/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2020 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 "dsp/samplemififo.h" #include "dsp/samplemofifo.h" #include "metismisoudphandler.h" MESSAGE_CLASS_DEFINITION(MetisMISOUDPHandler::MsgStartStop, Message) MetisMISOUDPHandler::MetisMISOUDPHandler(SampleMIFifo *sampleMIFifo, SampleMOFifo *sampleMOFifo, DeviceAPI *deviceAPI) : m_deviceAPI(deviceAPI), m_socket(nullptr), m_metisAddress(QHostAddress::LocalHost), m_metisPort(9090), m_running(false), m_dataConnected(false), m_sampleMIFifo(sampleMIFifo), m_sampleMOFifo(sampleMOFifo), m_sampleCount(0), m_sampleTxCount(0), m_messageQueueToGUI(nullptr), m_mutex(QMutex::Recursive), m_commandBase(0), m_receiveSequence(0), m_receiveSequenceError(0) { setNbReceivers(m_settings.m_nbReceivers); for (unsigned int i = 0; i < MetisMISOSettings::m_maxReceivers; i++) { m_convertBuffer[i].resize(1024, Sample{0,0}); } connect(&m_inputMessageQueue, SIGNAL(messageEnqueued()), this, SLOT(handleMessages())); } MetisMISOUDPHandler::~MetisMISOUDPHandler() { stop(); } void MetisMISOUDPHandler::start() { qDebug("MetisMISOUDPHandler::start"); m_rxFrame = 0; m_txFrame = 0; m_sendSequence = -1; m_offset = 8; m_receiveSequence = 0; if (m_running) { return; } if (!m_dataConnected) { if (m_socket.bind(QHostAddress::AnyIPv4, 10001, QUdpSocket::ShareAddress)) { qDebug("MetisMISOUDPHandler::start: bind host socket OK"); connect(&m_socket, SIGNAL(readyRead()), this, SLOT(dataReadyRead())); m_dataConnected = true; } else { qWarning("MetisMISOUDPHandler::start: cannot bind host socket"); m_dataConnected = false; return; } } // Start Metis unsigned char buffer[64]; buffer[0] = (unsigned char) 0xEF; buffer[1] = (unsigned char) 0XFE; buffer[2] = (unsigned char) 0x04; buffer[3] = (unsigned char) 0x01; std::fill(&buffer[4], &buffer[64], 0); if (m_socket.writeDatagram((const char*) buffer, sizeof(buffer), m_metisAddress, m_metisPort) < 0) { qDebug() << "MetisMISOUDPHandler::start: writeDatagram start command failed " << m_socket.errorString(); return; } else { qDebug() << "MetisMISOUDPHandler::start: writeDatagram start command" << m_metisAddress.toString() << ":" << m_metisPort; } m_socket.flush(); // send 2 frames with control data sendData(); sendData(); // TODO: on the next send frequencies m_running = true; } void MetisMISOUDPHandler::stop() { qDebug("MetisMISOUDPHandler::stop"); if (!m_running) { return; } // stop Metis unsigned char buffer[64]; buffer[0] = (unsigned char) 0xEF; buffer[1] = (unsigned char) 0XFE; buffer[2] = (unsigned char) 0x04; buffer[3] = (unsigned char) 0x00; std::fill(&buffer[4], &buffer[64], 0); if (m_dataConnected) { disconnect(&m_socket, SIGNAL(readyRead()), this, SLOT(dataReadyRead())); m_dataConnected = false; } if (m_socket.writeDatagram((const char*)buffer, sizeof(buffer), m_metisAddress,m_metisPort) < 0) { qDebug() << "MetisMISOUDPHandler::stop: writeDatagram failed " << m_socket.errorString(); return; } else { qDebug()<<"MetisMISOUDPHandler::stop: writeDatagram stop command" << m_metisAddress.toString() << ":" << m_metisPort; } m_socket.flush(); m_socket.close(); m_running = false; } void MetisMISOUDPHandler::setNbReceivers(unsigned int nbReceivers) { m_nbReceivers = nbReceivers; switch(m_nbReceivers) { case 1: m_bMax = 512-0; break; case 2: m_bMax = 512-0; break; case 3: m_bMax = 512-4; break; case 4: m_bMax = 512-10; break; case 5: m_bMax = 512-24; break; case 6: m_bMax = 512-10; break; case 7: m_bMax = 512-20; break; case 8: m_bMax = 512-4; break; } for (unsigned int i = 0; i < MetisMISOSettings::m_maxReceivers; i++) { m_convertBuffer[i].resize(1024, Sample{0,0}); } } void MetisMISOUDPHandler::applySettings(const MetisMISOSettings& settings) { if (m_settings.m_nbReceivers != settings.m_nbReceivers) { QMutexLocker mutexLocker(&m_mutex); int nbReceivers = settings.m_nbReceivers < 1 ? 1 : settings.m_nbReceivers > MetisMISOSettings::m_maxReceivers ? MetisMISOSettings::m_maxReceivers : settings.m_nbReceivers; setNbReceivers(nbReceivers); } if (m_settings.m_log2Decim != settings.m_log2Decim) { QMutexLocker mutexLocker(&m_mutex); m_decimators.resetCounters(); } m_settings = settings; } void MetisMISOUDPHandler::handleMessages() { Message* message; while ((message = m_inputMessageQueue.pop()) != 0) { if (handleMessage(*message)) { delete message; } } } bool MetisMISOUDPHandler::handleMessage(const Message& message) { if (MsgStartStop::match(message)) { const MsgStartStop& cmd = (const MsgStartStop&) message; if (cmd.getStartStop()) { start(); } else { stop(); } return true; } else { return false; } } void MetisMISOUDPHandler::sendMetisBuffer(int ep, unsigned char* buffer) { if (m_offset == 8) // header and first HPSDR frame { m_sendSequence++; m_outputBuffer[0] = 0xEF; m_outputBuffer[1] = 0xFE; m_outputBuffer[2] = 0x01; m_outputBuffer[3] = ep; m_outputBuffer[4] = (m_sendSequence>>24) & 0xFF; m_outputBuffer[5] = (m_sendSequence>>16) & 0xFF; m_outputBuffer[6] = (m_sendSequence>>8) & 0xFF; m_outputBuffer[7] = (m_sendSequence) & 0xFF; std::copy(buffer, buffer+512, &m_outputBuffer[m_offset]); // copy the buffer over m_offset = 520; } else // second HPSDR frame and send { std::copy(buffer, buffer+512, &m_outputBuffer[m_offset]); // copy the buffer over m_offset = 8; // send the buffer if (m_socket.writeDatagram((const char*) m_outputBuffer, sizeof(m_outputBuffer), m_metisAddress, m_metisPort) < 0) { qDebug() << "MetisMISOUDPHandler::sendMetisBuffer: writeDatagram failed " << m_socket.errorString(); return; } m_socket.flush(); } } void MetisMISOUDPHandler::dataReadyRead() { QHostAddress metisAddress; quint16 metisPort; unsigned char receiveBuffer[1032]; qint64 length; unsigned long sequence; if ((length = m_socket.readDatagram((char*) &receiveBuffer, (qint64) sizeof(receiveBuffer), &metisAddress, &metisPort)) != 1032) { qDebug() << "MetisMISOUDPHandler::dataReadyRead: readDatagram failed " << m_socket.errorString(); return; } if (receiveBuffer[0] == 0xEF && receiveBuffer[1] == 0xFE) { // valid frame switch(receiveBuffer[2]) { case 1: // IQ data switch (receiveBuffer[3]) { case 4: // EP4 data break; case 6: // EP6 data sequence = ((receiveBuffer[4] & 0xFF)<<24) + ((receiveBuffer[5] & 0xFF)<<16) + ((receiveBuffer[6] & 0xFF)<<8) +(receiveBuffer[7] & 0xFF); if (m_receiveSequence == 0) { m_receiveSequence = sequence; } else { m_receiveSequence++; if (m_receiveSequence != sequence) { //qDebug()<<"Sequence error: expected "<>24; // C1 buffer[5]= (commandValue>>16) & 0xFF; // C2 buffer[6]= (commandValue>>8) & 0xFF; // C3 buffer[7]= commandValue & 0xFF; // C4 if (m_commandBase < 18) { // base count 0 to 18 m_commandBase++; } else { m_commandBase = 0; } if (nullPayload) { std::fill(&buffer[8], &buffer[512], 0); } else { unsigned int iPart1Begin, iPart1End, iPart2Begin, iPart2End; int bufferIndex = 8; m_sampleMOFifo->readSync(63, iPart1Begin, iPart1End, iPart2Begin, iPart2End); if (iPart1Begin != iPart1End) { fillBuffer(buffer, bufferIndex, iPart1Begin, iPart1End); } if (iPart2Begin != iPart2End) { fillBuffer(buffer, bufferIndex, iPart2Begin, iPart2End); } } sendMetisBuffer(2, buffer); } m_txFrame++; } void MetisMISOUDPHandler::fillBuffer(unsigned char *buffer, int& bufferIndex, int iBegin, int iEnd) { SampleVector::iterator it = m_sampleMOFifo->getData(0).begin() + iBegin; const SampleVector::iterator itEnd = m_sampleMOFifo->getData(0).begin() + iEnd; for (; it != itEnd; ++it) { std::fill(&buffer[bufferIndex], &buffer[bufferIndex+4], 0); // Fill with zeros bufferIndex += 4; buffer[bufferIndex++] = it->imag() >> 8; buffer[bufferIndex++] = it->imag() & 0xFF; buffer[bufferIndex++] = it->real() >> 8; buffer[bufferIndex++] = it->real() & 0xFF; } } int MetisMISOUDPHandler::getCommandValue(int commandIndex) { int c1 = 0, c3 = 0, c4 = 0; if (commandIndex == 0) { c1 = m_settings.m_sampleRateIndex & 0x03; c3 = m_settings.m_preamp ? 0x04 : 0; c3 += m_settings.m_dither ? 0x08 : 0; c3 += m_settings.m_random ? 0x10 : 0; c4 = m_settings.m_duplex ? 0x04 : 0; c4 += (((m_nbReceivers-1) & 0x07)<<3); return (c1<<24) + (c3<<8) + c4; } else if (commandIndex == 2) { return getTxCenterFrequency(); } else if (commandIndex == 4) { return getRxCenterFrequency(0); } else if (commandIndex == 6) { return getRxCenterFrequency(1); } else if (commandIndex == 8) { return getRxCenterFrequency(2); } else if (commandIndex == 10) { return getRxCenterFrequency(3); } else if (commandIndex == 12) { return getRxCenterFrequency(4); } else if (commandIndex == 14) { return getRxCenterFrequency(5); } else if (commandIndex == 16) { return getRxCenterFrequency(6); } else if (commandIndex == 18) { c1 = (m_settings.m_txDrive & 0x0F) << 4; return (c1<<24) + (c3<<8) + c4; } else if (commandIndex == 36) { return getRxCenterFrequency(7); } else { return 0; } } quint64 MetisMISOUDPHandler::getRxCenterFrequency(int index) { qint64 deviceCenterFrequency; qint64 loHalfFrequency = 61440000LL - ((m_settings.m_LOppmTenths * 122880000LL) / 20000000LL); qint64 requiredRxFrequency = m_settings.m_rxCenterFrequencies[index] - (m_settings.m_rxTransverterMode ? m_settings.m_rxTransverterDeltaFrequency : 0); requiredRxFrequency = requiredRxFrequency < 0 ? 0 : requiredRxFrequency; if (m_settings.m_rxSubsamplingIndexes[index] % 2 == 0) { deviceCenterFrequency = requiredRxFrequency - m_settings.m_rxSubsamplingIndexes[index]*loHalfFrequency; } else { deviceCenterFrequency = (m_settings.m_rxSubsamplingIndexes[index] + 1)*loHalfFrequency - requiredRxFrequency; } qint64 df = ((qint64)deviceCenterFrequency * m_settings.m_LOppmTenths) / 10000000LL; deviceCenterFrequency += df; return deviceCenterFrequency < 0 ? 0 : deviceCenterFrequency > 61440000 ? 61440000 : deviceCenterFrequency; } quint64 MetisMISOUDPHandler::getTxCenterFrequency() { qint64 requiredTxFrequency = m_settings.m_txCenterFrequency - (m_settings.m_txTransverterMode ? m_settings.m_txTransverterDeltaFrequency : 0); requiredTxFrequency = requiredTxFrequency < 0 ? 0 : requiredTxFrequency; return requiredTxFrequency; } bool MetisMISOUDPHandler::getRxIQInversion(int index) { return ((m_settings.m_rxSubsamplingIndexes[index] % 2) == 1) ^ !m_settings.m_iqOrder; } void MetisMISOUDPHandler::processIQBuffer(unsigned char* buffer) { int b = 0; unsigned int r; int sampleI, sampleQ, sampleMic; if (buffer[b++]==0x7F && buffer[b++]==0x7F && buffer[b++]==0x7F) { QMutexLocker mutexLocker(&m_mutex); // extract control bytes m_controlIn[0] = buffer[b++]; m_controlIn[1] = buffer[b++]; m_controlIn[2] = buffer[b++]; m_controlIn[3] = buffer[b++]; m_controlIn[4] = buffer[b++]; // extract PTT, DOT and DASH m_ptt = (m_controlIn[0] & 0x01) == 0x01; m_dash = (m_controlIn[0] & 0x02) == 0x02; m_dot = (m_controlIn[0] & 0x04) == 0x04; switch((m_controlIn[0]>>3) & 0x1F) { case 0: m_lt2208ADCOverflow = m_controlIn[1] & 0x01; m_IO1 = (m_controlIn[1] & 0x02) ? 0 : 1; m_IO2 = (m_controlIn[1] & 0x04) ? 0 : 1; m_IO3 = (m_controlIn[1] & 0x08) ? 0 : 1; // { // int nbRx = (m_controlIn[4]>>3) & 0x07; // nbRx++; // qDebug("MetisMISOUDPHandler::processIQBuffer: nbRx: %d", nbRx); // } if (m_mercurySoftwareVersion != m_controlIn[2]) { m_mercurySoftwareVersion = m_controlIn[2]; qDebug("MetisMISOUDPHandler::processIQBuffer: Mercury Software version: %d (0x%0X)", m_mercurySoftwareVersion, m_mercurySoftwareVersion); } if (m_penelopeSoftwareVersion != m_controlIn[3]) { m_penelopeSoftwareVersion = m_controlIn[3]; qDebug("MetisMISOUDPHandler::processIQBuffer: Penelope Software version: %d (0x%0X)", m_penelopeSoftwareVersion, m_penelopeSoftwareVersion); } if (m_ozySoftwareVersion != m_controlIn[4]) { m_ozySoftwareVersion = m_controlIn[4]; qDebug("MetisMISOUDPHandler::processIQBuffer: Ozy Software version: %d (0x%0X)", m_ozySoftwareVersion, m_ozySoftwareVersion); } break; case 1: m_forwardPower = (m_controlIn[1]<<8) + m_controlIn[2]; // from Penelope or Hermes m_alexForwardPower = (m_controlIn[3]<<8) + m_controlIn[4]; // from Alex or Apollo break; case 2: m_alexForwardPower = (m_controlIn[1]<<8) + m_controlIn[2]; // from Alex or Apollo m_AIN3 = (m_controlIn[3]<<8) + m_controlIn[4]; // from Pennelope or Hermes break; case 3: m_AIN4 = (m_controlIn[1]<<8) + m_controlIn[2]; // from Pennelope or Hermes m_AIN6 = (m_controlIn[3]<<8) + m_controlIn[4]; // from Pennelope or Hermes break; } // extract the samples while (b < m_bMax) { int samplesAdded = 0; // extract each of the receivers for (r = 0; r < m_nbReceivers; r++) { if (SDR_RX_SAMP_SZ == 16) { sampleQ = (int)((signed char)buffer[b++]) << 8; sampleQ += (int)((unsigned char)buffer[b++]); b++; sampleI = (int)((signed char)buffer[b++]) << 8; sampleI += (int)((unsigned char)buffer[b++]); b++; } else { sampleQ = (int)((signed char)buffer[b++]) << 16; sampleQ += (int)((unsigned char)buffer[b++]) << 8; sampleQ += (int)((unsigned char)buffer[b++]); sampleI = (int)((signed char)buffer[b++]) << 16; sampleI += (int)((unsigned char)buffer[b++]) << 8; sampleI += (int)((unsigned char)buffer[b++]); } if (r < MetisMISOSettings::m_maxReceivers) { if (m_settings.m_log2Decim == 0) // no decimation - direct conversion { m_convertBuffer[r][m_sampleCount] = getRxIQInversion(r) ? Sample{sampleQ, sampleI} : Sample{sampleI, sampleQ}; samplesAdded = 1; } else { SampleVector v(2, Sample{0, 0}); switch (m_settings.m_log2Decim) { case 1: samplesAdded = getRxIQInversion(r) ? m_decimators.decimate2(sampleQ, sampleI, v, r) : m_decimators.decimate2(sampleI, sampleQ, v, r); break; case 2: samplesAdded = getRxIQInversion(r) ? m_decimators.decimate4(sampleQ, sampleI, v, r) : m_decimators.decimate4(sampleI, sampleQ, v, r); break; case 3: samplesAdded = getRxIQInversion(r) ? m_decimators.decimate8(sampleQ, sampleI, v, r) : m_decimators.decimate8(sampleI, sampleQ, v, r); break; default: break; } if (samplesAdded != 0) { std::copy( v.begin(), v.begin() + samplesAdded, &m_convertBuffer[r][m_sampleCount] ); } } } } sampleMic = (int)((signed char) buffer[b++]) << 8; sampleMic += (int)((unsigned char)buffer[b++]); m_sampleTxCount++; if (m_sampleTxCount >= 63) // 63 samples per 512 byte Tx block { sendData(!m_settings.m_txEnable); // synchronous sending of a Tx frame m_sampleTxCount = 0; } if (samplesAdded != 0) { m_sampleCount += samplesAdded; if (m_sampleCount >= 1024) { std::vector vbegin; for (unsigned int channel = 0; channel < MetisMISOSettings::m_maxReceivers; channel++) { vbegin.push_back(m_convertBuffer[channel].begin()); } m_sampleMIFifo->writeSync(vbegin, 1024); m_sampleCount = 0; } } } } else { qDebug()<<"MetisMISOUDPHandler::processIQBuffer: SYNC Error"; } m_rxFrame++; }