding of messages. Two message handling classes are introduced, MessageClient and MessageServer. WSJT-X uses the MessageClient class to manage outgoing and incoming UDP messages that allow communication with other applications. The MessageServer class implements the kind of code that a potential cooperating application might use. Although these classes use Qt serialization facilities, the message formats are easily read and written by applications that do not use the Qt framework. MessageAggregator is a demonstration application that uses MessageServer and presents a GUI that displays messages from one or more WSJT-X instances and allows sending back a CQ or QRZ reply invocation by double clicking a decode. This application is not intended as a user facing tool but rather as a demonstration of the WSJT-X UDP messaging facility. It also demonstrates being a multicast UDP server by allowing multiple instances to run concurrently. This is enabled by using an appropriate multicast group address as the server address. Cooperating applications need not implement multicast techniques but it is recomended otherwise only a single appliaction can act as a broadcast message (from WSJT-X) recipient. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5225 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-15 12:40:49 -04:00
}
}
void MainWindow::on_syncSpinBox_valueChanged(int n)
{
m_minSync=n;
}
void MainWindow::p1ReadFromStdout() //p1readFromStdout
{
QString t1;
while(p1.canReadLine()) {
QString t(p1.readLine());
if(ui->cbNoOwnCall->isChecked()) {
if(t.contains(" " + m_config.my_callsign() + " ")) continue;
if(t.contains(" <" + m_config.my_callsign() + "> ")) continue;
}
if(t.indexOf("<DecodeFinished>") >= 0) {
m_bDecoded = m_nWSPRdecodes > 0;
if(!m_diskData) {
WSPR_history(m_dialFreqRxWSPR, m_nWSPRdecodes);
if(m_nWSPRdecodes==0 and ui->band_hopping_group_box->isChecked()) {
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t = " " + tr ("Receiving") + " " + m_mode + " ----------------------- " +
m_config.bands ()->find (m_dialFreqRxWSPR);
t=beacon_start_time (-m_TRperiod / 2) + ' ' + t.rightJustified (66, '-');
ui->decodedTextBrowser->appendText(t);
}
killFileTimer.start (45*1000); //Kill in 45s (for slow modes)
}
m_nWSPRdecodes=0;
ui->DecodeButton->setChecked (false);
if (m_uploadWSPRSpots
&& m_config.is_transceiver_online ()) { // need working rig control
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#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
uploadTimer.start(QRandomGenerator::global ()->bounded (0, 20000)); // Upload delay
#else
uploadTimer.start(20000 * qrand()/((double)RAND_MAX + 1.0)); // Upload delay
#endif
} else {
QFile f {QDir::toNativeSeparators (m_config.writeable_data_dir ().absoluteFilePath ("wspr_spots.txt"))};
if (f.exists ()) f.remove ();
}
m_RxLog=0;
m_startAnother=m_loopall;
m_decoderBusy = false;
statusUpdate ();
} else {
int n=t.length();
t=t.mid(0,n-2) + " ";
t.remove(QRegExp("\\s+$"));
QStringList rxFields = t.split(QRegExp("\\s+"));
QString rxLine;
QString grid="";
if ( rxFields.count() == 8 ) {
rxLine = QString("%1 %2 %3 %4 %5 %6 %7 %8")
.arg(rxFields.at(0), 4)
.arg(rxFields.at(1), 4)
.arg(rxFields.at(2), 5)
.arg(rxFields.at(3), 11)
.arg(rxFields.at(4), 4)
.arg(rxFields.at(5).leftJustified (12))
.arg(rxFields.at(6), -6)
.arg(rxFields.at(7), 3);
postWSPRDecode (true, rxFields);
grid = rxFields.at(6);
} else if ( rxFields.count() == 7 ) { // Type 2 message
rxLine = QString("%1 %2 %3 %4 %5 %6 %7 %8")
.arg(rxFields.at(0), 4)
.arg(rxFields.at(1), 4)
.arg(rxFields.at(2), 5)
.arg(rxFields.at(3), 11)
.arg(rxFields.at(4), 4)
.arg(rxFields.at(5).leftJustified (12))
.arg("", -6)
.arg(rxFields.at(6), 3);
postWSPRDecode (true, rxFields);
} else {
rxLine = t;
}
if(grid!="") {
double utch=0.0;
int nAz,nEl,nDmiles,nDkm,nHotAz,nHotABetter;
azdist_(const_cast <char *> ((m_config.my_grid () + " ").left (6).toLatin1 ().constData ()),
const_cast <char *> ((grid + " ").left (6).toLatin1 ().constData ()),&utch,
&nAz,&nEl,&nDmiles,&nDkm,&nHotAz,&nHotABetter,6,6);
QString t1;
if(m_config.miles()) {
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t1 = t1.asprintf("%7d",nDmiles);
} else {
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t1 = t1.asprintf("%7d",nDkm);
}
rxLine += t1;
}
if (rxLine.left (4) != m_tBlankLine) {
ui->decodedTextBrowser->new_period ();
if (m_config.insert_blank ()) {
QString band;
Frequency f=1000000.0*rxFields.at(3).toDouble()+0.5;
band = ' ' + m_config.bands ()->find (f);
ui->decodedTextBrowser->appendText(band.rightJustified (71, '-'));
}
m_tBlankLine = rxLine.left(4);
}
m_nWSPRdecodes += 1;
ui->decodedTextBrowser->appendText(rxLine);
}
}
}
QString MainWindow::beacon_start_time (int n)
{
auto bt = qt_truncate_date_time_to (QDateTime::currentDateTimeUtc ().addSecs (n), m_TRperiod * 1.e3);
if (m_TRperiod < 60.)
{
return bt.toString ("HHmmss");
}
else
{
return bt.toString ("HHmm");
}
}
void MainWindow::WSPR_history(Frequency dialFreq, int ndecodes)
{
QDateTime t=QDateTime::currentDateTimeUtc().addSecs(-60);
QString t1=t.toString("yyMMdd");
QString t2=beacon_start_time (-m_TRperiod / 2);
QString t3;
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t3 = t3.asprintf("%13.6f",0.000001*dialFreq);
if(ndecodes<0) {
t1=t1 + " " + t2 + t3 + " T";
} else {
QString t4;
2020-05-06 21:56:57 -04:00
t4 = t4.asprintf("%4d",ndecodes);
t1=t1 + " " + t2 + t3 + " R" + t4;
}
QFile f {m_config.writeable_data_dir ().absoluteFilePath ("WSPR_history.txt")};
if (f.open(QIODevice::WriteOnly | QIODevice::Text | QIODevice::Append)) {
QTextStream out(&f);
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out << t1
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f.close();
} else {
MessageBox::warning_message (this, tr ("File Error")
, tr ("Cannot open \"%1\" for append: %2")
.arg (f.fileName ()).arg (f.errorString ()));
}
}
void MainWindow::uploadWSPRSpots (bool direct_post, QString const& decode_text)
{
// do not spot if disabled, replays, or if rig control not working
if(!m_uploadWSPRSpots || m_diskData || !m_config.is_transceiver_online ()) return;
if(m_uploading && !decode_text.size ()) {
qDebug() << "Previous upload has not completed, spots were lost";
wsprNet->abortOutstandingRequests ();
m_uploading = false;
}
QString rfreq = QString("%1").arg((m_dialFreqRxWSPR + m_wideGraph->rxFreq ()) / 1e6, 0, 'f', 6);
QString tfreq = QString("%1").arg((m_dialFreqRxWSPR +
ui->TxFreqSpinBox->value()) / 1e6, 0, 'f', 6);
auto pct = QString::number (ui->autoButton->isChecked () ? ui->sbTxPercent->value () : 0);
if (direct_post)
{
// queues one FST4W spot
wsprNet->post (m_config.my_callsign (), m_config.my_grid (), rfreq, tfreq,
m_mode, m_TRperiod, pct,
QString::number (m_dBm), version (), decode_text);
}
else
{
// queues spots for each decode in wspr_spots.txt
wsprNet->upload (m_config.my_callsign (), m_config.my_grid (), rfreq, tfreq,
m_mode, m_TRperiod, pct,
QString::number (m_dBm), version (),
m_config.writeable_data_dir ().absoluteFilePath ("wspr_spots.txt"));
}
// trigger upload of any queued spots
if (!decode_text.size ())
{
m_uploading = true;
}
}
void MainWindow::uploadResponse(QString const& response)
{
if (response == "done") {
m_uploading=false;
} else {
if (response.startsWith ("Upload Failed")) {
m_uploading=false;
}
qDebug () << "WSPRnet.org status:" << response;
}
}
void MainWindow::on_TxPowerComboBox_currentIndexChanged(int index)
{
m_dBm = ui->TxPowerComboBox->itemData (index).toInt ();
}
void MainWindow::on_cbUploadWSPR_Spots_toggled(bool b)
{
m_uploadWSPRSpots=b;
}
void MainWindow::on_WSPRfreqSpinBox_valueChanged(int n)
{
ui->TxFreqSpinBox->setValue(n);
}
void MainWindow::on_sbFST4W_RxFreq_valueChanged(int n)
{
m_wideGraph->setRxFreq(n);
statusUpdate ();
}
void MainWindow::on_sbFST4W_FTol_valueChanged(int n)
{
ui->sbFST4W_RxFreq->setSingleStep(n);
m_wideGraph->setTol(n);
statusUpdate ();
}
void MainWindow::on_pbTxNext_clicked(bool b)
{
if (b && !ui->autoButton->isChecked ())
{
ui->autoButton->click (); // make sure Tx is possible
}
}
void MainWindow::WSPR_scheduling ()
{
if (ui->pbTxNext->isEnabled () && ui->pbTxNext->isChecked ())
{
// Tx Next button overrides all scheduling
m_WSPR_tx_next = true;
return;
}
QString t=ui->RoundRobin->currentText();
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if(m_mode=="FST4W" and t != tr ("Random")) {
bool ok;
int i=t.left (1).toInt (&ok) - 1;
if (!ok) return;
int n=t.right (1).toInt (&ok);
if (!ok || 0 == n) return;
qint64 ms = QDateTime::currentMSecsSinceEpoch() % 86400000;
int nsec=ms/1000;
int ntr=m_TRperiod;
int j=((nsec+ntr-1) % (n*ntr))/ntr;
m_WSPR_tx_next = i == j;
return;
}
m_WSPR_tx_next = false;
if (!ui->sbTxPercent->isEnabled () || !ui->sbTxPercent->value ())
{
return; // don't schedule if %age disabled or zero
}
if (m_config.is_transceiver_online () // need working rig control for hopping
2020-07-27 10:01:09 -04:00
&& !m_config.is_dummy_rig ()
&& ui->band_hopping_group_box->isChecked ()) {
auto hop_data = m_WSPR_band_hopping.next_hop (m_auto);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
qDebug () << "hop data: period:" << hop_data.period_name_
<< "frequencies index:" << hop_data.frequencies_index_
<< "tune:" << hop_data.tune_required_
<< "tx:" << hop_data.tx_next_;
m_WSPR_tx_next = hop_data.tx_next_;
if (hop_data.frequencies_index_ >= 0) { // new band
ui->bandComboBox->setCurrentIndex (hop_data.frequencies_index_);
on_bandComboBox_activated (hop_data.frequencies_index_);
// Execute user's hardware controller
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auto band = m_config.bands ()->find (m_freqNominal).remove ('m');
#if defined(Q_OS_WIN)
// On windows we use CMD.EXE to find and execute the
// user_hardware executable. This means that the first matching
// file extension on the PATHEXT environment variable found on
// the PATH environment variable path list. This give maximum
// flexibility for users to write user_hardware in their
// language of choice, and place the file anywhere on the PATH
// environment variable. Equivalent to typing user_hardware
// without any path or extension at the CMD.EXE prompt.
2020-07-26 19:51:12 -04:00
p3.start("CMD", QStringList {"/C", "user_hardware", band});
#else
// On non-Windows systems we expect the user_hardware executable
// to be anywhere in the paths specified in the PATH environment
// variable path list, and executable. Equivalent to typing
// user_hardware without any path at the shell prompt.
p3.start("/bin/sh", QStringList {"-c", "user_hardware " + band});
#endif
// Produce a short tuneup signal
m_tuneup = false;
if (hop_data.tune_required_) {
m_tuneup = true;
on_tuneButton_clicked (true);
tuneATU_Timer.start (2500);
}
}
// Display grayline status
band_hopping_label.setText (hop_data.period_name_);
}
else {
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m_WSPR_tx_next = m_WSPR_band_hopping.next_is_tx(m_mode=="FST4W");
}
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
void MainWindow::astroUpdate ()
{
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if (m_astroWidget)
{
// no Doppler correction while CTRL pressed allows manual tuning
if (Qt::ControlModifier & QApplication::queryKeyboardModifiers ()) return;
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
auto correction = m_astroWidget->astroUpdate(QDateTime::currentDateTimeUtc (),
m_config.my_grid(), m_hisGrid,
m_freqNominal,
"Echo" == m_mode, m_transmitting,
!m_config.tx_QSY_allowed (), m_TRperiod);
// no Doppler correction in Tx if rig can't do it
if (m_transmitting && !m_config.tx_QSY_allowed ()) return;
if (!m_astroWidget->doppler_tracking ()) return;
if ((m_monitoring || m_transmitting)
// no Doppler correction below 6m
&& m_freqNominal >= 50000000
&& m_config.split_mode ())
{
// adjust for rig resolution
if (m_config.transceiver_resolution () > 2)
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
{
correction.rx = (correction.rx + 50) / 100 * 100;
correction.tx = (correction.tx + 50) / 100 * 100;
}
else if (m_config.transceiver_resolution () > 1)
{
correction.rx = (correction.rx + 10) / 20 * 20;
correction.tx = (correction.tx + 10) / 20 * 20;
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
else if (m_config.transceiver_resolution () > 0)
{
correction.rx = (correction.rx + 5) / 10 * 10;
correction.tx = (correction.tx + 5) / 10 * 10;
}
else if (m_config.transceiver_resolution () < -2)
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
{
correction.rx = correction.rx / 100 * 100;
correction.tx = correction.tx / 100 * 100;
}
else if (m_config.transceiver_resolution () < -1)
{
correction.rx = correction.rx / 20 * 20;
correction.tx = correction.tx / 20 * 20;
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
else if (m_config.transceiver_resolution () < 0)
{
correction.rx = correction.rx / 10 * 10;
correction.tx = correction.tx / 10 * 10;
}
m_astroCorrection = correction;
if (m_reverse_Doppler)
{
m_astroCorrection.reverse ();
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
else
{
m_astroCorrection = {};
}
setRig ();
}
}
void MainWindow::setRig (Frequency f)
{
if (f)
{
m_freqNominal = f;
genCQMsg ();
m_freqTxNominal = m_freqNominal;
if (m_astroWidget) m_astroWidget->nominal_frequency (m_freqNominal, m_freqTxNominal);
}
if (m_mode == "FreqCal"
&& m_frequency_list_fcal_iter != m_config.frequencies ()->end ()) {
m_freqNominal = m_frequency_list_fcal_iter->frequency_ - ui->RxFreqSpinBox->value ();
}
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
if(m_transmitting && !m_config.tx_QSY_allowed ()) return;
if ((m_monitoring || m_transmitting) && m_config.transceiver_online ())
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
{
if (m_transmitting && m_config.split_mode ())
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
{
2020-09-08 07:54:19 -04:00
m_config.transceiver_tx_frequency (m_freqTxNominal + m_astroCorrection.tx);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
else
{
2020-09-08 07:54:19 -04:00
m_config.transceiver_frequency (m_freqNominal + m_astroCorrection.rx);
Rig control overhaul to implement generic Doppler shift tracking The concept of a nominal receive and transmit frequency has been introduced. This is used as a base frequency for Doppler correction, frequency setting and reporting. The start up frequency is now zero which is updated by the first rig control status report. This needs more work to accommodate calling frequency plus working frequency operation as is used for random MS operation etc.. The main window frequency display now shows the transmit dial frequency while transmitting. The mode changing logic sequence has been changed such that the rig is correctly put into and taken out of split mode as required by the target mode. This also avoids the "other" VFO having its frequency changed when entering a mode that does not use split operating like WSPR. The main window band combo box edit may now be used to input an kHz offset from the current MHz dial frequency. This is intended for setting a sked or working frequency on the VHF and up bands. For example the working frequency for 23cms might be set to 1296MHz and a working frequency of 1296.3MHz would be selected by selecting the 23cms band with the combo box drop down list and then entering 300k into the band combo box edit widget. When using JT4 modes a CTRL+Click on the waterfall adjusts the nominal frequency such that the frequency clicked on becomes the Tx and Rx frequency using the fixed 1000Hz DF that JT4 modes use. This will probably be extended to all QSO modes when used in VHF & up mode. This assumes that 1000Hz is an optimal DF for both Tx and Rx and therefore one can "net" to an off frequency, but visible on the waterfall, caller with one click. Improvements to OmniRig rig control including use of the serial port control lines RTS or DTR, on the CAT serial port used by OmniRig, for PTT control. Incrementing transaction sequence numbers added to messages to and from the rig control thread. This enables round trip status to be tracked and associated with a request. For example a command that might cause several asynchronous status updates can now be tracked in the originating thread such that it is clear which updates are caused by executing the request. This in turn allows updates to be held until the request is complete i.e. the state is consistent with the results of the request. Messages to the rig control thread are now posted as a new state (Transceiver::TransceiverState) object. The rig control thread tracks requests and actions any differences between the prior requests and the new state. The rig control thread is now stored on the heap so that it can be closed down and released as needed. Along with this the rig control close down semantics are better defined avoiding some potential deadlock situations. If the rig is placed into split mode it will be reverted to simplex mode when the rig connection is closed. When using direct rig control via Hamlib, rigs that have A/B VFO arrangements and no method to query the current VFO like many Icoms and the Yaesu FT-817/857/897(D) series now have smarted frequency updating requiring no VFO changes when changing the frequency. This is particularly important when doing Tx Doppler correction to avoid glitches. The implementation of emulated split operating mode ("Fake It") is simplified and improved. A dummy Hamlib transceiver for PTT control on a separate port is no long instantiated if CAT or VOX PTT control is selected. The resolution and any rounding of the rig CAT frequency set and get commands is determined automatically upon opening the rig connection. This is needed to determine the rate of frequency updates for Doppler tracking. It also allows the rig to be more accurately controlled. Frequency calibration is calculated separately for the receive and transmit frequencies. Whether the rig modulation mode should be controlled is now a constructor argument rather than being passed with individual rig control requests. Doppler shift correction is considerably enhanced with simpler controls and much better rig control. A new mode of tracking called "receive only" is introduced for those with rigs that cannot be QSY:ed via CAT when transmitting. Such rigs have a Doppler correction calculated for the middle of the next transmit period just before transmission starts. While using Doppler tracking it is now possible to adjust the sked frequency either using the new kHz offset feature of the main window band combo box or by directly tuning the rig VFO knob while holding down the CTRL key. The astronomical data window that includes Doppler tracking control is now opened and closed using a checkable menu item to avoid it being accidentally closed. Debug configuration rig control diagnostic messages now have a facility argument for clearer and more standardized trace messages. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6590 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2016-04-06 13:11:58 -04:00
}
}
}
void MainWindow::fastPick(int x0, int x1, int y)
{
float pixPerSecond=12000.0/512.0;
if(m_TRperiod<30.0) pixPerSecond=12000.0/256.0;
if(m_mode!="ISCAT" and m_mode!="MSK144") return;
if(!m_decoderBusy) {
dec_data.params.newdat=0;
dec_data.params.nagain=1;
m_nPick=1;
if(y > 120) m_nPick=2;
m_t0Pick=x0/pixPerSecond;
m_t1Pick=x1/pixPerSecond;
m_dataAvailable=true;
decode();
}
}
void MainWindow::on_actionMeasure_reference_spectrum_triggered()
{
if(!m_monitoring) on_monitorButton_clicked (true);
m_bRefSpec=true;
}
void MainWindow::on_actionMeasure_phase_response_triggered()
{
if(m_bTrain) {
m_bTrain=false;
MessageBox::information_message (this, tr ("Phase Training Disabled"));
} else {
m_bTrain=true;
MessageBox::information_message (this, tr ("Phase Training Enabled"));
}
}
void MainWindow::on_actionErase_reference_spectrum_triggered()
{
m_bClearRefSpec=true;
}
void MainWindow::freqCalStep()
{
if (m_frequency_list_fcal_iter == m_config.frequencies ()->end ()
|| ++m_frequency_list_fcal_iter == m_config.frequencies ()->end ()) {
m_frequency_list_fcal_iter = m_config.frequencies ()->begin ();
}
// allow for empty list
if (m_frequency_list_fcal_iter != m_config.frequencies ()->end ()) {
setRig (m_frequency_list_fcal_iter->frequency_ - ui->RxFreqSpinBox->value ());
}
}
void MainWindow::on_sbCQTxFreq_valueChanged(int)
{
setXIT (ui->TxFreqSpinBox->value ());
}
void MainWindow::on_cbCQTx_toggled(bool b)
{
ui->sbCQTxFreq->setEnabled(b);
genCQMsg();
if(b) {
ui->txrb6->setChecked(true);
m_ntx=6;
Add the option to ALT+click a decoded CQ or QRZ message which only moves the Rx frequency to theirs, this facilitates calling a station who is busy and may have many callers on their frequency. Updated the corresponding mouse shortcuts help text. Allow for times with seconds when parsing fast mode and FT8 decodes. Exclude the RR73 grid square from and grid validation or matching, it is not a grid square any more as far as WSJT-X is concerned, it is an RRR substitute. Add a simple state machine for QSO progress such that replies and auto-sequencing can be better controlled. Get compound callsign edge cases working again and allow QSOs from and to compound callsign holders working in as many situations as possible including auto-sequencing and FT8 auto-reply mode. This does mean that a "DE W6/K1ABC DM93" type message close to a callers Tx or Rx frequency will be taken as a reply to a CQ call despite it not being explicitly addressed back to the CQ caller. Compound callsigns should work in MSK144 contest mode also as well as in short code modes with some minor restrictions (short codes will not be used where configuration demands that a message be used to send a full compound callsign). Auto sequencing has been made generic such that it can be used for more than one mode if desired. Allow the use of free text messages to sign off in auto sequenced QSOs without the message being overwritten by the sequencer. Double click actions have been added to the Tx5 radio and push buttons to revert back to the default standard 73 message. Make DisplayText class interface more idiomatic C++ and simplify a bit. Fixed some displayed widget arrangements for different modes and sub-modes so that they are consistent when starting up and when switching mode or sub-mode. This is a big change which has been extensively tested but no doubt there will also be some new defects introduced. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7939 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-07-24 15:27:23 -04:00
m_QSOProgress = CALLING;
}
setRig ();
setXIT (ui->TxFreqSpinBox->value ());
}
void MainWindow::statusUpdate () const
{
if (!ui || m_block_udp_status_updates) return;
auto submode = current_submode ();
auto ftol = ui->sbFtol->value ();
if ("FST4W" == m_mode)
{
ftol = ui->sbFST4W_FTol->value ();
}
else if (!(ui->sbFtol->isVisible () && ui->sbFtol->isEnabled ()))
{
ftol = quint32_max;
}
auto tr_period = ui->sbTR->value ();
auto rx_frequency = ui->RxFreqSpinBox->value ();
if ("FST4W" == m_mode)
{
tr_period = ui->sbTR_FST4W->value ();
rx_frequency = ui->sbFST4W_RxFreq->value ();
}
else if (!(ui->sbTR->isVisible () && ui->sbTR->isEnabled ()))
{
tr_period = quint32_max;
}
m_messageClient->status_update (m_freqNominal, m_mode, m_hisCall,
QString::number (ui->rptSpinBox->value ()),
m_modeTx, ui->autoButton->isChecked (),
m_transmitting, m_decoderBusy,
rx_frequency, ui->TxFreqSpinBox->value (),
m_config.my_callsign (), m_config.my_grid (),
m_hisGrid, m_tx_watchdog,
submode != QChar::Null ? QString {submode} : QString {}, m_bFastMode,
static_cast<quint8> (m_config.special_op_id ()),
ftol, tr_period, m_multi_settings->configuration_name ());
}
void MainWindow::childEvent (QChildEvent * e)
{
if (e->child ()->isWidgetType ())
{
switch (e->type ())
{
case QEvent::ChildAdded: add_child_to_event_filter (e->child ()); break;
case QEvent::ChildRemoved: remove_child_from_event_filter (e->child ()); break;
default: break;
}
}
QMainWindow::childEvent (e);
}
// add widget and any child widgets to our event filter so that we can
// take action on key press ad mouse press events anywhere in the main window
void MainWindow::add_child_to_event_filter (QObject * target)
{
if (target && target->isWidgetType ())
{
target->installEventFilter (this);
}
auto const& children = target->children ();
for (auto iter = children.begin (); iter != children.end (); ++iter)
{
add_child_to_event_filter (*iter);
}
}
// recursively remove widget and any child widgets from our event filter
void MainWindow::remove_child_from_event_filter (QObject * target)
{
auto const& children = target->children ();
for (auto iter = children.begin (); iter != children.end (); ++iter)
{
remove_child_from_event_filter (*iter);
}
if (target && target->isWidgetType ())
{
target->removeEventFilter (this);
}
}
void MainWindow::tx_watchdog (bool triggered)
{
auto prior = m_tx_watchdog;
m_tx_watchdog = triggered;
if (triggered)
{
m_bTxTime=false;
if (m_tune) stop_tuning ();
if (m_auto) auto_tx_mode (false);
tx_status_label.setStyleSheet ("QLabel{color: #000000; background-color: #ff0000}");
2020-05-19 06:26:24 -04:00
tx_status_label.setText (tr ("Runaway Tx watchdog"));
QApplication::alert (this);
}
else
{
m_idleMinutes = 0;
update_watchdog_label ();
}
if (prior != triggered) statusUpdate ();
}
void MainWindow::update_watchdog_label ()
{
2020-07-23 13:51:05 -04:00
if (m_config.watchdog () && m_mode!="WSPR" && m_mode!="FST4W")
{
2020-05-19 06:26:24 -04:00
watchdog_label.setText (tr ("WD:%1m").arg (m_config.watchdog () - m_idleMinutes));
watchdog_label.setVisible (true);
}
else
{
watchdog_label.setText (QString {});
watchdog_label.setVisible (false);
}
}
void MainWindow::on_cbMenus_toggled(bool b)
{
hideMenus(!b);
}
void MainWindow::on_cbCQonly_toggled(bool)
{ //Fix this -- no decode here?
to_jt9(m_ihsym,1,-1); //Send m_ihsym to jt9[.exe] and start decoding
decodeBusy(true);
}
void MainWindow::on_cbFirst_toggled(bool b)
{
if (b) {
if (m_auto && CALLING == m_QSOProgress) {
ui->cbFirst->setStyleSheet ("QCheckBox{color:red}");
}
} else {
ui->cbFirst->setStyleSheet ("");
}
}
void MainWindow::on_cbAutoSeq_toggled(bool b)
{
if(!b) ui->cbFirst->setChecked(false);
2020-07-23 13:51:05 -04:00
ui->cbFirst->setVisible((m_mode=="FT8" or m_mode=="FT4" or m_mode=="FST4") and b);
}
void MainWindow::on_measure_check_box_stateChanged (int state)
{
m_config.enable_calibration (Qt::Checked != state);
}
void MainWindow::write_transmit_entry (QString const& file_name)
{
QFile f {m_config.writeable_data_dir ().absoluteFilePath (file_name)};
if (f.open(QIODevice::WriteOnly | QIODevice::Text | QIODevice::Append))
{
QTextStream out(&f);
auto time = QDateTime::currentDateTimeUtc ();
time = time.addSecs (-fmod(double(time.time().second()),m_TRperiod));
out << time.toString("yyMMdd_hhmmss")
<< " Transmitting " << qSetRealNumberPrecision (12) << (m_freqNominal / 1.e6)
<< " MHz " << m_modeTx
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<< ": " << m_currentMessage
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f.close();
}
else
{
auto const& message = tr ("Cannot open \"%1\" for append: %2")
.arg (f.fileName ()).arg (f.errorString ());
QTimer::singleShot (0, [=] { // don't block guiUpdate
MessageBox::warning_message (this, tr ("Log File Error"), message);
});
}
}
// -------------------------- Code for FT8 DXpedition Mode ---------------------------
void MainWindow::hound_reply ()
{
if (!m_tune) {
//Select TX3, set TxFreq to FoxFreq, and Force Auto ON.
ui->txrb3->setChecked (true);
m_nSentFoxRrpt = 1;
ui->rptSpinBox->setValue(m_rptSent.toInt());
if (!m_auto) auto_tx_mode(true);
ui->TxFreqSpinBox->setValue (m_nFoxFreq);
}
}
void MainWindow::on_sbNlist_valueChanged(int n)
{
m_Nlist=n;
}
void MainWindow::on_sbNslots_valueChanged(int n)
{
m_Nslots=n;
QString t;
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t = t.asprintf(" NSlots %d",m_Nslots);
writeFoxQSO(t);
}
void MainWindow::on_sbMax_dB_valueChanged(int n)
{
m_max_dB=n;
QString t;
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t = t.asprintf(" Max_dB %d",m_max_dB);
writeFoxQSO(t);
}
void MainWindow::on_pbFoxReset_clicked()
{
auto button = MessageBox::query_message (this, tr ("Confirm Reset"),
tr ("Are you sure you want to clear the QSO queues?"));
if(button == MessageBox::Yes) {
QFile f(m_config.temp_dir().absoluteFilePath("houndcallers.txt"));
f.remove();
ui->decodedTextBrowser->setText("");
ui->textBrowser4->setText("");
m_houndQueue.clear();
m_foxQSO.clear();
m_foxQSOinProgress.clear();
writeFoxQSO(" Reset");
}
}
void MainWindow::on_comboBoxHoundSort_activated(int index)
{
if(index!=-99) houndCallers(); //Silence compiler warning
}
//------------------------------------------------------------------------------
QString MainWindow::sortHoundCalls(QString t, int isort, int max_dB)
{
/* Called from "houndCallers()" to sort the list of calling stations by
* specified criteria.
*
* QString "t" contains a list of Hound callers read from file "houndcallers.txt".
* isort=0: random (shuffled order)
* 1: Call
* 2: Grid
* 3: SNR (reverse order)
* 4: Distance (reverse order)
*/
QMap<QString,QString> map;
QStringList lines,lines2;
QString msg,houndCall,t1;
QString ABC{"ABCDEFGHIJKLMNOPQRSTUVWXYZ _"};
QList<int> list;
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int i,j,k,n,nlines;
bool bReverse=(isort >= 3);
isort=qAbs(isort);
// Save only the most recent transmission from each caller.
lines = t.split("\n");
nlines=lines.length()-1;
for(i=0; i<nlines; i++) {
msg=lines.at(i); //key = callsign
if(msg.mid(13,1)==" ") msg=msg.mid(0,13) + "...." + msg.mid(17);
houndCall=msg.split(" ").at(0); //value = "call grid snr freq dist age"
map[houndCall]=msg;
}
j=0;
t="";
for(auto a: map.keys()) {
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t1=map[a].split(" ",SkipEmptyParts).at(2);
int nsnr=t1.toInt(); // get snr
if(nsnr <= max_dB) { // keep only if snr in specified range
if(isort==1) t += map[a] + "\n";
if(isort==3 or isort==4) {
i=2; // sort Hound calls by snr
if(isort==4) i=4; // sort Hound calls by distance
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t1=map[a].split(" ",SkipEmptyParts).at(i);
n=1000*(t1.toInt()+100) + j; // pack (snr or dist) and index j into n
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list.insert(j,n); // add n to list at [j]
}
if(isort==2) { // sort Hound calls by grid
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t1=map[a].split(" ",SkipEmptyParts).at(1);
if(t1=="....") t1="ZZ99";
int i1=ABC.indexOf(t1.mid(0,1));
int i2=ABC.indexOf(t1.mid(1,1));
n=100*(26*i1+i2)+t1.mid(2,2).toInt();
n=1000*n + j; // pack ngrid and index j into n
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list.insert(j,n); // add n to list at [j]
}
lines2.insert(j,map[a]); // add map[a] to lines2 at [j]
j++;
}
}
if(isort>1) {
if(bReverse) {
std::sort (list.begin (), list.end (), std::greater<int> ());
} else {
std::sort (list.begin (), list.end ());
}
}
if(isort>1) {
for(i=0; i<j; i++) {
k=list[i]%1000;
n=list[i]/1000 - 100;
t += lines2.at(k) + "\n";
}
}
int nn=lines2.length();
if(isort==0) { // shuffle Hound calls to random order
int a[nn];
for(i=0; i<nn; i++) {
a[i]=i;
}
for(i=nn-1; i>-1; i--) {
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#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
j = (i + 1) * QRandomGenerator::global ()->generateDouble ();
#else
j=(i+1)*double(qrand())/RAND_MAX;
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#endif
std::swap (a[j], a[i]);
t += lines2.at(a[i]) + "\n";
}
}
int i0=t.indexOf("\n") + 1;
m_nSortedHounds=0;
if(i0 > 0) {
m_nSortedHounds=qMin(t.length(),m_Nlist*i0)/i0; // Number of sorted & displayed Hounds
}
m_houndCallers=t.mid(0,m_Nlist*i0);
return m_houndCallers;
}
//------------------------------------------------------------------------------
void MainWindow::selectHound(QString line)
{
/* Called from doubleClickOnCall() in DXpedition Fox mode.
* QString "line" is a user-selected line from left text window.
* The line may be selected by double-clicking; alternatively, hitting
* <Enter> is equivalent to double-clicking on the top-most line.
*/
if(line.length()==0) return;
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QString houndCall=line.split(" ",SkipEmptyParts).at(0);
// Don't add a call already enqueued or in QSO
if(ui->textBrowser4->toPlainText().indexOf(houndCall) >= 0) return;
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QString houndGrid=line.split(" ",SkipEmptyParts).at(1); // Hound caller's grid
QString rpt=line.split(" ",SkipEmptyParts).at(2); // Hound SNR
m_houndCallers=m_houndCallers.remove(line+"\n"); // Remove t from sorted Hound list
m_nSortedHounds--;
ui->decodedTextBrowser->setText(m_houndCallers); // Populate left window with Hound callers
QString t1=houndCall + " ";
QString t2=rpt;
if(rpt.mid(0,1) != "-" and rpt.mid(0,1) != "+") t2="+" + rpt;
if(t2.length()==2) t2=t2.mid(0,1) + "0" + t2.mid(1,1);
t1=t1.mid(0,12) + t2;
ui->textBrowser4->displayFoxToBeCalled(t1); // Add hound call and rpt to tb4
t1=t1 + " " + houndGrid; // Append the grid
m_houndQueue.enqueue(t1); // Put this hound into the queue
writeFoxQSO(" Sel: " + t1);
QTextCursor cursor = ui->textBrowser4->textCursor();
cursor.setPosition(0); // Scroll to top of list
ui->textBrowser4->setTextCursor(cursor);
}
//------------------------------------------------------------------------------
void MainWindow::houndCallers()
{
/* Called from decodeDone(), in DXpedition Fox mode. Reads decodes from file
* "houndcallers.txt", ignoring any that are not addressed to MyCall, are already
* in the stack, or with whom a QSO has been started. Others are considered to
* be Hounds eager for a QSO. We add caller information (Call, Grid, SNR, Freq,
* Distance, Age, and Continent) to a list, sort the list by specified criteria,
* and display the top N_Hounds entries in the left text window.
*/
QFile f(m_config.temp_dir().absoluteFilePath("houndcallers.txt"));
if(f.open(QIODevice::ReadOnly | QIODevice::Text)) {
QTextStream s(&f);
QString t="";
QString line,houndCall,paddedHoundCall;
m_nHoundsCalling=0;
int nTotal=0; //Total number of decoded Hounds calling Fox in 4 most recent Rx sequences
// Read and process the file of Hound callers.
while(!s.atEnd()) {
line=s.readLine();
nTotal++;
int i0=line.indexOf(" ");
houndCall=line.mid(0,i0);
paddedHoundCall=houndCall + " ";
//Don't list a hound already in the queue
if(!ui->textBrowser4->toPlainText().contains(paddedHoundCall)) {
if(m_loggedByFox[houndCall].contains(m_lastBand)) continue; //already logged on this band
if(m_foxQSO.contains(houndCall)) continue; //still in the QSO map
auto const& entity = m_logBook.countries ()->lookup (houndCall);
auto const& continent = AD1CCty::continent (entity.continent);
//If we are using a directed CQ, ignore Hound calls that do not comply.
QString CQtext=ui->comboBoxCQ->currentText();
if(CQtext.length()==5 and (continent!=CQtext.mid(3,2))) continue;
int nCallArea=-1;
if(CQtext.length()==4) {
for(int i=houndCall.length()-1; i>0; i--) {
if(houndCall.mid(i,1).toInt() > 0) nCallArea=houndCall.mid(i,1).toInt();
if(houndCall.mid(i,1)=="0") nCallArea=0;
if(nCallArea>=0) break;
}
if(nCallArea!=CQtext.mid(3,1).toInt()) continue;
}
//This houndCall passes all tests, add it to the list.
t = t + line + " " + continent + "\n";
m_nHoundsCalling++; // Number of accepted Hounds to be sorted
}
}
if(m_foxLogWindow) m_foxLogWindow->callers (nTotal);
// Sort and display accumulated list of Hound callers
if(t.length()>30) {
m_isort=ui->comboBoxHoundSort->currentIndex();
QString t1=sortHoundCalls(t,m_isort,m_max_dB);
ui->decodedTextBrowser->setText(t1);
}
f.close();
}
}
void MainWindow::foxRxSequencer(QString msg, QString houndCall, QString rptRcvd)
{
/* Called from "readFromStdOut()" to process decoded messages of the form
* "myCall houndCall R+rpt".
*
* If houndCall matches a callsign in one of our active QSO slots, we
* prepare to send "houndCall RR73" to that caller.
*/
if(m_foxQSO.contains(houndCall)) {
m_foxQSO[houndCall].rcvd=rptRcvd.mid(1); //Save report Rcvd, for the log
m_foxQSO[houndCall].tFoxRrpt=m_tFoxTx; //Save time R+rpt was received
writeFoxQSO(" Rx: " + msg.trimmed());
} else {
for(QString hc: m_foxQSO.keys()) { //Check for a matching compound call
if(hc.contains("/"+houndCall) or hc.contains(houndCall+"/")) {
m_foxQSO[hc].rcvd=rptRcvd.mid(1); //Save report Rcvd, for the log
m_foxQSO[hc].tFoxRrpt=m_tFoxTx; //Save time R+rpt was received
writeFoxQSO(" Rx: " + msg.trimmed());
}
}
}
}
void MainWindow::foxTxSequencer()
{
/* Called from guiUpdate at the point where an FT8 Fox-mode transmission
* is to be started.
*
* Determine what the Tx message(s) will be for each active slot, call
* foxgen() to generate and accumulate the corresponding waveform.
*/
qint64 now=QDateTime::currentMSecsSinceEpoch()/1000;
QStringList list1; //Up to NSlots Hound calls to be sent RR73
QStringList list2; //Up to NSlots Hound calls to be sent a report
QString fm; //Fox message to be transmitted
QString hc,hc1,hc2; //Hound calls
QString t,rpt;
qint32 islot=0;
qint32 n1,n2,n3;
m_tFoxTx++; //Increment Fox Tx cycle counter
//Is it time for a stand-alone CQ?
if(m_tFoxTxSinceCQ >= m_foxCQtime and ui->cbMoreCQs->isChecked()) {
fm=ui->comboBoxCQ->currentText() + " " + m_config.my_callsign();
if(!fm.contains("/")) {
//If Fox is not a compound callsign, add grid to the CQ message.
fm += " " + m_config.my_grid().mid(0,4);
m_fullFoxCallTime=now;
}
m_tFoxTx0=m_tFoxTx; //Remember when we sent a CQ
islot++;
foxGenWaveform(islot-1,fm);
goto Transmit;
}
//Compile list1: up to NSLots Hound calls to be sent RR73
for(QString hc: m_foxQSO.keys()) { //Check all Hound calls: First priority
if(m_foxQSO[hc].tFoxRrpt<0) continue;
if(m_foxQSO[hc].tFoxRrpt - m_foxQSO[hc].tFoxTxRR73 > 3) {
//Has been a long time since we sent RR73
list1 << hc; //Add to list1
m_foxQSO[hc].tFoxTxRR73 = m_tFoxTx; //Time RR73 is sent
m_foxQSO[hc].nRR73++; //Increment RR73 counter
if(list1.size()==m_Nslots) goto list1Done;
}
}
for(QString hc: m_foxQSO.keys()) { //Check all Hound calls: Second priority
if(m_foxQSO[hc].tFoxRrpt<0) continue;
if(m_foxQSO[hc].tFoxTxRR73 < 0) {
//Have not yet sent RR73
list1 << hc; //Add to list1
m_foxQSO[hc].tFoxTxRR73 = m_tFoxTx; //Time RR73 is sent
m_foxQSO[hc].nRR73++; //Increment RR73 counter
if(list1.size()==m_Nslots) goto list1Done;
}
}
for(QString hc: m_foxQSO.keys()) { //Check all Hound calls: Third priority
if(m_foxQSO[hc].tFoxRrpt<0) continue;
if(m_foxQSO[hc].tFoxTxRR73 <= m_foxQSO[hc].tFoxRrpt) {
//We received R+rpt more recently than we sent RR73
list1 << hc; //Add to list1
m_foxQSO[hc].tFoxTxRR73 = m_tFoxTx; //Time RR73 is sent
m_foxQSO[hc].nRR73++; //Increment RR73 counter
if(list1.size()==m_Nslots) goto list1Done;
}
}
list1Done:
//Compile list2: Up to Nslots Hound calls to be sent a report.
for(int i=0; i<m_foxQSOinProgress.count(); i++) {
//First do those for QSOs in progress
hc=m_foxQSOinProgress.at(i);
if((m_foxQSO[hc].tFoxRrpt < 0) and (m_foxQSO[hc].ncall < m_maxStrikes)) {
//Sent him a report and have not received R+rpt: call him again
list2 << hc; //Add to list2
if(list2.size()==m_Nslots) goto list2Done;
}
}
while(!m_houndQueue.isEmpty()) {
//Start QSO with a new Hound
t=m_houndQueue.dequeue(); //Fetch new hound from queue
int i0=t.indexOf(" ");
hc=t.mid(0,i0); //hound call
list2 << hc; //Add new Hound to list2
m_foxQSOinProgress.enqueue(hc); //Put him in the QSO queue
m_foxQSO[hc].grid=t.mid(16,4); //Hound grid
rpt=t.mid(12,3); //report to send Hound
m_foxQSO[hc].sent=rpt; //Report to send him
m_foxQSO[hc].ncall=0; //Start a new Hound
m_foxQSO[hc].nRR73 = 0; //Have not sent RR73
m_foxQSO[hc].rcvd = -99; //Have not received R+rpt
m_foxQSO[hc].tFoxRrpt = -1; //Have not received R+rpt
m_foxQSO[hc].tFoxTxRR73 = -1; //Have not sent RR73
rm_tb4(hc); //Remove this Hound from tb4
if(list2.size()==m_Nslots) goto list2Done;
if(m_foxQSO.count()>=2*m_Nslots) goto list2Done;
}
list2Done:
n1=list1.size();
n2=list2.size();
n3=qMax(n1,n2);
if(n3>m_Nslots) n3=m_Nslots;
for(int i=0; i<n3; i++) {
hc1="";
fm="";
if(i<n1 and i<n2) {
hc1=list1.at(i);
hc2=list2.at(i);
m_foxQSO[hc2].ncall++;
fm = Radio::base_callsign(hc1) + " RR73; " + Radio::base_callsign(hc2) +
" <" + m_config.my_callsign() + "> " + m_foxQSO[hc2].sent;
}
if(i<n1 and i>=n2) {
hc1=list1.at(i);
fm = Radio::base_callsign(hc1) + " " + m_baseCall + " RR73"; //Standard FT8 message
}
if(hc1!="") {
// Log this QSO!
auto QSO_time = QDateTime::currentDateTimeUtc ();
m_hisCall=hc1;
m_hisGrid=m_foxQSO[hc1].grid;
m_rptSent=m_foxQSO[hc1].sent;
m_rptRcvd=m_foxQSO[hc1].rcvd;
if (!m_foxLogWindow) on_fox_log_action_triggered ();
if (m_logBook.fox_log ()->add_QSO (QSO_time, m_hisCall, m_hisGrid, m_rptSent, m_rptRcvd, m_lastBand))
{
writeFoxQSO (QString {" Log: %1 %2 %3 %4 %5"}.arg (m_hisCall).arg (m_hisGrid)
.arg (m_rptSent).arg (m_rptRcvd).arg (m_lastBand));
on_logQSOButton_clicked ();
m_foxRateQueue.enqueue (now); //Add present time in seconds
//to Rate queue.
}
m_loggedByFox[hc1] += (m_lastBand + " ");
}
if(i<n2 and fm=="") {
hc2=list2.at(i);
m_foxQSO[hc2].ncall++;
fm = Radio::base_callsign(hc2) + " " + m_baseCall + " " + m_foxQSO[hc2].sent; //Standard FT8 message
}
islot++;
foxGenWaveform(islot-1,fm); //Generate tx waveform
}
if(islot < m_Nslots) {
//At least one slot is still open
if(islot==0 or ((m_tFoxTx-m_tFoxTx0>=4) and ui->cbMoreCQs->isChecked())) {
//Roughly every 4th Tx sequence, put a CQ message in an otherwise empty slot
fm=ui->comboBoxCQ->currentText() + " " + m_config.my_callsign();
if(!fm.contains("/")) {
fm += " " + m_config.my_grid().mid(0,4);
m_tFoxTx0=m_tFoxTx; //Remember when we send a CQ
m_fullFoxCallTime=now;
}
islot++;
foxGenWaveform(islot-1,fm);
}
}
Transmit:
foxcom_.nslots=islot;
foxcom_.nfreq=ui->TxFreqSpinBox->value();
if(m_config.split_mode()) foxcom_.nfreq = foxcom_.nfreq - m_XIT; //Fox Tx freq
QString foxCall=m_config.my_callsign() + " ";
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::memcpy(foxcom_.mycall, foxCall.toLatin1(),sizeof foxcom_.mycall); //Copy Fox callsign into foxcom_
foxgen_();
m_tFoxTxSinceCQ++;
for(QString hc: m_foxQSO.keys()) { //Check for strikeout or timeout
if(m_foxQSO[hc].ncall>=m_maxStrikes) m_foxQSO[hc].ncall++;
bool b1=((m_tFoxTx - m_foxQSO[hc].tFoxRrpt) > 2*m_maxFoxWait) and
(m_foxQSO[hc].tFoxRrpt > 0);
bool b2=((m_tFoxTx - m_foxQSO[hc].tFoxTxRR73) > m_maxFoxWait) and
(m_foxQSO[hc].tFoxTxRR73>0);
bool b3=(m_foxQSO[hc].ncall >= m_maxStrikes+m_maxFoxWait);
bool b4=(m_foxQSO[hc].nRR73 >= m_maxStrikes);
if(b1 or b2 or b3 or b4) {
m_foxQSO.remove(hc);
m_foxQSOinProgress.removeOne(hc);
}
}
while(!m_foxRateQueue.isEmpty()) {
qint64 age = now - m_foxRateQueue.head();
if(age < 3600) break;
m_foxRateQueue.dequeue();
}
if (m_foxLogWindow)
{
m_foxLogWindow->rate (m_foxRateQueue.size ());
m_foxLogWindow->queued (m_foxQSOinProgress.count ());
}
}
void MainWindow::rm_tb4(QString houndCall)
{
if(houndCall=="") return;
QString t="";
QString tb4=ui->textBrowser4->toPlainText();
QStringList list=tb4.split("\n");
int n=list.size();
int j=0;
for (int i=0; i<n; i++) {
if(j>0) t += "\n";
QString line=list.at(i);
if(!line.contains(houndCall + " ")) {
j++;
t += line;
}
}
t.replace("\n\n","\n");
ui->textBrowser4->setText(t);
}
void MainWindow::doubleClickOnFoxQueue(Qt::KeyboardModifiers modifiers)
{
if(modifiers==9999) return; //Silence compiler warning
QTextCursor cursor=ui->textBrowser4->textCursor();
cursor.setPosition(cursor.selectionStart());
QString houndCall=cursor.block().text().mid(0,12).trimmed();
rm_tb4(houndCall);
writeFoxQSO(" Del: " + houndCall);
QQueue<QString> tmpQueue;
while(!m_houndQueue.isEmpty()) {
QString t=m_houndQueue.dequeue();
QString hc=t.mid(0,12).trimmed();
if(hc != houndCall) tmpQueue.enqueue(t);
}
m_houndQueue.swap(tmpQueue);
}
void MainWindow::foxGenWaveform(int i,QString fm)
{
//Generate and accumulate the Tx waveform
fm += " ";
fm=fm.mid(0,40);
if(fm.mid(0,3)=="CQ ") m_tFoxTxSinceCQ=-1;
QString txModeArg;
2020-05-06 21:56:57 -04:00
txModeArg = txModeArg.asprintf("FT8fox %d",i+1);
ui->decodedTextBrowser2->displayTransmittedText(fm.trimmed(), txModeArg,
ui->TxFreqSpinBox->value()+60*i,m_bFastMode,m_TRperiod);
foxcom_.i3bit[i]=0;
if(fm.indexOf("<")>0) foxcom_.i3bit[i]=1;
strncpy(&foxcom_.cmsg[i][0],fm.toLatin1(),40); //Copy this message into cmsg[i]
if(i==0) m_fm1=fm;
QString t;
2020-05-06 21:56:57 -04:00
t = t.asprintf(" Tx%d: ",i+1);
writeFoxQSO(t + fm.trimmed());
}
void MainWindow::writeFoxQSO(QString const& msg)
{
QString t;
2020-05-06 21:56:57 -04:00
t = t.asprintf("%3d%3d%3d",m_houndQueue.count(),m_foxQSOinProgress.count(),m_foxQSO.count());
QFile f {m_config.writeable_data_dir ().absoluteFilePath ("FoxQSO.txt")};
if (f.open(QIODevice::WriteOnly | QIODevice::Text | QIODevice::Append)) {
QTextStream out(&f);
2020-06-13 11:04:41 -04:00
out << QDateTime::currentDateTimeUtc().toString("yyyy-MM-dd hh:mm:ss") << " "
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::fixed
#else
<< fixed
#endif
<< qSetRealNumberPrecision (3) << (m_freqNominal/1.e6)
<< t << msg
#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f.close();
} else {
MessageBox::warning_message (this, tr("File Open Error"),
tr("Cannot open \"%1\" for append: %2").arg(f.fileName()).arg(f.errorString()));
}
}
/*################################################################################### */
void MainWindow::foxTest()
{
QFile f("steps.txt");
if(!f.open(QIODevice::ReadOnly | QIODevice::Text)) return;
QFile fdiag("diag.txt");
if(!fdiag.open(QIODevice::WriteOnly | QIODevice::Text)) return;
QTextStream s(&f);
QTextStream sdiag(&fdiag);
QString line;
QString t;
QString msg;
QString hc1;
QString rptRcvd;
qint32 n=0;
while(!s.atEnd()) {
line=s.readLine();
if(line.length()==0) continue;
if(line.mid(0,4).toInt()==0) line=" " + line;
if(line.contains("NSlots")) {
n=line.mid(44,1).toInt();
ui->sbNslots->setValue(n);
}
if(line.contains("Sel:")) {
t=line.mid(43,6) + " " + line.mid(54,4) + " " + line.mid(50,3);
selectHound(t);
}
if(line.contains("Del:")) {
int i0=line.indexOf("Del:");
hc1=line.mid(i0+6);
int i1=hc1.indexOf(" ");
hc1=hc1.mid(0,i1);
rm_tb4(hc1);
writeFoxQSO(" Del: " + hc1);
QQueue<QString> tmpQueue;
while(!m_houndQueue.isEmpty()) {
t=m_houndQueue.dequeue();
QString hc=t.mid(0,6).trimmed();
if(hc != hc1) tmpQueue.enqueue(t);
}
m_houndQueue.swap(tmpQueue);
}
if(line.contains("Rx:")) {
msg=line.mid(43);
t=msg.mid(24);
int i0=t.indexOf(" ");
hc1=t.mid(i0+1);
int i1=hc1.indexOf(" ");
hc1=hc1.mid(0,i1);
int i2=qMax(msg.indexOf("R+"),msg.indexOf("R-"));
if(i2>20) {
rptRcvd=msg.mid(i2,4);
foxRxSequencer(msg,hc1,rptRcvd);
}
}
if(line.contains("Tx1:")) {
foxTxSequencer();
} else {
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t = t.asprintf("%3d %3d %3d %3d %5d ",m_houndQueue.count(),
m_foxQSOinProgress.count(),m_foxQSO.count(),
m_loggedByFox.count(),m_tFoxTx);
sdiag << t << line.mid(37).trimmed() << "\n";
}
}
}
void MainWindow::write_all(QString txRx, QString message)
{
QString line;
QString t;
QString msg;
QString mode_string;
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if (message.size () > 5 && message[4]==' ') {
msg=message.mid(4,-1);
} else {
msg=message.mid(6,-1);
}
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if (message.size () > 19 && message[19]=='#') {
mode_string="JT65 ";
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} else if (message.size () > 19 && message[19]=='@') {
mode_string="JT9 ";
} else {
mode_string=m_mode.leftJustified(6,' ');
}
msg=msg.mid(0,15) + msg.mid(18,-1);
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t = t.asprintf("%5d",ui->TxFreqSpinBox->value());
if (txRx=="Tx") msg=" 0 0.0" + t + " " + message;
auto time = QDateTime::currentDateTimeUtc ();
if( txRx=="Rx" ) time=m_dateTimeSeqStart;
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t = t.asprintf("%10.3f ",m_freqNominal/1.e6);
if (m_diskData) {
if (m_fileDateTime.size()==11) {
line=m_fileDateTime + " " + t + txRx + " " + mode_string + msg;
} else {
line=m_fileDateTime + t + txRx + " " + mode_string + msg;
}
} else {
line=time.toString("yyMMdd_hhmmss") + t + txRx + " " + mode_string + msg;
}
QString file_name="ALL.TXT";
if (m_mode=="WSPR") file_name="ALL_WSPR.TXT";
QFile f{m_config.writeable_data_dir().absoluteFilePath(file_name)};
if (f.open(QIODevice::WriteOnly | QIODevice::Text | QIODevice::Append)) {
QTextStream out(&f);
out << line.trimmed()
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#if QT_VERSION >= QT_VERSION_CHECK (5, 15, 0)
<< Qt::endl
#else
<< endl
#endif
;
f.close();
} else {
auto const& message2 = tr ("Cannot open \"%1\" for append: %2")
.arg (f.fileName ()).arg (f.errorString ());
QTimer::singleShot (0, [=] { // don't block guiUpdate
MessageBox::warning_message(this, tr ("Log File Error"), message2); });
}
}
void MainWindow::chkFT4()
{
if(m_mode!="FT4") return;
ui->cbAutoSeq->setEnabled(true);
ui->cbFirst->setVisible(true);
ui->cbFirst->setEnabled(true);
ui->labDXped->setVisible(m_config.special_op_id()!=SpecOp::NONE);
ui->cbFirst->setVisible(ui->cbAutoSeq->isChecked());
if (SpecOp::NONE < m_config.special_op_id () && SpecOp::FOX > m_config.special_op_id ()) {
QString t0="";
if(SpecOp::NA_VHF==m_config.special_op_id()) t0+="NA VHF";
if(SpecOp::EU_VHF==m_config.special_op_id()) t0+="EU VHF";
if(SpecOp::FIELD_DAY==m_config.special_op_id()) t0+="Field Day";
if(SpecOp::RTTY==m_config.special_op_id()) t0+="RTTY";
if(SpecOp::WW_DIGI==m_config.special_op_id()) t0+="WW_DIGI";
if(t0=="") {
ui->labDXped->setVisible(false);
} else {
ui->labDXped->setVisible(true);
ui->labDXped->setText(t0);
}
on_contest_log_action_triggered();
}
if (SpecOp::HOUND == m_config.special_op_id() or SpecOp::FOX == m_config.special_op_id()) {
ui->labDXped->setVisible(false);
}
}
void MainWindow::on_pbBestSP_clicked()
{
m_bBestSPArmed = !m_bBestSPArmed;
if(m_bBestSPArmed and !m_transmitting) ui->pbBestSP->setStyleSheet ("QPushButton{color:red}");
if(!m_bBestSPArmed) ui->pbBestSP->setStyleSheet ("");
if(m_bBestSPArmed) m_dateTimeBestSP=QDateTime::currentDateTimeUtc();
}
void MainWindow::set_mode (QString const& mode)
{
if ("FT4" == mode) on_actionFT4_triggered ();
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else if ("FST4" == mode) on_actionFST4_triggered ();
else if ("FST4W" == mode) on_actionFST4W_triggered ();
else if ("FT8" == mode) on_actionFT8_triggered ();
else if ("JT4" == mode) on_actionJT4_triggered ();
else if ("JT9" == mode) on_actionJT9_triggered ();
else if ("JT9+JT65" == mode) on_actionJT9_JT65_triggered ();
else if ("JT65" == mode) on_actionJT65_triggered ();
else if ("QRA64" == mode) on_actionQRA64_triggered ();
else if ("FreqCal" == mode) on_actionFreqCal_triggered ();
else if ("ISCAT" == mode) on_actionISCAT_triggered ();
else if ("MSK144" == mode) on_actionMSK144_triggered ();
else if ("WSPR" == mode) on_actionWSPR_triggered ();
else if ("Echo" == mode) on_actionEcho_triggered ();
}
void MainWindow::remote_configure (QString const& mode, quint32 frequency_tolerance
, QString const& submode, bool fast_mode, quint32 tr_period, quint32 rx_df
, QString const& dx_call, QString const& dx_grid, bool generate_messages)
{
if (mode.size ())
{
set_mode (mode);
}
auto is_FST4W = "FST4W" == m_mode;
if (frequency_tolerance != quint32_max && (ui->sbFtol->isVisible () || is_FST4W))
{
m_block_udp_status_updates = true;
if (is_FST4W)
{
ui->sbFST4W_FTol->setValue (frequency_tolerance);
}
else
{
ui->sbFtol->setValue (frequency_tolerance);
}
m_block_udp_status_updates = false;
}
if (submode.size () && ui->sbSubmode->isVisible ())
{
ui->sbSubmode->setValue (submode.toUpper ().at (0).toLatin1 () - 'A');
}
if (ui->cbFast9->isVisible () && ui->cbFast9->isChecked () != fast_mode)
{
ui->cbFast9->click ();
}
if (tr_period != quint32_max && ui->sbTR->isVisible ())
{
if (is_FST4W)
{
ui->sbTR_FST4W->setValue (tr_period);
ui->sbTR_FST4W->interpretText ();
}
else
{
ui->sbTR->setValue (tr_period);
ui->sbTR->interpretText ();
}
}
if (rx_df != quint32_max && ui->RxFreqSpinBox->isVisible ())
{
m_block_udp_status_updates = true;
if (is_FST4W)
{
ui->sbFST4W_RxFreq->setValue (rx_df);
ui->sbFST4W_RxFreq->interpretText ();
}
else
{
ui->RxFreqSpinBox->setValue (rx_df);
ui->RxFreqSpinBox->interpretText ();
}
m_block_udp_status_updates = false;
}
if (dx_call.size () && ui->dxCallEntry->isVisible ())
{
ui->dxCallEntry->setText (dx_call);
}
if (dx_grid.size () && ui->dxGridEntry->isVisible ())
{
ui->dxGridEntry->setText (dx_grid);
}
if (generate_messages && ui->genStdMsgsPushButton->isVisible ())
{
ui->genStdMsgsPushButton->click ();
}
if (m_config.udpWindowToFront ())
{
show ();
raise ();
activateWindow ();
}
if (m_config.udpWindowRestore () && isMinimized ())
{
showNormal ();
raise ();
}
tx_watchdog (false);
QApplication::alert (this);
}
QString MainWindow::WSPR_message()
{
QString sdBm,msg0,msg1,msg2;
sdBm = sdBm.asprintf(" %d",m_dBm);
m_tx=1-m_tx;
int i2=m_config.my_callsign().indexOf("/");
if(i2>0
|| (6 == m_config.my_grid ().size ()
&& !ui->WSPR_prefer_type_1_check_box->isChecked ())) {
if(i2<0) { // "Type 2" WSPR message
msg1=m_config.my_callsign() + " " + m_config.my_grid().mid(0,4) + sdBm;
} else {
msg1=m_config.my_callsign() + sdBm;
}
msg0="<" + m_config.my_callsign() + "> " + m_config.my_grid();
if(m_mode=="WSPR") msg0 += sdBm;
if(m_tx==0) msg2=msg0;
if(m_tx==1) msg2=msg1;
} else {
msg2=m_config.my_callsign() + " " + m_config.my_grid().mid(0,4) + sdBm; // Normal WSPR message
}
return msg2;
}