/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2019 F4EXB // // written by Edouard Griffiths // // // // 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 #include "dsp/dspcommands.h" #include "threadedbasebandsamplesource.h" #include "threadedbasebandsamplesink.h" #include "devicesamplemimo.h" #include "dspdevicemimoengine.h" MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::SetSampleMIMO, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::AddThreadedBasebandSampleSource, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::RemoveThreadedBasebandSampleSource, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::AddThreadedBasebandSampleSink, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::RemoveThreadedBasebandSampleSink, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::AddBasebandSampleSink, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::RemoveBasebandSampleSink, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::AddSpectrumSink, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::RemoveSpectrumSink, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::GetErrorMessage, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::GetMIMODeviceDescription, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::ConfigureCorrection, Message) MESSAGE_CLASS_DEFINITION(DSPDeviceMIMOEngine::SignalNotification, Message) DSPDeviceMIMOEngine::DSPDeviceMIMOEngine(uint32_t uid, QObject* parent) : QThread(parent), m_uid(uid), m_state(StNotStarted) { connect(&m_inputMessageQueue, SIGNAL(messageEnqueued()), this, SLOT(handleInputMessages()), Qt::QueuedConnection); connect(&m_syncMessenger, SIGNAL(messageSent()), this, SLOT(handleSynchronousMessages()), Qt::QueuedConnection); moveToThread(this); } DSPDeviceMIMOEngine::~DSPDeviceMIMOEngine() { stop(); wait(); } void DSPDeviceMIMOEngine::run() { qDebug() << "DSPDeviceMIMOEngine::run"; m_state = StIdle; exec(); } void DSPDeviceMIMOEngine::start() { qDebug() << "DSPDeviceMIMOEngine::start"; QThread::start(); } void DSPDeviceMIMOEngine::stop() { qDebug() << "DSPDeviceMIMOEngine::stop"; gotoIdle(); m_state = StNotStarted; QThread::exit(); } bool DSPDeviceMIMOEngine::initProcess() { qDebug() << "DSPDeviceMIMOEngine::initGeneration"; DSPGenerationInit cmd; return m_syncMessenger.sendWait(cmd) == StReady; } bool DSPDeviceMIMOEngine::startProcess() { qDebug() << "DSPDeviceMIMOEngine::startGeneration"; DSPGenerationStart cmd; return m_syncMessenger.sendWait(cmd) == StRunning; } void DSPDeviceMIMOEngine::stopProcess() { qDebug() << "DSPDeviceMIMOEngine::stopGeneration"; DSPGenerationStop cmd; m_syncMessenger.storeMessage(cmd); handleSynchronousMessages(); } void DSPDeviceMIMOEngine::setMIMO(DeviceSampleMIMO* mimo) { qDebug() << "DSPDeviceMIMOEngine::setSink"; SetSampleMIMO cmd(mimo); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::setMIMOSequence(int sequence) { qDebug("DSPDeviceMIMOEngine::setSinkSequence: seq: %d", sequence); m_sampleMIMOSequence = sequence; } void DSPDeviceMIMOEngine::addChannelSource(ThreadedBasebandSampleSource* source, int index) { qDebug() << "DSPDeviceMIMOEngine::addThreadedSource: " << source->objectName().toStdString().c_str() << " at: " << index; AddThreadedBasebandSampleSource cmd(source, index); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::removeChannelSource(ThreadedBasebandSampleSource* source, int index) { qDebug() << "DSPDeviceMIMOEngine::removeThreadedSource: " << source->objectName().toStdString().c_str() << " at: " << index; RemoveThreadedBasebandSampleSource cmd(source, index); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::addChannelSink(ThreadedBasebandSampleSink* sink, int index) { qDebug() << "DSPDeviceMIMOEngine::addThreadedSink: " << sink->objectName().toStdString().c_str() << " at: " << index; AddThreadedBasebandSampleSink cmd(sink, index); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::removeChannelSink(ThreadedBasebandSampleSink* sink, int index) { qDebug() << "DSPDeviceMIMOEngine::removeThreadedSink: " << sink->objectName().toStdString().c_str() << " at: " << index; RemoveThreadedBasebandSampleSink cmd(sink, index); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::addAncillarySink(BasebandSampleSink* sink, int index) { qDebug() << "DSPDeviceMIMOEngine::addSink: " << sink->objectName().toStdString().c_str() << " at: " << index; AddBasebandSampleSink cmd(sink, index); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::removeAncillarySink(BasebandSampleSink* sink, int index) { qDebug() << "DSPDeviceMIMOEngine::removeSink: " << sink->objectName().toStdString().c_str() << " at: " << index; RemoveBasebandSampleSink cmd(sink, index); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::addSpectrumSink(BasebandSampleSink* spectrumSink) { qDebug() << "DSPDeviceMIMOEngine::addSpectrumSink: " << spectrumSink->objectName().toStdString().c_str(); AddSpectrumSink cmd(spectrumSink); m_syncMessenger.sendWait(cmd); } void DSPDeviceMIMOEngine::removeSpectrumSink(BasebandSampleSink* spectrumSink) { qDebug() << "DSPDeviceSinkEngine::removeSpectrumSink: " << spectrumSink->objectName().toStdString().c_str(); DSPRemoveSpectrumSink cmd(spectrumSink); m_syncMessenger.sendWait(cmd); } QString DSPDeviceMIMOEngine::errorMessage() { qDebug() << "DSPDeviceMIMOEngine::errorMessage"; GetErrorMessage cmd; m_syncMessenger.sendWait(cmd); return cmd.getErrorMessage(); } QString DSPDeviceMIMOEngine::deviceDescription() { qDebug() << "DSPDeviceMIMOEngine::deviceDescription"; GetMIMODeviceDescription cmd; m_syncMessenger.sendWait(cmd); return cmd.getDeviceDescription(); } /** * Routes samples from device source FIFO to sink channels that are registered for the FIFO * Routes samples from source channels registered for the FIFO to the device sink FIFO */ void DSPDeviceMIMOEngine::work(int nbWriteSamples) { (void) nbWriteSamples; // Sources for (unsigned int isource = 0; isource < m_deviceSampleMIMO->getNbSourceFifos(); isource++) { if (isource >= m_sourceStreamSampleRates.size()) { continue; } SampleSinkFifo* sampleFifo = m_deviceSampleMIMO->getSampleSinkFifo(isource); // sink FIFO is for Rx std::size_t samplesDone = 0; bool positiveOnly = false; while ((sampleFifo->fill() > 0) && (m_inputMessageQueue.size() == 0) && (samplesDone < m_sourceStreamSampleRates[isource])) { SampleVector::iterator part1begin; SampleVector::iterator part1end; SampleVector::iterator part2begin; SampleVector::iterator part2end; std::size_t count = sampleFifo->readBegin(sampleFifo->fill(), &part1begin, &part1end, &part2begin, &part2end); // first part of FIFO data if (part1begin != part1end) { // TODO: DC and IQ corrections // feed data to direct sinks if (isource < m_basebandSampleSinks.size()) { for (BasebandSampleSinks::const_iterator it = m_basebandSampleSinks[isource].begin(); it != m_basebandSampleSinks[isource].end(); ++it) { (*it)->feed(part1begin, part1end, positiveOnly); } } // feed data to threaded sinks if (isource < m_threadedBasebandSampleSinks.size()) { for (ThreadedBasebandSampleSinks::const_iterator it = m_threadedBasebandSampleSinks[isource].begin(); it != m_threadedBasebandSampleSinks[isource].end(); ++it) { (*it)->feed(part1begin, part1end, positiveOnly); } } } // second part of FIFO data (used when block wraps around) if(part2begin != part2end) { // TODO: DC and IQ corrections // feed data to direct sinks if (isource < m_basebandSampleSinks.size()) { for (BasebandSampleSinks::const_iterator it = m_basebandSampleSinks[isource].begin(); it != m_basebandSampleSinks[isource].end(); ++it) { (*it)->feed(part2begin, part2end, positiveOnly); } } // feed data to threaded sinks if (isource < m_threadedBasebandSampleSinks.size()) { for (ThreadedBasebandSampleSinks::const_iterator it = m_threadedBasebandSampleSinks[isource].begin(); it != m_threadedBasebandSampleSinks[isource].end(); ++it) { (*it)->feed(part2begin, part2end, positiveOnly); } } } // adjust FIFO pointers sampleFifo->readCommit((unsigned int) count); samplesDone += count; } // while stream FIFO } // for stream source // TODO: sinks } // notStarted -> idle -> init -> running -+ // ^ | // +-----------------------+ DSPDeviceMIMOEngine::State DSPDeviceMIMOEngine::gotoIdle() { qDebug() << "DSPDeviceMIMOEngine::gotoIdle"; switch(m_state) { case StNotStarted: return StNotStarted; case StIdle: case StError: return StIdle; case StReady: case StRunning: break; } if (m_deviceSampleMIMO == 0) { return StIdle; } // stop everything std::vector::const_iterator vbit = m_basebandSampleSinks.begin(); for (; vbit != m_basebandSampleSinks.end(); ++vbit) { for (BasebandSampleSinks::const_iterator it = vbit->begin(); it != vbit->end(); ++it) { (*it)->stop(); } } std::vector::const_iterator vtit = m_threadedBasebandSampleSinks.begin(); for (; vtit != m_threadedBasebandSampleSinks.end(); vtit++) { for (ThreadedBasebandSampleSinks::const_iterator it = vtit->begin(); it != vtit->end(); ++it) { (*it)->stop(); } } m_deviceSampleMIMO->stop(); m_deviceDescription.clear(); for (std::vector::iterator it = m_sourceStreamSampleRates.begin(); it != m_sourceStreamSampleRates.end(); ++it) { *it = 0; } return StIdle; } DSPDeviceMIMOEngine::State DSPDeviceMIMOEngine::gotoInit() { switch(m_state) { case StNotStarted: return StNotStarted; case StRunning: // FIXME: assumes it goes first through idle state. Could we get back to init from running directly? return StRunning; case StReady: return StReady; case StIdle: case StError: break; } if (m_deviceSampleMIMO == 0) { return gotoError("No sample MIMO configured"); } // init: pass sample rate and center frequency to all sample rate and/or center frequency dependent sinks and wait for completion m_deviceDescription = m_deviceSampleMIMO->getDeviceDescription(); qDebug() << "DSPDeviceMIMOEngine::gotoInit: " << " m_deviceDescription: " << m_deviceDescription.toStdString().c_str(); for (unsigned int isource = 0; isource < m_deviceSampleMIMO->getNbSourceFifos(); isource++) { if (isource < m_sourcesCorrections.size()) { m_sourcesCorrections[isource].m_iOffset = 0; m_sourcesCorrections[isource].m_qOffset = 0; m_sourcesCorrections[isource].m_iRange = 1 << 16; m_sourcesCorrections[isource].m_qRange = 1 << 16; } if ((isource < m_sourceCenterFrequencies.size()) && (isource < m_sourceStreamSampleRates.size())) { m_sourceCenterFrequencies[isource] = m_deviceSampleMIMO->getSourceCenterFrequency(isource); m_sourceStreamSampleRates[isource] = m_deviceSampleMIMO->getSourceSampleRate(isource); qDebug("DSPDeviceMIMOEngine::gotoInit: m_sourceCenterFrequencies[%d] = %llu", isource, m_sourceCenterFrequencies[isource]); qDebug("DSPDeviceMIMOEngine::gotoInit: m_sourceStreamSampleRates[%d] = %d", isource, m_sourceStreamSampleRates[isource]); DSPSignalNotification notif(m_sourceStreamSampleRates[isource], m_sourceCenterFrequencies[isource]); if (isource < m_basebandSampleSinks.size()) { for (BasebandSampleSinks::const_iterator it = m_basebandSampleSinks[isource].begin(); it != m_basebandSampleSinks[isource].end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::gotoInit: initializing " << (*it)->objectName().toStdString().c_str(); (*it)->handleMessage(notif); } } if (isource < m_threadedBasebandSampleSinks.size()) { for (ThreadedBasebandSampleSinks::const_iterator it = m_threadedBasebandSampleSinks[isource].begin(); it != m_threadedBasebandSampleSinks[isource].end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::gotoInit: initializing ThreadedSampleSink(" << (*it)->getSampleSinkObjectName().toStdString().c_str() << ")"; (*it)->handleSinkMessage(notif); } } // pass data to listeners // if (m_deviceSampleSource->getMessageQueueToGUI()) // { // DSPSignalNotification* rep = new DSPSignalNotification(notif); // make a copy for the output queue // m_deviceSampleSource->getMessageQueueToGUI()->push(rep); // } } } return StReady; } DSPDeviceMIMOEngine::State DSPDeviceMIMOEngine::gotoRunning() { qDebug() << "DSPDeviceMIMOEngine::gotoRunning"; switch(m_state) { case StNotStarted: return StNotStarted; case StIdle: return StIdle; case StRunning: return StRunning; case StReady: case StError: break; } if (!m_deviceSampleMIMO) { return gotoError("DSPDeviceMIMOEngine::gotoRunning: No sample source configured"); } qDebug() << "DSPDeviceMIMOEngine::gotoRunning: " << m_deviceDescription.toStdString().c_str() << " started"; // Start everything if (!m_deviceSampleMIMO->start()) { return gotoError("Could not start sample source"); } std::vector::const_iterator vbit = m_basebandSampleSinks.begin(); for (; vbit != m_basebandSampleSinks.end(); ++vbit) { for (BasebandSampleSinks::const_iterator it = vbit->begin(); it != vbit->end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::gotoRunning: starting " << (*it)->objectName().toStdString().c_str(); (*it)->start(); } } std::vector::const_iterator vtit = m_threadedBasebandSampleSinks.begin(); for (; vtit != m_threadedBasebandSampleSinks.end(); vtit++) { for (ThreadedBasebandSampleSinks::const_iterator it = vtit->begin(); it != vtit->end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::gotoRunning: starting ThreadedSampleSink(" << (*it)->getSampleSinkObjectName().toStdString().c_str() << ")"; (*it)->start(); } } qDebug() << "DSPDeviceMIMOEngine::gotoRunning:input message queue pending: " << m_inputMessageQueue.size(); return StRunning; } DSPDeviceMIMOEngine::State DSPDeviceMIMOEngine::gotoError(const QString& errorMessage) { qDebug() << "DSPDeviceMIMOEngine::gotoError: " << errorMessage; m_errorMessage = errorMessage; m_deviceDescription.clear(); m_state = StError; return StError; } void DSPDeviceMIMOEngine::handleData() { if(m_state == StRunning) { work(0); // TODO: implement Tx side } } void DSPDeviceMIMOEngine::handleSetMIMO(DeviceSampleMIMO* mimo) { if (mimo && (mimo->getNbSinkFifos() > 0)) { // if there is at least one Rx then the first Rx drives the FIFOs qDebug("DSPDeviceMIMOEngine::handleSetMIMO: set %s", qPrintable(mimo->getDeviceDescription())); connect(m_deviceSampleMIMO->getSampleSinkFifo(0), SIGNAL(dataReady()), this, SLOT(handleData()), Qt::QueuedConnection); } // TODO: only Tx } void DSPDeviceMIMOEngine::handleSynchronousMessages() { Message *message = m_syncMessenger.getMessage(); qDebug() << "DSPDeviceMIMOEngine::handleSynchronousMessages: " << message->getIdentifier(); if (DSPGenerationInit::match(*message)) { m_state = gotoIdle(); if(m_state == StIdle) { m_state = gotoInit(); // State goes ready if init is performed } } else if (DSPGenerationStart::match(*message)) { if(m_state == StReady) { m_state = gotoRunning(); } } else if (DSPGenerationStop::match(*message)) { m_state = gotoIdle(); } else if (GetMIMODeviceDescription::match(*message)) { ((GetMIMODeviceDescription*) message)->setDeviceDescription(m_deviceDescription); } else if (DSPGetErrorMessage::match(*message)) { ((DSPGetErrorMessage*) message)->setErrorMessage(m_errorMessage); } else if (SetSampleMIMO::match(*message)) { handleSetMIMO(((SetSampleMIMO*) message)->getSampleMIMO()); } else if (AddBasebandSampleSink::match(*message)) { const AddBasebandSampleSink *msg = (AddBasebandSampleSink *) message; BasebandSampleSink* sink = msg->getSampleSink(); unsigned int isource = msg->getIndex(); if ((isource < m_basebandSampleSinks.size()) && (isource < m_sourceStreamSampleRates.size()) && (isource < m_sourceCenterFrequencies.size())) { m_basebandSampleSinks[isource].push_back(sink); // initialize sample rate and center frequency in the sink: DSPSignalNotification msg(m_sourceStreamSampleRates[isource], m_sourceCenterFrequencies[isource]); sink->handleMessage(msg); // start the sink: if(m_state == StRunning) { sink->start(); } } } else if (RemoveBasebandSampleSink::match(*message)) { const RemoveBasebandSampleSink *msg = (RemoveBasebandSampleSink *) message; BasebandSampleSink* sink = ((DSPRemoveBasebandSampleSink*) message)->getSampleSink(); unsigned int isource = msg->getIndex(); if (isource < m_basebandSampleSinks.size()) { if(m_state == StRunning) { sink->stop(); } m_basebandSampleSinks[isource].remove(sink); } } else if (AddThreadedBasebandSampleSink::match(*message)) { const AddThreadedBasebandSampleSink *msg = (AddThreadedBasebandSampleSink *) message; ThreadedBasebandSampleSink *threadedSink = msg->getThreadedSampleSink(); unsigned int isource = msg->getIndex(); if ((isource < m_threadedBasebandSampleSinks.size()) && (isource < m_sourceStreamSampleRates.size()) && (isource < m_sourceCenterFrequencies.size())) { m_threadedBasebandSampleSinks[isource].push_back(threadedSink); // initialize sample rate and center frequency in the sink: DSPSignalNotification msg(m_sourceStreamSampleRates[isource], m_sourceCenterFrequencies[isource]); threadedSink->handleSinkMessage(msg); // start the sink: if(m_state == StRunning) { threadedSink->start(); } } } else if (RemoveThreadedBasebandSampleSink::match(*message)) { const RemoveThreadedBasebandSampleSink *msg = (RemoveThreadedBasebandSampleSink *) message; ThreadedBasebandSampleSink* threadedSink = msg->getThreadedSampleSink(); unsigned int isource = msg->getIndex(); if (isource < m_threadedBasebandSampleSinks.size()) { threadedSink->stop(); m_threadedBasebandSampleSinks[isource].remove(threadedSink); } } else if (AddThreadedBasebandSampleSource::match(*message)) { const AddThreadedBasebandSampleSource *msg = (AddThreadedBasebandSampleSource *) message; ThreadedBasebandSampleSource *threadedSource = msg->getThreadedSampleSource(); unsigned int isink = msg->getIndex(); if ((isink < m_threadedBasebandSampleSources.size()) && (isink < m_sinkStreamSampleRates.size()) && (isink < m_sinkCenterFrequencies.size())) { m_threadedBasebandSampleSources[isink].push_back(threadedSource); // initialize sample rate and center frequency in the sink: DSPSignalNotification msg(m_sourceStreamSampleRates[isink], m_sourceCenterFrequencies[isink]); threadedSource->handleSourceMessage(msg); // start the sink: if(m_state == StRunning) { threadedSource->start(); } } } else if (RemoveThreadedBasebandSampleSource::match(*message)) { const RemoveThreadedBasebandSampleSource *msg = (RemoveThreadedBasebandSampleSource *) message; ThreadedBasebandSampleSource* threadedSource = msg->getThreadedSampleSource(); unsigned int isink = msg->getIndex(); if (isink < m_threadedBasebandSampleSources.size()) { threadedSource->stop(); m_threadedBasebandSampleSources[isink].remove(threadedSource); } } m_syncMessenger.done(m_state); } void DSPDeviceMIMOEngine::handleInputMessages() { Message* message; while ((message = m_inputMessageQueue.pop()) != 0) { qDebug("DSPDeviceMIMOEngine::handleInputMessages: message: %s", message->getIdentifier()); if (ConfigureCorrection::match(*message)) { ConfigureCorrection* conf = (ConfigureCorrection*) message; unsigned int isource = conf->getIndex(); if (isource < m_sourcesCorrections.size()) { m_sourcesCorrections[isource].m_iqImbalanceCorrection = conf->getIQImbalanceCorrection(); if (m_sourcesCorrections[isource].m_dcOffsetCorrection != conf->getDCOffsetCorrection()) { m_sourcesCorrections[isource].m_dcOffsetCorrection = conf->getDCOffsetCorrection(); m_sourcesCorrections[isource].m_iOffset = 0; m_sourcesCorrections[isource].m_qOffset = 0; if (m_sourcesCorrections[isource].m_iqImbalanceCorrection != conf->getIQImbalanceCorrection()) { m_sourcesCorrections[isource].m_iqImbalanceCorrection = conf->getIQImbalanceCorrection(); m_sourcesCorrections[isource].m_iRange = 1 << 16; m_sourcesCorrections[isource].m_qRange = 1 << 16; m_sourcesCorrections[isource].m_imbalance = 65536; } } m_sourcesCorrections[isource].m_avgAmp.reset(); m_sourcesCorrections[isource].m_avgII.reset(); m_sourcesCorrections[isource].m_avgII2.reset(); m_sourcesCorrections[isource].m_avgIQ.reset(); m_sourcesCorrections[isource].m_avgPhi.reset(); m_sourcesCorrections[isource].m_avgQQ2.reset(); m_sourcesCorrections[isource].m_iBeta.reset(); m_sourcesCorrections[isource].m_qBeta.reset(); } delete message; } else if (SignalNotification::match(*message)) { SignalNotification *notif = (SignalNotification *) message; // update DSP values bool sourceOrSink = notif->getSourceOrSink(); unsigned int istream = notif->getIndex(); int sampleRate = notif->getSampleRate(); qint64 centerFrequency = notif->getCenterFrequency(); qDebug() << "DeviceMIMOEngine::handleInputMessages: SignalNotification:" << " sourceOrSink: " << sourceOrSink << " istream: " << istream << " sampleRate: " << sampleRate << " centerFrequency: " << centerFrequency; if (sourceOrSink) { if ((istream < m_sourceStreamSampleRates.size()) && (istream < m_sourceCenterFrequencies.size())) { m_sourceStreamSampleRates[istream] = sampleRate; m_sourceCenterFrequencies[istream] = centerFrequency; DSPSignalNotification *message = new DSPSignalNotification(sampleRate, centerFrequency); // forward source changes to ancillary sinks with immediate execution (no queuing) if (istream < m_basebandSampleSinks.size()) { for (BasebandSampleSinks::const_iterator it = m_basebandSampleSinks[istream].begin(); it != m_basebandSampleSinks[istream].end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::gotoRunning: starting " << (*it)->objectName().toStdString().c_str(); (*it)->handleMessage(*message); } } // forward source changes to channel sinks with immediate execution (no queuing) if (istream < m_threadedBasebandSampleSinks.size()) { for (ThreadedBasebandSampleSinks::const_iterator it = m_threadedBasebandSampleSinks[istream].begin(); it != m_threadedBasebandSampleSinks[istream].end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::handleSourceMessages: forward message to ThreadedSampleSink(" << (*it)->getSampleSinkObjectName().toStdString().c_str() << ")"; (*it)->handleSinkMessage(*message); } } // forward changes to source GUI input queue // MessageQueue *guiMessageQueue = m_deviceSampleSource->getMessageQueueToGUI(); // qDebug("DSPDeviceSourceEngine::handleInputMessages: DSPSignalNotification: guiMessageQueue: %p", guiMessageQueue); // if (guiMessageQueue) { // DSPSignalNotification* rep = new DSPSignalNotification(*notif); // make a copy for the source GUI // guiMessageQueue->push(rep); // } delete message; } } else { if ((istream < m_sinkStreamSampleRates.size()) && (istream < m_sinkCenterFrequencies.size())) { m_sinkStreamSampleRates[istream] = sampleRate; m_sinkCenterFrequencies[istream] = centerFrequency; DSPSignalNotification *message = new DSPSignalNotification(sampleRate, centerFrequency); // forward source changes to channel sources with immediate execution (no queuing) if (istream < m_threadedBasebandSampleSources.size()) { for (ThreadedBasebandSampleSources::const_iterator it = m_threadedBasebandSampleSources[istream].begin(); it != m_threadedBasebandSampleSources[istream].end(); ++it) { qDebug() << "DSPDeviceMIMOEngine::handleSinkMessages: forward message to ThreadedSampleSource(" << (*it)->getSampleSourceObjectName().toStdString().c_str() << ")"; (*it)->handleSourceMessage(*message); } } // forward changes to source GUI input queue // MessageQueue *guiMessageQueue = m_deviceSampleSource->getMessageQueueToGUI(); // qDebug("DSPDeviceSourceEngine::handleInputMessages: DSPSignalNotification: guiMessageQueue: %p", guiMessageQueue); // if (guiMessageQueue) { // DSPSignalNotification* rep = new DSPSignalNotification(*notif); // make a copy for the source GUI // guiMessageQueue->push(rep); // } } delete message; } } } }