WSJT-X/HamlibTransceiver.cpp
Bill Somerville a84b7cdfd3 ------------------------------------------------------------------------
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 16:41:12 +00:00

875 lines
28 KiB
C++

#include "HamlibTransceiver.hpp"
#include <cstring>
#include <QByteArray>
#include <QString>
#include <QDebug>
#include "moc_HamlibTransceiver.cpp"
namespace
{
// Unfortunately bandwidth is conflated with mode, this is probably
// because Icom do the same. So we have to care about bandwidth if
// we want to set mode otherwise we will end up setting unwanted
// bandwidths every time we change mode. The best we can do via the
// Hamlib API is to request the normal option for the mode and hope
// that an appropriate filter is selected. Also ensure that mode is
// only set is absolutely necessary. On Icoms (and probably others)
// the filter is selected by number without checking the actual BW
// so unless the "normal" defaults are set on the rig we won't get
// desirable results.
//
// As an ultimate workaround make sure the user always has the
// option to skip mode setting altogether.
// reroute Hamlib diagnostic messages to Qt
int debug_callback (enum rig_debug_level_e level, rig_ptr_t /* arg */, char const * format, va_list ap)
{
QString message;
static char const fmt[] = "Hamlib: %s";
message = message.vsprintf (format, ap).trimmed ();
switch (level)
{
case RIG_DEBUG_BUG:
qFatal (fmt, message.toLocal8Bit ().data ());
break;
case RIG_DEBUG_ERR:
qCritical (fmt, message.toLocal8Bit ().data ());
break;
case RIG_DEBUG_WARN:
qWarning (fmt, message.toLocal8Bit ().data ());
break;
default:
qDebug (fmt, message.toLocal8Bit ().data ());
break;
}
return 0;
}
// callback function that receives transceiver capabilities from the
// hamlib libraries
int rigCallback (rig_caps const * caps, void * callback_data)
{
TransceiverFactory::Transceivers * rigs = reinterpret_cast<TransceiverFactory::Transceivers *> (callback_data);
QString key;
if (RIG_MODEL_DUMMY == caps->rig_model)
{
key = TransceiverFactory::basic_transceiver_name_;
}
else
{
key = QString::fromLatin1 (caps->mfg_name).trimmed ()
+ ' '+ QString::fromLatin1 (caps->model_name).trimmed ()
// + ' '+ QString::fromLatin1 (caps->version).trimmed ()
// + " (" + QString::fromLatin1 (rig_strstatus (caps->status)).trimmed () + ')'
;
}
auto port_type = TransceiverFactory::Capabilities::none;
switch (caps->port_type)
{
case RIG_PORT_SERIAL:
port_type = TransceiverFactory::Capabilities::serial;
break;
case RIG_PORT_NETWORK:
port_type = TransceiverFactory::Capabilities::network;
break;
default: break;
}
(*rigs)[key] = TransceiverFactory::Capabilities (caps->rig_model
, port_type
, RIG_MODEL_DUMMY != caps->rig_model
&& (RIG_PTT_RIG == caps->ptt_type
|| RIG_PTT_RIG_MICDATA == caps->ptt_type)
, RIG_PTT_RIG_MICDATA == caps->ptt_type);
return 1; // keep them coming
}
// int frequency_change_callback (RIG * /* rig */, vfo_t vfo, freq_t f, rig_ptr_t arg)
// {
// (void)vfo; // unused in release build
// Q_ASSERT (vfo == RIG_VFO_CURR); // G4WJS: at the time of writing only current VFO is signalled by hamlib
// HamlibTransceiver * transceiver (reinterpret_cast<HamlibTransceiver *> (arg));
// Q_EMIT transceiver->frequency_change (f, Transceiver::A);
// return RIG_OK;
// }
class hamlib_tx_vfo_fixup final
{
public:
hamlib_tx_vfo_fixup (RIG * rig, vfo_t tx_vfo)
: rig_ {rig}
{
original_vfo_ = rig_->state.tx_vfo;
rig_->state.tx_vfo = tx_vfo;
}
~hamlib_tx_vfo_fixup ()
{
rig_->state.tx_vfo = original_vfo_;
}
private:
RIG * rig_;
vfo_t original_vfo_;
};
}
freq_t HamlibTransceiver::dummy_frequency_;
rmode_t HamlibTransceiver::dummy_mode_ {RIG_MODE_NONE};
void HamlibTransceiver::register_transceivers (TransceiverFactory::Transceivers * registry)
{
rig_set_debug_callback (debug_callback, nullptr);
#if WSJT_HAMLIB_TRACE
#if WSJT_HAMLIB_VERBOSE_TRACE
rig_set_debug (RIG_DEBUG_TRACE);
#else
rig_set_debug (RIG_DEBUG_VERBOSE);
#endif
#elif defined (NDEBUG)
rig_set_debug (RIG_DEBUG_ERR);
#else
rig_set_debug (RIG_DEBUG_WARN);
#endif
rig_load_all_backends ();
rig_list_foreach (rigCallback, registry);
}
void HamlibTransceiver::RIGDeleter::cleanup (RIG * rig)
{
if (rig)
{
// rig->state.obj = 0;
rig_cleanup (rig);
}
}
HamlibTransceiver::HamlibTransceiver (TransceiverFactory::PTTMethod ptt_type, QString const& ptt_port)
: PollingTransceiver {0}
, rig_ {rig_init (RIG_MODEL_DUMMY)}
, back_ptt_port_ {false}
, is_dummy_ {true}
, reversed_ {false}
, split_query_works_ {true}
, get_vfo_works_ {true}
{
if (!rig_)
{
throw error {tr ("Hamlib initialisation error")};
}
switch (ptt_type)
{
case TransceiverFactory::PTT_method_VOX:
set_conf ("ptt_type", "None");
break;
case TransceiverFactory::PTT_method_CAT:
// Use the default PTT_TYPE for the rig (defined in the Hamlib
// rig back-end capabilities).
break;
case TransceiverFactory::PTT_method_DTR:
case TransceiverFactory::PTT_method_RTS:
if (!ptt_port.isEmpty ())
{
#if defined (WIN32)
set_conf ("ptt_pathname", ("\\\\.\\" + ptt_port).toLatin1 ().data ());
#else
set_conf ("ptt_pathname", ptt_port.toLatin1 ().data ());
#endif
}
if (TransceiverFactory::PTT_method_DTR == ptt_type)
{
set_conf ("ptt_type", "DTR");
}
else
{
set_conf ("ptt_type", "RTS");
}
}
}
HamlibTransceiver::HamlibTransceiver (int model_number, TransceiverFactory::ParameterPack const& params)
: PollingTransceiver {params.poll_interval}
, rig_ {rig_init (model_number)}
, back_ptt_port_ {TransceiverFactory::TX_audio_source_rear == params.audio_source}
, is_dummy_ {RIG_MODEL_DUMMY == model_number}
, reversed_ {false}
, split_query_works_ {true}
, tickle_hamlib_ {false}
, get_vfo_works_ {true}
{
if (!rig_)
{
throw error {tr ("Hamlib initialisation error")};
}
// rig_->state.obj = this;
if (RIG_MODEL_DUMMY != model_number)
{
switch (rig_->caps->port_type)
{
case RIG_PORT_SERIAL:
if (!params.serial_port.isEmpty ())
{
set_conf ("rig_pathname", params.serial_port.toLatin1 ().data ());
}
break;
case RIG_PORT_NETWORK:
if (!params.network_port.isEmpty ())
{
set_conf ("rig_pathname", params.network_port.toLatin1 ().data ());
}
break;
default:
throw error {tr ("Unsupported CAT type")};
break;
}
set_conf ("serial_speed", QByteArray::number (params.baud).data ());
set_conf ("data_bits", TransceiverFactory::seven_data_bits == params.data_bits ? "7" : "8");
set_conf ("stop_bits", TransceiverFactory::one_stop_bit == params.stop_bits ? "1" : "2");
switch (params.handshake)
{
case TransceiverFactory::handshake_none: set_conf ("serial_handshake", "None"); break;
case TransceiverFactory::handshake_XonXoff: set_conf ("serial_handshake", "XONXOFF"); break;
case TransceiverFactory::handshake_hardware: set_conf ("serial_handshake", "Hardware"); break;
}
if (params.force_line_control)
{
set_conf ("dtr_state", params.dtr_high ? "ON" : "OFF");
set_conf ("rts_state", params.rts_high ? "ON" : "OFF");
}
}
switch (params.ptt_type)
{
case TransceiverFactory::PTT_method_VOX:
set_conf ("ptt_type", "None");
break;
case TransceiverFactory::PTT_method_CAT:
// Use the default PTT_TYPE for the rig (defined in the Hamlib
// rig back-end capabilities).
break;
case TransceiverFactory::PTT_method_DTR:
case TransceiverFactory::PTT_method_RTS:
if (!params.ptt_port.isEmpty ()
&& params.ptt_port != "None"
&& (RIG_MODEL_DUMMY == model_number
|| params.ptt_port != params.serial_port))
{
#if defined (WIN32)
set_conf ("ptt_pathname", ("\\\\.\\" + params.ptt_port).toLatin1 ().data ());
#else
set_conf ("ptt_pathname", params.ptt_port.toLatin1 ().data ());
#endif
}
if (TransceiverFactory::PTT_method_DTR == params.ptt_type)
{
set_conf ("ptt_type", "DTR");
}
else
{
set_conf ("ptt_type", "RTS");
}
}
// Make Icom CAT split commands less glitchy
set_conf ("no_xchg", "1");
// would be nice to get events but not supported on Windows and also not on a lot of rigs
// rig_set_freq_callback (rig_.data (), &frequency_change_callback, this);
}
HamlibTransceiver::~HamlibTransceiver ()
{
}
void HamlibTransceiver::error_check (int ret_code, QString const& doing) const
{
if (RIG_OK != ret_code)
{
TRACE_CAT_POLL ("error:" << rigerror (ret_code));
throw error {tr ("Hamlib error: %1 while %2").arg (rigerror (ret_code)).arg (doing)};
}
}
void HamlibTransceiver::do_start ()
{
TRACE_CAT (QString::fromLatin1 (rig_->caps->mfg_name).trimmed () << QString::fromLatin1 (rig_->caps->model_name).trimmed ());
error_check (rig_open (rig_.data ()), tr ("opening connection to rig"));
// the Net rigctl back end promises all functions work but we must
// test get_vfo as it determines our strategy for Icom rigs
vfo_t vfo;
int rc = rig_get_vfo (rig_.data (), &vfo);
if (-RIG_ENAVAIL == rc || -RIG_ENIMPL == rc)
{
get_vfo_works_ = false;
}
else
{
error_check (rc, "getting current VFO");
}
if (!is_dummy_ && rig_->caps->set_split_vfo) // if split is possible
// do some extra setup
{
freq_t f1;
freq_t f2;
rmode_t m {RIG_MODE_USB};
rmode_t mb;
pbwidth_t w {RIG_PASSBAND_NORMAL};
pbwidth_t wb;
if ((!get_vfo_works_ || !rig_->caps->get_vfo)
&& (rig_->caps->set_vfo || rig_has_vfo_op (rig_.data (), RIG_OP_TOGGLE)))
{
// Icom have deficient CAT protocol with no way of reading which
// VFO is selected or if SPLIT is selected so we have to simply
// assume it is as when we started by setting at open time right
// here. We also gather/set other initial state.
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &f1), tr ("getting current frequency"));
TRACE_CAT ("current frequency =" << f1);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w), tr ("getting current mode"));
TRACE_CAT ("current mode =" << rig_strrmode (m) << "bw =" << w);
if (!rig_->caps->set_vfo)
{
TRACE_CAT ("rig_vfo_op TOGGLE");
error_check (rig_vfo_op (rig_.data (), RIG_VFO_CURR, RIG_OP_TOGGLE), tr ("exchanging VFOs"));
}
else
{
TRACE_CAT ("rig_set_vfo to other VFO");
error_check (rig_set_vfo (rig_.data (), rig_->state.vfo_list & RIG_VFO_B ? RIG_VFO_B : RIG_VFO_SUB), tr ("setting current VFO"));
}
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &f2), tr ("getting other VFO frequency"));
TRACE_CAT ("rig_get_freq other frequency =" << f2);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &mb, &wb), tr ("getting other VFO mode"));
TRACE_CAT ("rig_get_mode other mode =" << rig_strrmode (mb) << "bw =" << wb);
update_other_frequency (f2);
if (!rig_->caps->set_vfo)
{
TRACE_CAT ("rig_vfo_op TOGGLE");
error_check (rig_vfo_op (rig_.data (), RIG_VFO_CURR, RIG_OP_TOGGLE), tr ("exchanging VFOs"));
}
else
{
TRACE_CAT ("rig_set_vfo A/MAIN");
error_check (rig_set_vfo (rig_.data (), rig_->state.vfo_list & RIG_VFO_A ? RIG_VFO_A : RIG_VFO_MAIN), tr ("setting current VFO"));
}
if (f1 != f2 || m != mb || w != wb) // we must have started with MAIN/A
{
update_rx_frequency (f1);
}
else
{
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &f1), tr ("getting frequency"));
TRACE_CAT ("rig_get_freq frequency =" << f1);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w), tr ("getting mode"));
TRACE_CAT ("rig_get_mode mode =" << rig_strrmode (m) << "bw =" << w);
update_rx_frequency (f1);
}
// TRACE_CAT ("rig_set_split_vfo split off");
// error_check (rig_set_split_vfo (rig_.data (), RIG_VFO_CURR, RIG_SPLIT_OFF, RIG_VFO_CURR), tr ("setting split off"));
// update_split (false);
}
else
{
vfo_t v {RIG_VFO_A}; // assume RX always on VFO A/MAIN
if (get_vfo_works_ && rig_->caps->get_vfo)
{
error_check (rig_get_vfo (rig_.data (), &v), tr ("getting current VFO")); // has side effect of establishing current VFO inside hamlib
TRACE_CAT ("rig_get_vfo current VFO = " << rig_strvfo (v));
}
reversed_ = RIG_VFO_B == v;
if (!(rig_->caps->targetable_vfo & (RIG_TARGETABLE_MODE | RIG_TARGETABLE_PURE)))
{
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w), tr ("getting current mode"));
TRACE_CAT ("rig_get_mode current mode =" << rig_strrmode (m) << "bw =" << w);
}
}
update_mode (map_mode (m));
}
tickle_hamlib_ = true;
if (is_dummy_ && dummy_frequency_)
{
// return to where last dummy instance was
// TODO: this is going to break down if multiple dummy rigs are used
rig_set_freq (rig_.data (), RIG_VFO_CURR, dummy_frequency_);
update_rx_frequency (dummy_frequency_);
if (RIG_MODE_NONE != dummy_mode_)
{
rig_set_mode (rig_.data (), RIG_VFO_CURR, dummy_mode_, RIG_PASSBAND_NORMAL);
update_mode (map_mode (dummy_mode_));
}
}
poll ();
TRACE_CAT ("exit" << state () << "reversed =" << reversed_);
}
void HamlibTransceiver::do_stop ()
{
if (is_dummy_)
{
rig_get_freq (rig_.data (), RIG_VFO_CURR, &dummy_frequency_);
pbwidth_t width;
rig_get_mode (rig_.data (), RIG_VFO_CURR, &dummy_mode_, &width);
}
if (rig_)
{
rig_close (rig_.data ());
}
TRACE_CAT ("state:" << state () << "reversed =" << reversed_);
}
auto HamlibTransceiver::get_vfos () const -> std::tuple<vfo_t, vfo_t>
{
if (get_vfo_works_ && rig_->caps->get_vfo)
{
vfo_t v;
error_check (rig_get_vfo (rig_.data (), &v), tr ("getting current VFO")); // has side effect of establishing current VFO inside hamlib
TRACE_CAT ("rig_get_vfo VFO = " << rig_strvfo (v));
reversed_ = RIG_VFO_B == v;
}
else if (rig_->caps->set_vfo && rig_->caps->set_split_vfo)
{
// use VFO A/MAIN for main frequency and B/SUB for Tx
// frequency if split since these type of radios can only
// support this way around
TRACE_CAT ("rig_set_vfo VFO = A/MAIN");
error_check (rig_set_vfo (rig_.data (), rig_->state.vfo_list & RIG_VFO_A ? RIG_VFO_A : RIG_VFO_MAIN), tr ("setting current VFO"));
}
// else only toggle available but both VFOs should be substitutable
auto rx_vfo = rig_->state.vfo_list & RIG_VFO_A ? RIG_VFO_A : RIG_VFO_MAIN;
auto tx_vfo = !is_dummy_ && state ().split ()
? (rig_->state.vfo_list & RIG_VFO_B ? RIG_VFO_B : RIG_VFO_SUB)
: rx_vfo;
if (reversed_)
{
TRACE_CAT ("reversing VFOs");
std::swap (rx_vfo, tx_vfo);
}
TRACE_CAT ("RX VFO = " << rig_strvfo (rx_vfo) << " TX VFO = " << rig_strvfo (tx_vfo));
return std::make_tuple (rx_vfo, tx_vfo);
}
void HamlibTransceiver::do_frequency (Frequency f, MODE m)
{
TRACE_CAT (f << "mode:" << m << "reversed:" << reversed_);
// for the 1st time as a band change may cause a recalled mode to be
// set
error_check (rig_set_freq (rig_.data (), RIG_VFO_CURR, f), tr ("setting frequency"));
if (UNK != m)
{
do_mode (m, false);
// for the 2nd time because a mode change may have caused a
// frequency change
error_check (rig_set_freq (rig_.data (), RIG_VFO_CURR, f), tr ("setting frequency"));
// for the second time because some rigs change mode according
// to frequency such as the TS-2000 auto mode setting
do_mode (m, false);
}
update_rx_frequency (f);
}
void HamlibTransceiver::do_tx_frequency (Frequency tx, bool rationalise_mode)
{
TRACE_CAT (tx << "rationalise mode:" << rationalise_mode << "reversed:" << reversed_);
if (!is_dummy_) // split is meaning less if you can't
// see it
{
auto split = tx ? RIG_SPLIT_ON : RIG_SPLIT_OFF;
update_split (tx);
auto vfos = get_vfos ();
// auto rx_vfo = std::get<0> (vfos); // or use RIG_VFO_CURR
auto tx_vfo = std::get<1> (vfos);
if (tx)
{
// Doing set split for the 1st of two times, this one
// ensures that the internal Hamlib state is correct
// otherwise rig_set_split_freq() will target the wrong VFO
// on some rigs
if (tickle_hamlib_)
{
// This potentially causes issues with the Elecraft K3
// which will block setting split mode when it deems
// cross mode split operation not possible. There's not
// much we can do since the Hamlib Library needs this
// call at least once to establish the Tx VFO. Best we
// can do is only do this once per session.
TRACE_CAT ("rig_set_split_vfo split =" << split);
auto rc = rig_set_split_vfo (rig_.data (), RIG_VFO_CURR, split, tx_vfo);
if (tx || (-RIG_ENAVAIL != rc && -RIG_ENIMPL != rc))
{
// On rigs that can't have split controlled only throw an
// exception when an error other than command not accepted
// is returned when trying to leave split mode. This allows
// fake split mode and non-split mode to work without error
// on such rigs without having to know anything about the
// specific rig.
error_check (rc, tr ("setting/unsetting split mode"));
}
tickle_hamlib_ = false;
}
hamlib_tx_vfo_fixup fixup (rig_.data (), tx_vfo);
// do this before setting the mode because changing band may
// recall the last mode used on the target band
error_check (rig_set_split_freq (rig_.data (), RIG_VFO_CURR, tx), tr ("setting split TX frequency"));
if (rationalise_mode)
{
rmode_t current_mode;
pbwidth_t current_width;
error_check (rig_get_split_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting mode of split TX VFO"));
TRACE_CAT ("rig_get_split_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
auto new_mode = map_mode (state ().mode ());
if (new_mode != current_mode)
{
TRACE_CAT ("rig_set_split_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_split_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NORMAL), tr ("setting split TX VFO mode"));
// do this again as setting the mode may change the frequency
error_check (rig_set_split_freq (rig_.data (), RIG_VFO_CURR, tx), tr ("setting split TX frequency"));
}
}
}
// Enable split last since some rigs (Kenwood for one) come out
// of split when you switch RX VFO (to set split mode above for
// example). Also the Elecraft K3 will refuse to go to split
// with certain VFO A/B mode combinations.
TRACE_CAT ("rig_set_split_vfo split =" << split);
auto rc = rig_set_split_vfo (rig_.data (), RIG_VFO_CURR, split, tx_vfo);
if (tx || (-RIG_ENAVAIL != rc && -RIG_ENIMPL != rc))
{
// On rigs that can't have split controlled only throw an
// exception when an error other than command not accepted
// is returned when trying to leave split mode. This allows
// fake split mode and non-split mode to work without error
// on such rigs without having to know anything about the
// specific rig.
error_check (rc, tr ("setting/unsetting split mode"));
}
update_other_frequency (tx);
}
}
void HamlibTransceiver::do_mode (MODE mode, bool rationalise)
{
TRACE_CAT (mode << "rationalise:" << rationalise);
auto vfos = get_vfos ();
// auto rx_vfo = std::get<0> (vfos);
auto tx_vfo = std::get<1> (vfos);
rmode_t current_mode;
pbwidth_t current_width;
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting current VFO mode"));
TRACE_CAT ("rig_get_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
auto new_mode = map_mode (mode);
if (new_mode != current_mode)
{
TRACE_CAT ("rig_set_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NORMAL), tr ("setting current VFO mode"));
}
if (!is_dummy_ && state ().split () && rationalise)
{
error_check (rig_get_split_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting split TX VFO mode"));
TRACE_CAT ("rig_get_split_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
if (new_mode != current_mode)
{
TRACE_CAT ("rig_set_split_mode mode = " << rig_strrmode (new_mode));
hamlib_tx_vfo_fixup fixup (rig_.data (), tx_vfo);
error_check (rig_set_split_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NORMAL), tr ("setting split TX VFO mode"));
}
}
update_mode (mode);
}
void HamlibTransceiver::poll ()
{
#if !WSJT_TRACE_CAT_POLLS
#if defined (NDEBUG)
rig_set_debug (RIG_DEBUG_ERR);
#else
rig_set_debug (RIG_DEBUG_WARN);
#endif
#endif
freq_t f;
rmode_t m;
pbwidth_t w;
split_t s;
if (get_vfo_works_ && rig_->caps->get_vfo)
{
vfo_t v;
error_check (rig_get_vfo (rig_.data (), &v), tr ("getting current VFO")); // has side effect of establishing current VFO inside hamlib
TRACE_CAT_POLL ("VFO =" << rig_strvfo (v));
reversed_ = RIG_VFO_B == v;
}
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &f), tr ("getting current VFO frequency"));
TRACE_CAT_POLL ("rig_get_freq frequency =" << f);
update_rx_frequency (f);
if (!is_dummy_ && state ().split () && (rig_->caps->targetable_vfo & (RIG_TARGETABLE_FREQ | RIG_TARGETABLE_PURE)))
{
// only read "other" VFO if in split, this allows rigs like
// FlexRadio to work in Kenwood TS-2000 mode despite them
// not having a FB; command
// we can only probe current VFO unless rig supports reading
// the other one directly because we can't glitch the Rx
error_check (rig_get_freq (rig_.data ()
, reversed_
? (rig_->state.vfo_list & RIG_VFO_A ? RIG_VFO_A : RIG_VFO_MAIN)
: (rig_->state.vfo_list & RIG_VFO_B ? RIG_VFO_B : RIG_VFO_SUB)
, &f), tr ("getting current VFO frequency"));
TRACE_CAT_POLL ("rig_get_freq other VFO =" << f);
update_other_frequency (f);
}
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w), tr ("getting current VFO mode"));
TRACE_CAT_POLL ("rig_get_mode mode =" << rig_strrmode (m) << "bw =" << w);
update_mode (map_mode (m));
if (!is_dummy_ && rig_->caps->get_split_vfo && split_query_works_)
{
vfo_t v {RIG_VFO_NONE}; // so we can tell if it doesn't get updated :(
auto rc = rig_get_split_vfo (rig_.data (), RIG_VFO_CURR, &s, &v);
if (-RIG_OK == rc && RIG_SPLIT_ON == s)
{
TRACE_CAT_POLL ("rig_get_split_vfo split = " << s << " VFO = " << rig_strvfo (v));
update_split (true);
// if (RIG_VFO_A == v)
// {
// reversed_ = true; // not sure if this helps us here
// }
}
else if (-RIG_OK == rc) // not split
{
TRACE_CAT_POLL ("rig_get_split_vfo split = " << s << " VFO = " << rig_strvfo (v));
update_split (false);
}
else
{
// Some rigs (Icom) don't have a way of reporting SPLIT
// mode
TRACE_CAT_POLL ("rig_get_split_vfo can't do on this rig");
// just report how we see it based on prior commands
split_query_works_ = false;
}
}
if (RIG_PTT_NONE != rig_->state.pttport.type.ptt && rig_->caps->get_ptt)
{
ptt_t p;
auto rc = rig_get_ptt (rig_.data (), RIG_VFO_CURR, &p);
if (-RIG_ENAVAIL != rc && -RIG_ENIMPL != rc) // may fail if
// Net rig ctl and target doesn't
// support command
{
error_check (rc, tr ("getting PTT state"));
TRACE_CAT_POLL ("rig_get_ptt PTT =" << p);
update_PTT (!(RIG_PTT_OFF == p));
}
}
#if !WSJT_TRACE_CAT_POLLS
#if WSJT_HAMLIB_TRACE
#if WSJT_HAMLIB_VERBOSE_TRACE
rig_set_debug (RIG_DEBUG_TRACE);
#else
rig_set_debug (RIG_DEBUG_VERBOSE);
#endif
#elif defined (NDEBUG)
rig_set_debug (RIG_DEBUG_ERR);
#else
rig_set_debug (RIG_DEBUG_WARN);
#endif
#endif
}
void HamlibTransceiver::do_ptt (bool on)
{
TRACE_CAT (on << state () << "reversed =" << reversed_);
if (on)
{
if (RIG_PTT_NONE != rig_->state.pttport.type.ptt)
{
TRACE_CAT ("rig_set_ptt PTT = true");
error_check (rig_set_ptt (rig_.data (), RIG_VFO_CURR
, RIG_PTT_RIG_MICDATA == rig_->caps->ptt_type && back_ptt_port_
? RIG_PTT_ON_DATA : RIG_PTT_ON), tr ("setting PTT on"));
}
}
else
{
if (RIG_PTT_NONE != rig_->state.pttport.type.ptt)
{
TRACE_CAT ("rig_set_ptt PTT = false");
error_check (rig_set_ptt (rig_.data (), RIG_VFO_CURR, RIG_PTT_OFF), tr ("setting PTT off"));
}
}
update_PTT (on);
}
void HamlibTransceiver::set_conf (char const * item, char const * value)
{
token_t token = rig_token_lookup (rig_.data (), item);
if (RIG_CONF_END != token) // only set if valid for rig model
{
error_check (rig_set_conf (rig_.data (), token, value), tr ("setting a configuration item"));
}
}
QByteArray HamlibTransceiver::get_conf (char const * item)
{
token_t token = rig_token_lookup (rig_.data (), item);
QByteArray value {128, '\0'};
if (RIG_CONF_END != token) // only get if valid for rig model
{
error_check (rig_get_conf (rig_.data (), token, value.data ()), tr ("getting a configuration item"));
}
return value;
}
auto HamlibTransceiver::map_mode (rmode_t m) const -> MODE
{
switch (m)
{
case RIG_MODE_AM:
case RIG_MODE_SAM:
case RIG_MODE_AMS:
case RIG_MODE_DSB:
return AM;
case RIG_MODE_CW:
return CW;
case RIG_MODE_CWR:
return CW_R;
case RIG_MODE_USB:
case RIG_MODE_ECSSUSB:
case RIG_MODE_SAH:
case RIG_MODE_FAX:
return USB;
case RIG_MODE_LSB:
case RIG_MODE_ECSSLSB:
case RIG_MODE_SAL:
return LSB;
case RIG_MODE_RTTY:
return FSK;
case RIG_MODE_RTTYR:
return FSK_R;
case RIG_MODE_PKTLSB:
return DIG_L;
case RIG_MODE_PKTUSB:
return DIG_U;
case RIG_MODE_FM:
case RIG_MODE_WFM:
return FM;
case RIG_MODE_PKTFM:
return DIG_FM;
default:
return UNK;
}
}
rmode_t HamlibTransceiver::map_mode (MODE mode) const
{
switch (mode)
{
case AM: return RIG_MODE_AM;
case CW: return RIG_MODE_CW;
case CW_R: return RIG_MODE_CWR;
case USB: return RIG_MODE_USB;
case LSB: return RIG_MODE_LSB;
case FSK: return RIG_MODE_RTTY;
case FSK_R: return RIG_MODE_RTTYR;
case DIG_L: return RIG_MODE_PKTLSB;
case DIG_U: return RIG_MODE_PKTUSB;
case FM: return RIG_MODE_FM;
case DIG_FM: return RIG_MODE_PKTFM;
default: break;
}
return RIG_MODE_USB; // quieten compiler grumble
}