/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2019 Edouard Griffiths, F4EXB // // // // This program is free software; you can redistribute it and/or modify // // it under the terms of the GNU General Public License as published by // // the Free Software Foundation as version 3 of the License, or // // (at your option) any later version. // // // // This program is distributed in the hope that it will be useful, // // but WITHOUT ANY WARRANTY; without even the implied warranty of // // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // // GNU General Public License V3 for more details. // // // // You should have received a copy of the GNU General Public License // // along with this program. If not, see . // /////////////////////////////////////////////////////////////////////////////////// #include "plugin/plugininstancegui.h" #include "plugin/plugininterface.h" #include "dsp/dspdevicesourceengine.h" #include "dsp/dspdevicesinkengine.h" #include "dsp/dspdevicemimoengine.h" #include "dsp/dspengine.h" #include "dsp/devicesamplesource.h" #include "dsp/devicesamplesink.h" #include "dsp/devicesamplemimo.h" #include "settings/preset.h" #include "channel/channelapi.h" #include "deviceapi.h" DeviceAPI::DeviceAPI( StreamType streamType, int deviceTabIndex, DSPDeviceSourceEngine *deviceSourceEngine, DSPDeviceSinkEngine *deviceSinkEngine, DSPDeviceMIMOEngine *deviceMIMOEngine ) : m_streamType(streamType), m_deviceTabIndex(deviceTabIndex), m_deviceNbItems(1), m_deviceItemIndex(0), m_nbSourceStreams(0), m_nbSinkStreams(0), m_pluginInterface(nullptr), m_masterTimer(DSPEngine::instance()->getMasterTimer()), m_samplingDeviceSequence(0), m_samplingDevicePluginInstanceUI(0), m_buddySharedPtr(nullptr), m_isBuddyLeader(false), m_deviceSourceEngine(deviceSourceEngine), m_deviceSinkEngine(deviceSinkEngine), m_deviceMIMOEngine(deviceMIMOEngine) { } DeviceAPI::~DeviceAPI() { } void DeviceAPI::addAncillarySink(BasebandSampleSink *sink, unsigned int index) { if (m_deviceSourceEngine) { m_deviceSourceEngine->addSink(sink); } else if (m_deviceSinkEngine) { m_deviceSinkEngine->addSpectrumSink(sink); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->addAncillarySink(sink, index); } } void DeviceAPI::removeAncillarySink(BasebandSampleSink* sink, unsigned int index) { if (m_deviceSourceEngine) { m_deviceSourceEngine->removeSink(sink); } else if (m_deviceSinkEngine) { m_deviceSinkEngine->removeSpectrumSink(sink); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->removeAncillarySink(sink, index); } } void DeviceAPI::setSpectrumSinkInput(bool sourceElseSink, unsigned int index) { if (m_deviceMIMOEngine) { // In practice this is only used in the MIMO case m_deviceMIMOEngine->setSpectrumSinkInput(sourceElseSink, index); } } void DeviceAPI::addChannelSink(ThreadedBasebandSampleSink* sink, int streamIndex) { if (m_deviceSourceEngine) { m_deviceSourceEngine->addThreadedSink(sink); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->addChannelSink(sink, streamIndex); } } void DeviceAPI::removeChannelSink(ThreadedBasebandSampleSink* sink, int streamIndex) { (void) streamIndex; if (m_deviceSourceEngine) { m_deviceSourceEngine->removeThreadedSink(sink); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->removeChannelSink(sink, streamIndex); } } void DeviceAPI::addChannelSource(ThreadedBasebandSampleSource* source, int streamIndex) { (void) streamIndex; if (m_deviceSinkEngine) { m_deviceSinkEngine->addThreadedSource(source); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->addChannelSource(source); } } void DeviceAPI::removeChannelSource(ThreadedBasebandSampleSource* source, int streamIndex) { (void) streamIndex; if (m_deviceSinkEngine) { m_deviceSinkEngine->removeThreadedSource(source); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->removeChannelSource(source); } } void DeviceAPI::addMIMOChannel(MIMOChannel* channel) { if (m_deviceMIMOEngine) { m_deviceMIMOEngine->addMIMOChannel(channel); } } void DeviceAPI::removeMIMOChannel(MIMOChannel* channel) { if (m_deviceMIMOEngine) { m_deviceMIMOEngine->removeMIMOChannel(channel); } } void DeviceAPI::addChannelSinkAPI(ChannelAPI* channelAPI, int streamIndex) { (void) streamIndex; m_channelSinkAPIs.append(channelAPI); renumerateChannels(); } void DeviceAPI::removeChannelSinkAPI(ChannelAPI* channelAPI, int streamIndex) { (void) streamIndex; if (m_channelSinkAPIs.removeOne(channelAPI)) { renumerateChannels(); } channelAPI->setIndexInDeviceSet(-1); } void DeviceAPI::addChannelSourceAPI(ChannelAPI* channelAPI, int streamIndex) { (void) streamIndex; m_channelSourceAPIs.append(channelAPI); renumerateChannels(); } void DeviceAPI::removeChannelSourceAPI(ChannelAPI* channelAPI, int streamIndex) { (void) streamIndex; if (m_channelSourceAPIs.removeOne(channelAPI)) { renumerateChannels(); } channelAPI->setIndexInDeviceSet(-1); } void DeviceAPI::addMIMOChannelAPI(ChannelAPI* channelAPI) { m_mimoChannelAPIs.append(channelAPI); } void DeviceAPI::removeMIMOChannelAPI(ChannelAPI *channelAPI) { if (m_mimoChannelAPIs.removeOne(channelAPI)) { renumerateChannels(); } } void DeviceAPI::setSampleSource(DeviceSampleSource* source) { if (m_deviceSourceEngine) { m_deviceSourceEngine->setSource(source); } } void DeviceAPI::setSampleSink(DeviceSampleSink* sink) { if (m_deviceSinkEngine) { m_deviceSinkEngine->setSink(sink); } } void DeviceAPI::setSampleMIMO(DeviceSampleMIMO* mimo) { if (m_deviceMIMOEngine) { m_deviceMIMOEngine->setMIMO(mimo); } } DeviceSampleSource *DeviceAPI::getSampleSource() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->getSource(); } else { return nullptr; } } DeviceSampleSink *DeviceAPI::getSampleSink() { if (m_deviceSinkEngine) { return m_deviceSinkEngine->getSink(); } else { return nullptr; } } DeviceSampleMIMO *DeviceAPI::getSampleMIMO() { if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->getMIMO(); } else { return nullptr; } } bool DeviceAPI::initDeviceEngine() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->initAcquisition(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->initGeneration(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->initProcess(); } else { return false; } } bool DeviceAPI::startDeviceEngine() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->startAcquisition(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->startGeneration(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->startProcess(); } else { return false; } } void DeviceAPI::stopDeviceEngine() { if (m_deviceSourceEngine) { m_deviceSourceEngine->stopAcquistion(); } else if (m_deviceSinkEngine) { m_deviceSinkEngine->stopGeneration(); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->stopProcess(); } } DeviceAPI::EngineState DeviceAPI::state() const { if (m_deviceSourceEngine) { return (DeviceAPI::EngineState) m_deviceSourceEngine->state(); } else if (m_deviceSinkEngine) { return (DeviceAPI::EngineState) m_deviceSinkEngine->state(); } else if (m_deviceMIMOEngine) { return (DeviceAPI::EngineState) m_deviceMIMOEngine->state(); } else { return StError; } } QString DeviceAPI::errorMessage() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->errorMessage(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->errorMessage(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->errorMessage(); } else { return "Not implemented"; } } uint DeviceAPI::getDeviceUID() const { if (m_deviceSourceEngine) { return m_deviceSourceEngine->getUID(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->getUID(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->getUID(); } else { return 0; } } MessageQueue *DeviceAPI::getDeviceEngineInputMessageQueue() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->getInputMessageQueue(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->getInputMessageQueue(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->getInputMessageQueue(); } else { return nullptr; } } MessageQueue *DeviceAPI::getSamplingDeviceInputMessageQueue() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->getSource()->getInputMessageQueue(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->getSink()->getInputMessageQueue(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->getMIMO()->getInputMessageQueue(); } else { return nullptr; } } MessageQueue *DeviceAPI::getSamplingDeviceGUIMessageQueue() { if (m_deviceSourceEngine) { return m_deviceSourceEngine->getSource()->getMessageQueueToGUI(); } else if (m_deviceSinkEngine) { return m_deviceSinkEngine->getSink()->getMessageQueueToGUI(); } else if (m_deviceMIMOEngine) { return m_deviceMIMOEngine->getMIMO()->getMessageQueueToGUI(); } else { return nullptr; } } void DeviceAPI::configureCorrections(bool dcOffsetCorrection, bool iqImbalanceCorrection, int streamIndex) { if (m_deviceSourceEngine) { m_deviceSourceEngine->configureCorrections(dcOffsetCorrection, iqImbalanceCorrection); } else if (m_deviceMIMOEngine) { m_deviceMIMOEngine->configureCorrections(dcOffsetCorrection, iqImbalanceCorrection, streamIndex); } } void DeviceAPI::setHardwareId(const QString& id) { m_hardwareId = id; } void DeviceAPI::setDeviceNbItems(uint32_t nbItems) { m_deviceNbItems = nbItems; } void DeviceAPI::setDeviceItemIndex(uint32_t index) { m_deviceItemIndex = index; } void DeviceAPI::setSamplingDevicePluginInterface(PluginInterface *iface) { m_pluginInterface = iface; } void DeviceAPI::setSamplingDevicePluginInstanceGUI(PluginInstanceGUI *gui) { m_samplingDevicePluginInstanceUI = gui; } void DeviceAPI::getDeviceEngineStateStr(QString& state) { if (m_deviceSourceEngine) { switch(m_deviceSourceEngine->state()) { case DSPDeviceSourceEngine::StNotStarted: state = "notStarted"; break; case DSPDeviceSourceEngine::StIdle: state = "idle"; break; case DSPDeviceSourceEngine::StReady: state = "ready"; break; case DSPDeviceSourceEngine::StRunning: state = "running"; break; case DSPDeviceSourceEngine::StError: state = "error"; break; default: state = "notStarted"; break; } } else if (m_deviceSinkEngine) { switch(m_deviceSinkEngine->state()) { case DSPDeviceSinkEngine::StNotStarted: state = "notStarted"; break; case DSPDeviceSinkEngine::StIdle: state = "idle"; break; case DSPDeviceSinkEngine::StReady: state = "ready"; break; case DSPDeviceSinkEngine::StRunning: state = "running"; break; case DSPDeviceSinkEngine::StError: state = "error"; break; default: state = "notStarted"; break; } } else { state = "notStarted"; } } ChannelAPI *DeviceAPI::getChanelSinkAPIAt(int index, int streamIndex) { (void) streamIndex; if (m_streamType == StreamSingleRx) { if (index < m_channelSinkAPIs.size()) { return m_channelSinkAPIs.at(index); } else { return nullptr; } } else // TODO: not implemented { return nullptr; } } ChannelAPI *DeviceAPI::getChanelSourceAPIAt(int index, int streamIndex) { (void) streamIndex; if (m_streamType == StreamSingleTx) { if (index < m_channelSourceAPIs.size()) { return m_channelSourceAPIs.at(index); } else { return nullptr; } } else // TODO: not implemented { return nullptr; } } void DeviceAPI::loadSamplingDeviceSettings(const Preset* preset) { if (m_deviceSourceEngine && (preset->isSourcePreset())) { qDebug("DeviceAPI::loadSamplingDeviceSettings: Loading Rx preset [%s | %s]", qPrintable(preset->getGroup()), qPrintable(preset->getDescription())); const QByteArray* sourceConfig = preset->findBestDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence); qint64 centerFrequency = preset->getCenterFrequency(); qDebug("DeviceAPI::loadSamplingDeviceSettings: source center frequency: %llu Hz", centerFrequency); if (sourceConfig) { qDebug("DeviceAPI::loadSamplingDeviceSettings: deserializing source %s[%d]: %s", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); if (m_samplingDevicePluginInstanceUI != 0) // GUI flavor { m_samplingDevicePluginInstanceUI->deserialize(*sourceConfig); } else if (m_deviceSourceEngine->getSource() != 0) // Server flavor { m_deviceSourceEngine->getSource()->deserialize(*sourceConfig); } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: deserializing no source"); } } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: source %s[%d]: %s not found", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); } // set center frequency anyway if (m_samplingDevicePluginInstanceUI != 0) // GUI flavor { m_samplingDevicePluginInstanceUI->setCenterFrequency(centerFrequency); } else if (m_deviceSourceEngine->getSource() != 0) // Server flavor { m_deviceSourceEngine->getSource()->setCenterFrequency(centerFrequency); } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: no source"); } } else if (m_deviceSinkEngine && preset->isSinkPreset()) { qDebug("DeviceAPI::loadSamplingDeviceSettings: Loading Tx preset [%s | %s]", qPrintable(preset->getGroup()), qPrintable(preset->getDescription())); const QByteArray* sinkConfig = preset->findBestDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence); qint64 centerFrequency = preset->getCenterFrequency(); qDebug("DeviceAPI::loadSamplingDeviceSettings: sink center frequency: %llu Hz", centerFrequency); if (sinkConfig) { qDebug("DeviceAPI::loadSamplingDeviceSettings: deserializing sink %s[%d]: %s", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); if (m_samplingDevicePluginInstanceUI != 0) // GUI flavor { m_samplingDevicePluginInstanceUI->deserialize(*sinkConfig); m_samplingDevicePluginInstanceUI->setCenterFrequency(centerFrequency); } else if (m_deviceSinkEngine->getSink() != 0) // Server flavor { m_deviceSinkEngine->getSink()->deserialize(*sinkConfig); m_deviceSinkEngine->getSink()->setCenterFrequency(centerFrequency); } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: no sink"); } } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: sink %s[%d]: %s not found", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); } } else if (m_deviceMIMOEngine && preset->isMIMOPreset()) { qDebug("DeviceAPI::loadSamplingDeviceSettings: Loading MIMO preset [%s | %s]", qPrintable(preset->getGroup()), qPrintable(preset->getDescription())); const QByteArray* mimoConfig = preset->findBestDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence); qint64 centerFrequency = preset->getCenterFrequency(); qDebug("DeviceAPI::loadSamplingDeviceSettings: MIMO center frequency: %llu Hz", centerFrequency); if (mimoConfig) { qDebug("DeviceAPI::loadSamplingDeviceSettings: deserializing MIMO %s[%d]: %s", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); if (m_samplingDevicePluginInstanceUI != 0) // GUI flavor { m_samplingDevicePluginInstanceUI->deserialize(*mimoConfig); m_samplingDevicePluginInstanceUI->setCenterFrequency(centerFrequency); } else if (m_deviceSinkEngine->getSink() != 0) // Server flavor { m_deviceSinkEngine->getSink()->deserialize(*mimoConfig); m_deviceSinkEngine->getSink()->setCenterFrequency(centerFrequency); } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: no MIMO"); } } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: MIMO %s[%d]: %s not found", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); } } else { qDebug("DeviceAPI::loadSamplingDeviceSettings: Loading preset [%s | %s] is not a suitable preset", qPrintable(preset->getGroup()), qPrintable(preset->getDescription())); } } void DeviceAPI::saveSamplingDeviceSettings(Preset* preset) { if (m_deviceSourceEngine && (preset->isSourcePreset())) { qDebug("DeviceAPI::saveSamplingDeviceSettings: serializing source %s[%d]: %s", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); if (m_samplingDevicePluginInstanceUI) // GUI flavor { preset->addOrUpdateDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence, m_samplingDevicePluginInstanceUI->serialize()); preset->setCenterFrequency(m_samplingDevicePluginInstanceUI->getCenterFrequency()); } else if (m_deviceSourceEngine->getSource()) // Server flavor { preset->addOrUpdateDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence, m_deviceSourceEngine->getSource()->serialize()); preset->setCenterFrequency(m_deviceSourceEngine->getSource()->getCenterFrequency()); } else { qDebug("DeviceAPI::saveSamplingDeviceSettings: no source"); } } else if (m_deviceSinkEngine && preset->isSinkPreset()) { qDebug("DeviceAPI::saveSamplingDeviceSettings: serializing sink %s[%d]: %s", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); if (m_samplingDevicePluginInstanceUI) // GUI flavor { preset->addOrUpdateDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence, m_deviceSinkEngine->getSink()->serialize()); preset->setCenterFrequency(m_deviceSinkEngine->getSink()->getCenterFrequency()); } else if (m_deviceSinkEngine->getSink()) // Server flavor { preset->addOrUpdateDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence, m_deviceSinkEngine->getSink()->serialize()); preset->setCenterFrequency(m_deviceSinkEngine->getSink()->getCenterFrequency()); } else { qDebug("DeviceAPI::saveSamplingDeviceSettings: no sink"); } } else if (m_deviceMIMOEngine && preset->isMIMOPreset()) { qDebug("DeviceAPI::saveSamplingDeviceSettings: serializing MIMO %s[%d]: %s", qPrintable(m_samplingDeviceId), m_samplingDeviceSequence, qPrintable(m_samplingDeviceSerial)); if (m_samplingDevicePluginInstanceUI) // GUI flavor { preset->addOrUpdateDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence, m_deviceMIMOEngine->getMIMO()->serialize()); preset->setCenterFrequency(m_deviceMIMOEngine->getMIMO()->getMIMOCenterFrequency()); } else if (m_deviceMIMOEngine->getMIMO()) // Server flavor { preset->addOrUpdateDeviceConfig(m_samplingDeviceId, m_samplingDeviceSerial, m_samplingDeviceSequence, m_deviceMIMOEngine->getMIMO()->serialize()); preset->setCenterFrequency(m_deviceMIMOEngine->getMIMO()->getMIMOCenterFrequency()); } else { qDebug("DeviceAPI::saveSamplingDeviceSettings: no MIMO"); } } else { qDebug("DeviceAPI::saveSamplingDeviceSettings: not a suitable preset"); } } void DeviceAPI::addSourceBuddy(DeviceAPI* buddy) { if (buddy->m_streamType != StreamSingleRx) { qDebug("DeviceAPI::addSourceBuddy: buddy %s(%s) is not of single Rx type", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial())); return; } m_sourceBuddies.push_back(buddy); if (m_streamType == StreamSingleRx) { buddy->m_sourceBuddies.push_back(this); // this is a source } else if (m_streamType == StreamSingleTx) { buddy->m_sinkBuddies.push_back(this); // this is a sink } else { qDebug("DeviceAPI::addSourceBuddy: not relevant if this is not a single Rx or Tx"); return; } qDebug("DeviceAPI::addSourceBuddy: added buddy %s(%s) [%llu] <-> [%llu]", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial()), (quint64) buddy, (quint64) this); } void DeviceAPI::addSinkBuddy(DeviceAPI* buddy) { if (buddy->m_streamType != StreamSingleTx) { qDebug("DeviceAPI::addSinkBuddy: buddy %s(%s) is not of single Tx type", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial())); return; } m_sinkBuddies.push_back(buddy); if (m_streamType == StreamSingleRx) { buddy->m_sourceBuddies.push_back(this); // this is a source } else if (m_streamType == StreamSingleTx) { buddy->m_sinkBuddies.push_back(this); // this is a sink } else { qDebug("DeviceAPI::addSinkBuddy: not relevant if this is not a single Rx or Tx"); return; } qDebug("DeviceAPI::addSinkBuddy: added buddy %s(%s) [%llu] <-> [%llu]", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial()), (quint64) buddy, (quint64) this); } void DeviceAPI::removeSourceBuddy(DeviceAPI* buddy) { if (buddy->m_streamType != StreamSingleRx) { qDebug("DeviceAPI::removeSourceBuddy: buddy %s(%s) is not of single Rx type", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial())); return; } std::vector::iterator it = m_sourceBuddies.begin(); for (;it != m_sourceBuddies.end(); ++it) { if (*it == buddy) { qDebug("DeviceAPI::removeSourceBuddy: buddy %s(%s) [%llu] removed from the list of [%llu]", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial()), (quint64) (*it), (quint64) this); m_sourceBuddies.erase(it); return; } } qDebug("DeviceAPI::removeSourceBuddy: buddy %s(%s) [%llu] not found in the list of [%llu]", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial()), (quint64) buddy, (quint64) this); } void DeviceAPI::removeSinkBuddy(DeviceAPI* buddy) { if (buddy->m_streamType != StreamSingleTx) { qDebug("DeviceAPI::removeSinkBuddy: buddy %s(%s) is not of single Tx type", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial())); return; } std::vector::iterator it = m_sinkBuddies.begin(); for (;it != m_sinkBuddies.end(); ++it) { if (*it == buddy) { qDebug("DeviceAPI::removeSinkBuddy: buddy %s(%s) [%llu] removed from the list of [%llu]", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial()), (quint64) (*it), (quint64) this); m_sinkBuddies.erase(it); return; } } qDebug("DeviceAPI::removeSourceBuddy: buddy %s(%s) [%llu] not found in the list of [%llu]", qPrintable(buddy->getHardwareId()), qPrintable(buddy->getSamplingDeviceSerial()), (quint64) buddy, (quint64) this); } void DeviceAPI::clearBuddiesLists() { std::vector::iterator itSource = m_sourceBuddies.begin(); std::vector::iterator itSink = m_sinkBuddies.begin(); bool leaderElected = false; for (;itSource != m_sourceBuddies.end(); ++itSource) { if (isBuddyLeader() && !leaderElected) { (*itSource)->setBuddyLeader(true); leaderElected = true; } (*itSource)->removeSinkBuddy(this); } m_sourceBuddies.clear(); for (;itSink != m_sinkBuddies.end(); ++itSink) { if (isBuddyLeader() && !leaderElected) { (*itSink)->setBuddyLeader(true); leaderElected = true; } (*itSink)->removeSinkBuddy(this); } m_sinkBuddies.clear(); } void DeviceAPI::renumerateChannels() { if (m_streamType == StreamSingleRx) { for (int i = 0; i < m_channelSinkAPIs.size(); ++i) { m_channelSinkAPIs.at(i)->setIndexInDeviceSet(i); m_channelSinkAPIs.at(i)->setDeviceSetIndex(m_deviceTabIndex); m_channelSinkAPIs.at(i)->setDeviceAPI(this); } } else if (m_streamType == StreamSingleTx) { for (int i = 0; i < m_channelSourceAPIs.size(); ++i) { m_channelSourceAPIs.at(i)->setIndexInDeviceSet(i); m_channelSourceAPIs.at(i)->setDeviceSetIndex(m_deviceTabIndex); m_channelSourceAPIs.at(i)->setDeviceAPI(this); } } else if (m_streamType == StreamMIMO) { for (int i = 0; i < m_mimoChannelAPIs.size(); ++i) { m_mimoChannelAPIs.at(i)->setIndexInDeviceSet(i); m_mimoChannelAPIs.at(i)->setDeviceSetIndex(m_deviceTabIndex); m_mimoChannelAPIs.at(i)->setDeviceAPI(this); } } }