#include "DemodulatorThread.h" #include "CubicSDRDefs.h" #include #ifdef __APPLE__ #include #endif DemodulatorThread::DemodulatorThread(DemodulatorThreadPostInputQueue* pQueue, DemodulatorThreadControlCommandQueue *threadQueueControl, DemodulatorThreadCommandQueue* threadQueueNotify) : postInputQueue(pQueue), visOutQueue(NULL), audioInputQueue(NULL), agc(NULL), stereo(false), terminated(false), threadQueueNotify( threadQueueNotify), threadQueueControl(threadQueueControl), squelch_level(0), squelch_tolerance(0), squelch_enabled(false) { float kf = 0.5; // modulation factor fdem = freqdem_create(kf); // freqdem_print(fdem); } DemodulatorThread::~DemodulatorThread() { } #ifdef __APPLE__ void *DemodulatorThread::threadMain() { #else void DemodulatorThread::threadMain() { #endif #ifdef __APPLE__ pthread_t tID = pthread_self(); // ID of this thread int priority = sched_get_priority_max( SCHED_FIFO )-1; sched_param prio = {priority}; // scheduling priority of thread pthread_setschedparam(tID, SCHED_FIFO, &prio); #endif msresamp_rrrf audio_resampler = NULL; msresamp_rrrf stereo_resampler = NULL; msresamp_crcf resampler = NULL; unsigned int m=5; // filter semi-length float slsl=60.0f; // filter sidelobe suppression level liquid_float_complex x, y; firhilbf firR2C = firhilbf_create(m,slsl); firhilbf firC2R = firhilbf_create(m,slsl); nco_crcf nco_shift = nco_crcf_create(LIQUID_NCO); float shift_freq = 0; agc = agc_crcf_create(); agc_crcf_set_bandwidth(agc, 1e-3f); std::cout << "Demodulator thread started.." << std::endl; std::deque buffers; std::deque::iterator buffers_i; std::vector resampled_data; std::vector agc_data; std::vector demod_output; std::vector demod_output_stereo; std::vector resampled_audio_output; std::vector resampled_audio_output_stereo; double freq_index = 0; while (!terminated) { DemodulatorThreadPostIQData *inp; postInputQueue->pop(inp); std::lock_guard < std::mutex > lock(inp->m_mutex); int bufSize = inp->data.size(); if (!bufSize) { inp->decRefCount(); continue; } if (resampler == NULL) { resampler = inp->resampler; audio_resampler = inp->audio_resampler; stereo_resampler = inp->stereo_resampler; } else if (resampler != inp->resampler) { msresamp_crcf_destroy(resampler); msresamp_rrrf_destroy(audio_resampler); msresamp_rrrf_destroy(stereo_resampler); resampler = inp->resampler; audio_resampler = inp->audio_resampler; stereo_resampler = inp->stereo_resampler; } int out_size = ceil((float) (bufSize) * inp->resample_ratio); if (agc_data.size() != out_size) { if (agc_data.capacity() < out_size) { agc_data.reserve(out_size); resampled_data.reserve(out_size); } agc_data.resize(out_size); resampled_data.resize(out_size); } unsigned int num_written; msresamp_crcf_execute(resampler, &(inp->data[0]), bufSize, &resampled_data[0], &num_written); agc_crcf_execute_block(agc, &resampled_data[0], num_written, &agc_data[0]); float audio_resample_ratio = inp->audio_resample_ratio; if (demod_output.size() != num_written) { if (demod_output.capacity() < num_written) { demod_output.reserve(num_written); demod_output_stereo.reserve(num_written); } demod_output.resize(num_written); demod_output_stereo.resize(num_written); } freqdem_demodulate_block(fdem, &agc_data[0], num_written, &demod_output[0]); if (stereo) { double freq = (2.0 * M_PI) * (((float) abs(38000)) / ((float) inp->bandwidth)); if (shift_freq != freq) { nco_crcf_set_frequency(nco_shift, freq); shift_freq = freq; } for (int i = 0; i < num_written; i++) { firhilbf_r2c_execute(firR2C,demod_output[i],&x); nco_crcf_mix_down(nco_shift, x, &y); nco_crcf_step(nco_shift); firhilbf_c2r_execute(firR2C,y,&demod_output_stereo[i]); } } int audio_out_size = ceil((float) (num_written) * audio_resample_ratio); if (audio_out_size != resampled_audio_output.size()) { if (resampled_audio_output.capacity() < audio_out_size) { resampled_audio_output.reserve(audio_out_size); resampled_audio_output_stereo.reserve(audio_out_size); } resampled_audio_output.resize(audio_out_size); resampled_audio_output_stereo.resize(audio_out_size); } unsigned int num_audio_written; msresamp_rrrf_execute(audio_resampler, &demod_output[0], num_written, &resampled_audio_output[0], &num_audio_written); if (stereo) { msresamp_rrrf_execute(stereo_resampler, &demod_output_stereo[0], num_written, &resampled_audio_output_stereo[0], &num_audio_written); } if (audioInputQueue != NULL) { if (!squelch_enabled || ((agc_crcf_get_signal_level(agc)) >= 0.1)) { AudioThreadInput *ati = NULL; for (buffers_i = buffers.begin(); buffers_i != buffers.end(); buffers_i++) { if ((*buffers_i)->getRefCount() <= 0) { ati = (*buffers_i); break; } } if (ati == NULL) { ati = new AudioThreadInput; buffers.push_back(ati); } ati->setRefCount(1); if (stereo) { ati->channels = 2; ati->data.resize(num_audio_written * 2); for (int i = 0; i < num_audio_written; i++) { ati->data[i * 2] = (resampled_audio_output[i] - (resampled_audio_output_stereo[i])); ati->data[i * 2 + 1] = (resampled_audio_output[i] + (resampled_audio_output_stereo[i])); } } else { ati->channels = 1; ati->data.assign(resampled_audio_output.begin(), resampled_audio_output.begin() + num_audio_written); } audioInputQueue->push(ati); } } if (visOutQueue != NULL && visOutQueue->empty()) { AudioThreadInput *ati_vis = new AudioThreadInput; ati_vis->channels = 1; int num_vis = DEMOD_VIS_SIZE; if (stereo) { int stereoSize = resampled_audio_output.size(); if (stereoSize > DEMOD_VIS_SIZE) { stereoSize = DEMOD_VIS_SIZE; } ati_vis->data.resize(stereoSize); ati_vis->channels = stereo?2:1; for (int i = 0; i < stereoSize / 2; i++) { ati_vis->data[i] = (resampled_audio_output[i] - (resampled_audio_output_stereo[i])); ati_vis->data[i + stereoSize / 2] = (resampled_audio_output[i] + (resampled_audio_output_stereo[i])); } } else { if (num_audio_written > num_written) { if (num_vis > num_audio_written) { num_vis = num_audio_written; } ati_vis->data.assign(resampled_audio_output.begin(), resampled_audio_output.begin() + num_vis); } else { if (num_vis > num_written) { num_vis = num_written; } ati_vis->data.assign(demod_output.begin(), demod_output.begin() + num_vis); } // std::cout << "Signal: " << agc_crcf_get_signal_level(agc) << " -- " << agc_crcf_get_rssi(agc) << "dB " << std::endl; } visOutQueue->push(ati_vis); } if (!threadQueueControl->empty()) { while (!threadQueueControl->empty()) { DemodulatorThreadControlCommand command; threadQueueControl->pop(command); switch (command.cmd) { case DemodulatorThreadControlCommand::DEMOD_THREAD_CMD_CTL_SQUELCH_AUTO: squelch_level = agc_crcf_get_signal_level(agc); squelch_tolerance = agc_crcf_get_signal_level(agc) / 2.0; squelch_enabled = true; break; case DemodulatorThreadControlCommand::DEMOD_THREAD_CMD_CTL_SQUELCH_OFF: squelch_level = 0; squelch_tolerance = 1; squelch_enabled = false; break; default: break; } } } inp->decRefCount(); } if (resampler != NULL) { msresamp_crcf_destroy(resampler); } if (audio_resampler != NULL) { msresamp_rrrf_destroy(audio_resampler); } if (stereo_resampler != NULL) { msresamp_rrrf_destroy(stereo_resampler); } agc_crcf_destroy(agc); firhilbf_destroy(firR2C); firhilbf_destroy(firC2R); nco_crcf_destroy(nco_shift); while (!buffers.empty()) { AudioThreadInput *audioDataDel = buffers.front(); buffers.pop_front(); std::lock_guard < std::mutex > lock(audioDataDel->m_mutex); delete audioDataDel; } std::cout << "Demodulator thread done." << std::endl; DemodulatorThreadCommand tCmd(DemodulatorThreadCommand::DEMOD_THREAD_CMD_DEMOD_TERMINATED); tCmd.context = this; threadQueueNotify->push(tCmd); } void DemodulatorThread::terminate() { terminated = true; DemodulatorThreadPostIQData *inp = new DemodulatorThreadPostIQData; // push dummy to nudge queue postInputQueue->push(inp); } void DemodulatorThread::setStereo(bool state) { stereo = state; std::cout << "Stereo " << (state ? "Enabled" : "Disabled") << std::endl; } bool DemodulatorThread::isStereo() { return stereo; }