WSJT-X/Transceiver/HamlibTransceiver.cpp
2019-07-02 10:19:43 -05:00

1152 lines
41 KiB
C++

#include "HamlibTransceiver.hpp"
#include <cstring>
#include <cmath>
#include <QByteArray>
#include <QString>
#include <QStandardPaths>
#include <QFile>
#include <QJsonDocument>
#include <QJsonObject>
#include <QJsonValue>
#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 constexpr 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 register_callback (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;
case RIG_PORT_USB:
port_type = TransceiverFactory::Capabilities::usb;
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 unregister_callback (rig_caps const * caps, void *)
{
rig_unregister (caps->rig_model);
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 (register_callback, registry);
}
void HamlibTransceiver::unregister_transceivers ()
{
rig_list_foreach (unregister_callback, nullptr);
}
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,
QObject * parent)
: PollingTransceiver {0, parent}
, rig_ {rig_init (RIG_MODEL_DUMMY)}
, back_ptt_port_ {false}
, one_VFO_ {false}
, is_dummy_ {true}
, reversed_ {false}
, freq_query_works_ {true}
, mode_query_works_ {true}
, split_query_works_ {true}
, tickle_hamlib_ {false}
, get_vfo_works_ {true}
, set_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,
QObject * parent)
: PollingTransceiver {params.poll_interval, parent}
, rig_ {rig_init (model_number)}
, back_ptt_port_ {TransceiverFactory::TX_audio_source_rear == params.audio_source}
, one_VFO_ {false}
, is_dummy_ {RIG_MODEL_DUMMY == model_number}
, reversed_ {false}
, freq_query_works_ {rig_ && rig_->caps->get_freq}
, mode_query_works_ {rig_ && rig_->caps->get_mode}
, split_query_works_ {rig_ && rig_->caps->get_split_vfo}
, tickle_hamlib_ {false}
, get_vfo_works_ {true}
, set_vfo_works_ {true}
{
if (!rig_)
{
throw error {tr ("Hamlib initialisation error")};
}
// rig_->state.obj = this;
if (!is_dummy_)
{
//
// user defined Hamlib settings
//
auto settings_file_name = QStandardPaths::locate (QStandardPaths::AppConfigLocation
, "hamlib_settings.json");
if (!settings_file_name.isEmpty ())
{
QFile settings_file {settings_file_name};
qDebug () << "Using Hamlib settings file:" << settings_file_name;
if (settings_file.open (QFile::ReadOnly))
{
QJsonParseError status;
auto settings_doc = QJsonDocument::fromJson (settings_file.readAll (), &status);
if (status.error)
{
throw error {tr ("Hamlib settings file error: %1 at character offset %2")
.arg (status.errorString ()).arg (status.offset)};
}
qDebug () << "Hamlib settings JSON:" << settings_doc.toJson ();
if (!settings_doc.isObject ())
{
throw error {tr ("Hamlib settings file error: top level must be a JSON object")};
}
auto const& settings = settings_doc.object ();
//
// configuration settings
//
auto const& config = settings["config"];
if (!config.isUndefined ())
{
if (!config.isObject ())
{
throw error {tr ("Hamlib settings file error: config must be a JSON object")};
}
auto const& config_list = config.toObject ();
for (auto item = config_list.constBegin (); item != config_list.constEnd (); ++item)
{
set_conf (item.key ().toLocal8Bit ().constData ()
, (*item).toVariant ().toString ().toLocal8Bit ().constData ());
}
}
}
}
switch (rig_->caps->port_type)
{
case RIG_PORT_SERIAL:
if (!params.serial_port.isEmpty ())
{
set_conf ("rig_pathname", params.serial_port.toLatin1 ().data ());
}
set_conf ("serial_speed", QByteArray::number (params.baud).data ());
if (params.data_bits != TransceiverFactory::default_data_bits)
{
set_conf ("data_bits", TransceiverFactory::seven_data_bits == params.data_bits ? "7" : "8");
}
if (params.stop_bits != TransceiverFactory::default_stop_bits)
{
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;
default: break;
}
if (params.force_dtr)
{
set_conf ("dtr_state", params.dtr_high ? "ON" : "OFF");
}
if (params.force_rts)
{
if (TransceiverFactory::handshake_hardware != params.handshake)
{
set_conf ("rts_state", params.rts_high ? "ON" : "OFF");
}
}
break;
case RIG_PORT_NETWORK:
if (!params.network_port.isEmpty ())
{
set_conf ("rig_pathname", params.network_port.toLatin1 ().data ());
}
break;
case RIG_PORT_USB:
if (!params.usb_port.isEmpty ())
{
set_conf ("rig_pathname", params.usb_port.toLatin1 ().data ());
}
break;
default:
throw error {tr ("Unsupported CAT type")};
break;
}
}
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"
&& (is_dummy_ || 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);
}
void HamlibTransceiver::error_check (int ret_code, QString const& doing) const
{
if (RIG_OK != ret_code)
{
TRACE_CAT_POLL ("HamlibTransceiver", "error:" << rigerror (ret_code));
throw error {tr ("Hamlib error: %1 while %2").arg (rigerror (ret_code)).arg (doing)};
}
}
int HamlibTransceiver::do_start ()
{
TRACE_CAT ("HamlibTransceiver",
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"));
// reset dynamic state
one_VFO_ = false;
reversed_ = false;
freq_query_works_ = rig_->caps->get_freq;
mode_query_works_ = rig_->caps->get_mode;
split_query_works_ = rig_->caps->get_split_vfo;
tickle_hamlib_ = false;
get_vfo_works_ = true;
set_vfo_works_ = true;
// 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;
// determine if the rig uses single VFO addressing i.e. A/B and
// no get_vfo function
if (rig_->state.vfo_list & RIG_VFO_B)
{
one_VFO_ = true;
}
}
else
{
error_check (rc, "testing getting current VFO");
}
if ((WSJT_RIG_NONE_CAN_SPLIT || !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 (freq_query_works_
&& (!get_vfo_works_ || !rig_->caps->get_vfo))
{
// 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"));
f1 = std::round (f1);
TRACE_CAT ("HamlibTransceiver", "current frequency =" << f1);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w), tr ("getting current mode"));
TRACE_CAT ("HamlibTransceiver", "current mode =" << rig_strrmode (m) << "bw =" << w);
if (!rig_->caps->set_vfo)
{
TRACE_CAT ("HamlibTransceiver", "rig_vfo_op TOGGLE");
rc = rig_vfo_op (rig_.data (), RIG_VFO_CURR, RIG_OP_TOGGLE);
}
else
{
TRACE_CAT ("HamlibTransceiver", "rig_set_vfo to other VFO");
rc = rig_set_vfo (rig_.data (), rig_->state.vfo_list & RIG_VFO_B ? RIG_VFO_B : RIG_VFO_SUB);
if (-RIG_ENAVAIL == rc || -RIG_ENIMPL == rc)
{
// if we are talking to netrigctl then toggle VFO op
// may still work
TRACE_CAT ("HamlibTransceiver", "rig_vfo_op TOGGLE");
rc = rig_vfo_op (rig_.data (), RIG_VFO_CURR, RIG_OP_TOGGLE);
}
}
if (-RIG_ENAVAIL == rc || -RIG_ENIMPL == rc)
{
// we are probably dealing with rigctld so we do not
// have completely accurate rig capabilities
set_vfo_works_ = false;
one_VFO_ = false; // we do not need single VFO addressing
}
else
{
error_check (rc, tr ("exchanging VFOs"));
}
if (set_vfo_works_)
{
// without the above we cannot proceed but we know we
// are on VFO A and that will not change so there's no
// need to execute this block
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &f2), tr ("getting other VFO frequency"));
f2 = std::round (f2);
TRACE_CAT ("HamlibTransceiver", "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 ("HamlibTransceiver", "rig_get_mode other mode =" << rig_strrmode (mb) << "bw =" << wb);
update_other_frequency (f2);
if (!rig_->caps->set_vfo)
{
TRACE_CAT ("HamlibTransceiver", "rig_vfo_op TOGGLE");
error_check (rig_vfo_op (rig_.data (), RIG_VFO_CURR, RIG_OP_TOGGLE), tr ("exchanging VFOs"));
}
else
{
TRACE_CAT ("HamlibTransceiver", "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"));
f1 = std::round (f1);
TRACE_CAT ("HamlibTransceiver", "rig_get_freq frequency =" << f1);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w), tr ("getting mode"));
TRACE_CAT ("HamlibTransceiver", "rig_get_mode mode =" << rig_strrmode (m) << "bw =" << w);
update_rx_frequency (f1);
}
}
// TRACE_CAT ("HamlibTransceiver", "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 ("HamlibTransceiver", "rig_get_vfo current VFO = " << rig_strvfo (v));
}
reversed_ = RIG_VFO_B == v;
if (mode_query_works_ && !(rig_->caps->targetable_vfo & (RIG_TARGETABLE_MODE | RIG_TARGETABLE_PURE)))
{
if (RIG_OK == rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w))
{
TRACE_CAT ("HamlibTransceiver", "rig_get_mode current mode =" << rig_strrmode (m) << "bw =" << w);
}
else
{
mode_query_works_ = false;
// Some rigs (HDSDR) don't have a working way of
// reporting MODE so we give up on mode queries -
// sets will still cause an error
TRACE_CAT ("HamlibTransceiver", "rig_get_mode can't do on this rig");
}
}
}
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_NOCHANGE);
update_mode (map_mode (dummy_mode_));
}
}
int resolution {0};
if (freq_query_works_)
{
freq_t current_frequency;
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &current_frequency), tr ("getting current VFO frequency"));
current_frequency = std::round (current_frequency);
Frequency f = current_frequency;
if (f && !(f % 10))
{
auto test_frequency = f - f % 100 + 55;
error_check (rig_set_freq (rig_.data (), RIG_VFO_CURR, test_frequency), tr ("setting frequency"));
freq_t new_frequency;
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &new_frequency), tr ("getting current VFO frequency"));
new_frequency = std::round (new_frequency);
switch (static_cast<Radio::FrequencyDelta> (new_frequency - test_frequency))
{
case -5: resolution = -1; break; // 10Hz truncated
case 5: resolution = 1; break; // 10Hz rounded
case -15: resolution = -2; break; // 20Hz truncated
case -55: resolution = -3; break; // 100Hz truncated
case 45: resolution = 3; break; // 100Hz rounded
}
if (1 == resolution) // may be 20Hz rounded
{
test_frequency = f - f % 100 + 51;
error_check (rig_set_freq (rig_.data (), RIG_VFO_CURR, test_frequency), tr ("setting frequency"));
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &new_frequency), tr ("getting current VFO frequency"));
if (9 == static_cast<Radio::FrequencyDelta> (new_frequency - test_frequency))
{
resolution = 2; // 20Hz rounded
}
}
error_check (rig_set_freq (rig_.data (), RIG_VFO_CURR, current_frequency), tr ("setting frequency"));
}
}
else
{
resolution = -1; // best guess
}
do_poll ();
TRACE_CAT ("HamlibTransceiver", "exit" << state () << "reversed =" << reversed_ << "resolution = " << resolution);
return resolution;
}
void HamlibTransceiver::do_stop ()
{
if (is_dummy_)
{
rig_get_freq (rig_.data (), RIG_VFO_CURR, &dummy_frequency_);
dummy_frequency_ = std::round (dummy_frequency_);
if (mode_query_works_)
{
pbwidth_t width;
rig_get_mode (rig_.data (), RIG_VFO_CURR, &dummy_mode_, &width);
}
}
if (rig_)
{
rig_close (rig_.data ());
}
TRACE_CAT ("HamlibTransceiver", "state:" << state () << "reversed =" << reversed_);
}
auto HamlibTransceiver::get_vfos (bool for_split) 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 ("HamlibTransceiver", "rig_get_vfo VFO = " << rig_strvfo (v));
reversed_ = RIG_VFO_B == v;
}
else if (!for_split && set_vfo_works_ && 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 ("HamlibTransceiver", "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 VFOs should be substitutable
auto rx_vfo = rig_->state.vfo_list & RIG_VFO_A ? RIG_VFO_A : RIG_VFO_MAIN;
auto tx_vfo = (WSJT_RIG_NONE_CAN_SPLIT || !is_dummy_) && for_split
? (rig_->state.vfo_list & RIG_VFO_B ? RIG_VFO_B : RIG_VFO_SUB)
: rx_vfo;
if (reversed_)
{
TRACE_CAT ("HamlibTransceiver", "reversing VFOs");
std::swap (rx_vfo, tx_vfo);
}
TRACE_CAT ("HamlibTransceiver", "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, bool no_ignore)
{
TRACE_CAT ("HamlibTransceiver", f << "mode:" << m << "reversed:" << reversed_);
// only change when receiving or simplex or direct VFO addressing
// unavailable or forced
if (!state ().ptt () || !state ().split () || !one_VFO_ || no_ignore)
{
// 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"));
update_rx_frequency (f);
if (mode_query_works_ && UNK != m)
{
rmode_t current_mode;
pbwidth_t current_width;
auto new_mode = map_mode (m);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting current VFO mode"));
TRACE_CAT ("HamlibTransceiver", "rig_get_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
if (new_mode != current_mode)
{
TRACE_CAT ("HamlibTransceiver", "rig_set_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NOCHANGE), tr ("setting current VFO mode"));
// 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
TRACE_CAT ("HamlibTransceiver", "rig_set_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NOCHANGE), tr ("setting current VFO mode"));
}
update_mode (m);
}
}
}
void HamlibTransceiver::do_tx_frequency (Frequency tx, MODE mode, bool no_ignore)
{
TRACE_CAT ("HamlibTransceiver", tx << "reversed:" << reversed_);
if (WSJT_RIG_NONE_CAN_SPLIT || !is_dummy_) // split is meaningless if you can't see it
{
auto split = tx ? RIG_SPLIT_ON : RIG_SPLIT_OFF;
auto vfos = get_vfos (tx);
// 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 ("HamlibTransceiver", "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;
update_split (tx);
}
// just change current when transmitting with single VFO
// addressing
if (state ().ptt () && one_VFO_)
{
TRACE_CAT ("HamlibTransceiver", "rig_set_split_vfo split =" << split);
error_check (rig_set_split_vfo (rig_.data (), RIG_VFO_CURR, split, tx_vfo), tr ("setting split mode"));
error_check (rig_set_freq (rig_.data (), RIG_VFO_CURR, tx), tr ("setting frequency"));
if (UNK != mode && mode_query_works_)
{
rmode_t current_mode;
pbwidth_t current_width;
auto new_mode = map_mode (mode);
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting current VFO mode"));
TRACE_CAT ("HamlibTransceiver", "rig_get_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
if (new_mode != current_mode)
{
TRACE_CAT ("HamlibTransceiver", "rig_set_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NOCHANGE), tr ("setting current VFO mode"));
}
}
update_other_frequency (tx);
}
else if (!one_VFO_ || no_ignore) // if not single VFO addressing and not forced
{
hamlib_tx_vfo_fixup fixup (rig_.data (), tx_vfo);
if (UNK != mode)
{
auto new_mode = map_mode (mode);
TRACE_CAT ("HamlibTransceiver", "rig_set_split_freq_mode freq = " << tx
<< " mode = " << rig_strrmode (new_mode));
error_check (rig_set_split_freq_mode (rig_.data (), RIG_VFO_CURR, tx, new_mode, RIG_PASSBAND_NOCHANGE), tr ("setting split TX frequency and mode"));
}
else
{
TRACE_CAT ("HamlibTransceiver", "rig_set_split_freq freq = " << tx);
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 ("HamlibTransceiver", "rig_set_split_vfo split =" << split);
error_check (rig_set_split_vfo (rig_.data (), RIG_VFO_CURR, split, tx_vfo), tr ("setting split mode"));
update_other_frequency (tx);
update_split (tx);
}
}
else
{
// Disable split
TRACE_CAT ("HamlibTransceiver", "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);
update_split (tx);
}
}
}
void HamlibTransceiver::do_mode (MODE mode)
{
TRACE_CAT ("HamlibTransceiver", mode);
auto vfos = get_vfos (state ().split ());
// auto rx_vfo = std::get<0> (vfos);
auto tx_vfo = std::get<1> (vfos);
rmode_t current_mode;
pbwidth_t current_width;
auto new_mode = map_mode (mode);
// only change when receiving or simplex if direct VFO addressing unavailable
if (!(state ().ptt () && state ().split () && one_VFO_))
{
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting current VFO mode"));
TRACE_CAT ("HamlibTransceiver", "rig_get_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
if (new_mode != current_mode)
{
TRACE_CAT ("HamlibTransceiver", "rig_set_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NOCHANGE), tr ("setting current VFO mode"));
}
}
// just change current when transmitting split with one VFO mode
if (state ().ptt () && state ().split () && one_VFO_)
{
error_check (rig_get_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting current VFO mode"));
TRACE_CAT ("HamlibTransceiver", "rig_get_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
if (new_mode != current_mode)
{
TRACE_CAT ("HamlibTransceiver", "rig_set_mode mode = " << rig_strrmode (new_mode));
error_check (rig_set_mode (rig_.data (), RIG_VFO_CURR, new_mode, RIG_PASSBAND_NOCHANGE), tr ("setting current VFO mode"));
}
}
else if (state ().split () && !one_VFO_)
{
error_check (rig_get_split_mode (rig_.data (), RIG_VFO_CURR, &current_mode, &current_width), tr ("getting split TX VFO mode"));
TRACE_CAT ("HamlibTransceiver", "rig_get_split_mode mode = " << rig_strrmode (current_mode) << "bw =" << current_width);
if (new_mode != current_mode)
{
TRACE_CAT ("HamlibTransceiver", "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_NOCHANGE), tr ("setting split TX VFO mode"));
}
}
update_mode (mode);
}
void HamlibTransceiver::do_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 ("HamlibTransceiver", "VFO =" << rig_strvfo (v));
reversed_ = RIG_VFO_B == v;
}
if ((WSJT_RIG_NONE_CAN_SPLIT || !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 ("HamlibTransceiver", "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 ("HamlibTransceiver", "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 ("HamlibTransceiver", "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 (freq_query_works_)
{
// only read if possible and when receiving or simplex
if (!state ().ptt () || !state ().split ())
{
error_check (rig_get_freq (rig_.data (), RIG_VFO_CURR, &f), tr ("getting current VFO frequency"));
f = std::round (f);
TRACE_CAT_POLL ("HamlibTransceiver", "rig_get_freq frequency =" << f);
update_rx_frequency (f);
}
if ((WSJT_RIG_NONE_CAN_SPLIT || !is_dummy_)
&& state ().split ()
&& (rig_->caps->targetable_vfo & (RIG_TARGETABLE_FREQ | RIG_TARGETABLE_PURE))
&& !one_VFO_)
{
// 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 other VFO frequency"));
f = std::round (f);
TRACE_CAT_POLL ("HamlibTransceiver", "rig_get_freq other VFO =" << f);
update_other_frequency (f);
}
}
// only read when receiving or simplex if direct VFO addressing unavailable
if ((!state ().ptt () || !state ().split ())
&& mode_query_works_)
{
// We have to ignore errors here because Yaesu FTdx... rigs can
// report the wrong mode when transmitting split with different
// modes per VFO. This is unfortunate because that is exactly
// what you need to do to get 4kHz Rx b.w and modulation into
// the rig through the data socket or USB. I.e. USB for Rx and
// DATA-USB for Tx.
auto rc = rig_get_mode (rig_.data (), RIG_VFO_CURR, &m, &w);
if (RIG_OK == rc)
{
TRACE_CAT_POLL ("HamlibTransceiver", "rig_get_mode mode =" << rig_strrmode (m) << "bw =" << w);
update_mode (map_mode (m));
}
else
{
TRACE_CAT_POLL ("HamlibTransceiver", "rig_get_mode mode failed with rc:" << rc << "ignoring");
}
}
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 ("HamlibTransceiver", "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 ("HamlibTransceiver", on << state () << "reversed =" << reversed_);
if (on)
{
if (RIG_PTT_NONE != rig_->state.pttport.type.ptt)
{
TRACE_CAT ("HamlibTransceiver", "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 ("HamlibTransceiver", "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
}