/*! * \file gps_l1_ca_dll_pll_tracking_gpu_cc.cc * \brief Implementation of a code DLL + carrier PLL tracking block, GPU ACCELERATED * \author Javier Arribas, 2015. jarribas(at)cttc.es * * Code DLL + carrier PLL according to the algorithms described in: * [1] K.Borre, D.M.Akos, N.Bertelsen, P.Rinder, and S.H.Jensen, * A Software-Defined GPS and Galileo Receiver. A Single-Frequency * Approach, Birkhauser, 2007 * * ------------------------------------------------------------------------- * * Copyright (C) 2010-2015 (see AUTHORS file for a list of contributors) * * GNSS-SDR is a software defined Global Navigation * Satellite Systems receiver * * This file is part of GNSS-SDR. * * GNSS-SDR 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, either version 3 of the License, or * (at your option) any later version. * * GNSS-SDR 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 for more details. * * You should have received a copy of the GNU General Public License * along with GNSS-SDR. If not, see . * * ------------------------------------------------------------------------- */ #include "gps_l1_ca_dll_pll_tracking_gpu_cc.h" #include #include #include #include #include #include #include #include "gnss_synchro.h" #include "gps_sdr_signal_processing.h" #include "tracking_discriminators.h" #include "lock_detectors.h" #include "GPS_L1_CA.h" #include "control_message_factory.h" #include //volk_alignement // includes #include #include // helper for shared functions common to CUDA Samples #include // helper functions for CUDA error checking and initialization /*! * \todo Include in definition header file */ #define CN0_ESTIMATION_SAMPLES 20 #define MINIMUM_VALID_CN0 25 #define MAXIMUM_LOCK_FAIL_COUNTER 50 #define CARRIER_LOCK_THRESHOLD 0.85 using google::LogMessage; gps_l1_ca_dll_pll_tracking_gpu_cc_sptr gps_l1_ca_dll_pll_make_tracking_gpu_cc( long if_freq, long fs_in, unsigned int vector_length, boost::shared_ptr queue, bool dump, std::string dump_filename, float pll_bw_hz, float dll_bw_hz, float early_late_space_chips) { return gps_l1_ca_dll_pll_tracking_gpu_cc_sptr(new Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc(if_freq, fs_in, vector_length, queue, dump, dump_filename, pll_bw_hz, dll_bw_hz, early_late_space_chips)); } void Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::forecast (int noutput_items, gr_vector_int &ninput_items_required) { ninput_items_required[0] = static_cast(d_vector_length) * 2; //set the required available samples in each call } Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc( long if_freq, long fs_in, unsigned int vector_length, boost::shared_ptr queue, bool dump, std::string dump_filename, float pll_bw_hz, float dll_bw_hz, float early_late_space_chips) : gr::block("Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc", gr::io_signature::make(1, 1, sizeof(gr_complex)), gr::io_signature::make(1, 1, sizeof(Gnss_Synchro))) { // initialize internal vars d_queue = queue; d_dump = dump; d_if_freq = if_freq; d_fs_in = fs_in; d_vector_length = vector_length; d_dump_filename = dump_filename; // Initialize tracking ========================================== d_code_loop_filter.set_DLL_BW(dll_bw_hz); d_carrier_loop_filter.set_PLL_BW(pll_bw_hz); //--- DLL variables -------------------------------------------------------- d_early_late_spc_chips = early_late_space_chips; // Define early-late offset (in chips) // Initialization of local code replica // Get space for a vector with the C/A code replica sampled 1x/chip //d_ca_code = static_cast(volk_malloc((GPS_L1_CA_CODE_LENGTH_CHIPS + 2) * sizeof(gr_complex), volk_get_alignment())); d_ca_code = static_cast(volk_malloc((GPS_L1_CA_CODE_LENGTH_CHIPS) * sizeof(gr_complex), volk_get_alignment())); multicorrelator_gpu = new cuda_multicorrelator(); int N_CORRELATORS = 3; //local code resampler on CPU (old) //multicorrelator_gpu->init_cuda(0, NULL, 2 * d_vector_length , 2 * d_vector_length , N_CORRELATORS); //local code resampler on GPU (new) multicorrelator_gpu->init_cuda_integrated_resampler(0, NULL, 2 * d_vector_length , GPS_L1_CA_CODE_LENGTH_CHIPS , N_CORRELATORS); // Get space for the resampled early / prompt / late local replicas checkCudaErrors(cudaHostAlloc((void**)&d_local_code_shift_chips, N_CORRELATORS * sizeof(float), cudaHostAllocMapped )); //allocate host memory //pinned memory mode - use special function to get OS-pinned memory checkCudaErrors(cudaHostAlloc((void**)&in_gpu, 2 * d_vector_length * sizeof(gr_complex), cudaHostAllocMapped )); //old local codes vector //checkCudaErrors(cudaHostAlloc((void**)&d_local_codes_gpu, (V_LEN * sizeof(gr_complex))*N_CORRELATORS, cudaHostAllocWriteCombined )); //new integrated shifts //checkCudaErrors(cudaHostAlloc((void**)&d_local_codes_gpu, (2 * d_vector_length * sizeof(gr_complex)), cudaHostAllocWriteCombined )); // correlator outputs (scalar) checkCudaErrors(cudaHostAlloc((void**)&d_corr_outs_gpu ,sizeof(gr_complex)*N_CORRELATORS, cudaHostAllocWriteCombined )); //map to EPL pointers d_Early = &d_corr_outs_gpu[0]; d_Prompt = &d_corr_outs_gpu[1]; d_Late = &d_corr_outs_gpu[2]; //--- Perform initializations ------------------------------ // define initial code frequency basis of NCO d_code_freq_chips = GPS_L1_CA_CODE_RATE_HZ; // define residual code phase (in chips) d_rem_code_phase_samples = 0.0; // define residual carrier phase d_rem_carr_phase_rad = 0.0; // sample synchronization d_sample_counter = 0; //d_sample_counter_seconds = 0; d_acq_sample_stamp = 0; d_enable_tracking = false; d_pull_in = false; d_last_seg = 0; d_current_prn_length_samples = static_cast(d_vector_length); // CN0 estimation and lock detector buffers d_cn0_estimation_counter = 0; d_Prompt_buffer = new gr_complex[CN0_ESTIMATION_SAMPLES]; d_carrier_lock_test = 1; d_CN0_SNV_dB_Hz = 0; d_carrier_lock_fail_counter = 0; d_carrier_lock_threshold = CARRIER_LOCK_THRESHOLD; systemName["G"] = std::string("GPS"); systemName["S"] = std::string("SBAS"); set_relative_rate(1.0/((double)d_vector_length*2)); d_channel_internal_queue = 0; d_acquisition_gnss_synchro = 0; d_channel = 0; d_acq_code_phase_samples = 0.0; d_acq_carrier_doppler_hz = 0.0; d_carrier_doppler_hz = 0.0; d_acc_carrier_phase_rad = 0.0; d_code_phase_samples = 0.0; d_acc_code_phase_secs = 0.0; //set_min_output_buffer((long int)300); } void Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::start_tracking() { /* * correct the code phase according to the delay between acq and trk */ d_acq_code_phase_samples = d_acquisition_gnss_synchro->Acq_delay_samples; d_acq_carrier_doppler_hz = d_acquisition_gnss_synchro->Acq_doppler_hz; d_acq_sample_stamp = d_acquisition_gnss_synchro->Acq_samplestamp_samples; long int acq_trk_diff_samples; float acq_trk_diff_seconds; acq_trk_diff_samples = static_cast(d_sample_counter) - static_cast(d_acq_sample_stamp);//-d_vector_length; DLOG(INFO) << "Number of samples between Acquisition and Tracking =" << acq_trk_diff_samples; acq_trk_diff_seconds = static_cast(acq_trk_diff_samples) / static_cast(d_fs_in); //doppler effect // Fd=(C/(C+Vr))*F float radial_velocity = (GPS_L1_FREQ_HZ + d_acq_carrier_doppler_hz) / GPS_L1_FREQ_HZ; // new chip and prn sequence periods based on acq Doppler float T_chip_mod_seconds; float T_prn_mod_seconds; float T_prn_mod_samples; d_code_freq_chips = radial_velocity * GPS_L1_CA_CODE_RATE_HZ; T_chip_mod_seconds = 1/d_code_freq_chips; T_prn_mod_seconds = T_chip_mod_seconds * GPS_L1_CA_CODE_LENGTH_CHIPS; T_prn_mod_samples = T_prn_mod_seconds * static_cast(d_fs_in); d_current_prn_length_samples = round(T_prn_mod_samples); float T_prn_true_seconds = GPS_L1_CA_CODE_LENGTH_CHIPS / GPS_L1_CA_CODE_RATE_HZ; float T_prn_true_samples = T_prn_true_seconds * static_cast(d_fs_in); float T_prn_diff_seconds= T_prn_true_seconds - T_prn_mod_seconds; float N_prn_diff = acq_trk_diff_seconds / T_prn_true_seconds; float corrected_acq_phase_samples, delay_correction_samples; corrected_acq_phase_samples = fmod((d_acq_code_phase_samples + T_prn_diff_seconds * N_prn_diff * static_cast(d_fs_in)), T_prn_true_samples); if (corrected_acq_phase_samples < 0) { corrected_acq_phase_samples = T_prn_mod_samples + corrected_acq_phase_samples; } delay_correction_samples = d_acq_code_phase_samples - corrected_acq_phase_samples; d_acq_code_phase_samples = corrected_acq_phase_samples; d_carrier_doppler_hz = d_acq_carrier_doppler_hz; // DLL/PLL filter initialization d_carrier_loop_filter.initialize(); // initialize the carrier filter d_code_loop_filter.initialize(); // initialize the code filter // generate local reference ALWAYS starting at chip 1 (1 sample per chip) gps_l1_ca_code_gen_complex(d_ca_code, d_acquisition_gnss_synchro->PRN, 0); d_local_code_shift_chips[0]=-d_early_late_spc_chips; d_local_code_shift_chips[1]=0.0; d_local_code_shift_chips[2]=d_early_late_spc_chips; multicorrelator_gpu->set_local_code_and_taps(GPS_L1_CA_CODE_LENGTH_CHIPS,d_ca_code, d_local_code_shift_chips,3); d_carrier_lock_fail_counter = 0; d_rem_code_phase_samples = 0; d_rem_carr_phase_rad = 0; d_acc_carrier_phase_rad = 0; d_acc_code_phase_secs = 0; d_code_phase_samples = d_acq_code_phase_samples; std::string sys_ = &d_acquisition_gnss_synchro->System; sys = sys_.substr(0,1); // DEBUG OUTPUT std::cout << "Tracking start on channel " << d_channel << " for satellite " << Gnss_Satellite(systemName[sys], d_acquisition_gnss_synchro->PRN) << std::endl; LOG(INFO) << "Starting tracking of satellite " << Gnss_Satellite(systemName[sys], d_acquisition_gnss_synchro->PRN) << " on channel " << d_channel; // enable tracking d_pull_in = true; d_enable_tracking = true; LOG(INFO) << "PULL-IN Doppler [Hz]=" << d_carrier_doppler_hz << " Code Phase correction [samples]=" << delay_correction_samples << " PULL-IN Code Phase [samples]=" << d_acq_code_phase_samples; } Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::~Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc() { d_dump_file.close(); cudaFreeHost(in_gpu); cudaFreeHost(d_carr_sign_gpu); cudaFreeHost(d_corr_outs_gpu); cudaFreeHost(d_local_code_shift_chips); multicorrelator_gpu->free_cuda(); delete(multicorrelator_gpu); volk_free(d_ca_code); delete[] d_Prompt_buffer; } int Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::general_work (int noutput_items, gr_vector_int &ninput_items, gr_vector_const_void_star &input_items, gr_vector_void_star &output_items) { // process vars float carr_error_hz=0.0; float carr_error_filt_hz=0.0; float code_error_chips=0.0; float code_error_filt_chips=0.0; // Block input data and block output stream pointers const gr_complex* in = (gr_complex*) input_items[0]; Gnss_Synchro **out = (Gnss_Synchro **) &output_items[0]; // GNSS_SYNCHRO OBJECT to interchange data between tracking->telemetry_decoder Gnss_Synchro current_synchro_data = Gnss_Synchro(); if (d_enable_tracking == true) { // Receiver signal alignment if (d_pull_in == true) { int samples_offset; int acq_to_trk_delay_samples; acq_to_trk_delay_samples = d_sample_counter - d_acq_sample_stamp; samples_offset = round(d_acq_code_phase_samples)+d_current_prn_length_samples - acq_to_trk_delay_samples%d_current_prn_length_samples; d_sample_counter = d_sample_counter + samples_offset; //count for the processed samples d_pull_in = false; // Fill the acquisition data current_synchro_data = *d_acquisition_gnss_synchro; *out[0] = current_synchro_data; consume_each(samples_offset); //shift input to perform alignment with local replica return 1; } // Fill the acquisition data current_synchro_data = *d_acquisition_gnss_synchro; // UPDATE NCO COMMAND float phase_step_rad = static_cast(GPS_TWO_PI) * d_carrier_doppler_hz / static_cast(d_fs_in); //code resampler on GPU (new) float code_phase_step_chips = static_cast(d_code_freq_chips) / static_cast(d_fs_in); float rem_code_phase_chips = d_rem_code_phase_samples * (d_code_freq_chips / d_fs_in); cudaProfilerStart(); multicorrelator_gpu->Carrier_wipeoff_multicorrelator_resampler_cuda( d_corr_outs_gpu, in, d_rem_carr_phase_rad, phase_step_rad, code_phase_step_chips, rem_code_phase_chips, d_current_prn_length_samples, 3); cudaProfilerStop(); // ################## PLL ########################################################## // PLL discriminator carr_error_hz = pll_cloop_two_quadrant_atan(*d_Prompt) / static_cast(GPS_TWO_PI); // Carrier discriminator filter carr_error_filt_hz = d_carrier_loop_filter.get_carrier_nco(carr_error_hz); // New carrier Doppler frequency estimation d_carrier_doppler_hz = d_acq_carrier_doppler_hz + carr_error_filt_hz; // New code Doppler frequency estimation d_code_freq_chips = GPS_L1_CA_CODE_RATE_HZ + ((d_carrier_doppler_hz * GPS_L1_CA_CODE_RATE_HZ) / GPS_L1_FREQ_HZ); //carrier phase accumulator for (K) doppler estimation d_acc_carrier_phase_rad = d_acc_carrier_phase_rad + GPS_TWO_PI * d_carrier_doppler_hz * GPS_L1_CA_CODE_PERIOD; //remanent carrier phase to prevent overflow in the code NCO d_rem_carr_phase_rad = d_rem_carr_phase_rad + GPS_TWO_PI * d_carrier_doppler_hz * GPS_L1_CA_CODE_PERIOD; d_rem_carr_phase_rad = fmod(d_rem_carr_phase_rad, GPS_TWO_PI); // ################## DLL ########################################################## // DLL discriminator code_error_chips = dll_nc_e_minus_l_normalized(*d_Early, *d_Late); //[chips/Ti] // Code discriminator filter code_error_filt_chips = d_code_loop_filter.get_code_nco(code_error_chips); //[chips/second] //Code phase accumulator float code_error_filt_secs; code_error_filt_secs = (GPS_L1_CA_CODE_PERIOD * code_error_filt_chips) / GPS_L1_CA_CODE_RATE_HZ; //[seconds] d_acc_code_phase_secs = d_acc_code_phase_secs + code_error_filt_secs; // ################## CARRIER AND CODE NCO BUFFER ALIGNEMENT ####################### // keep alignment parameters for the next input buffer double T_chip_seconds; double T_prn_seconds; double T_prn_samples; double K_blk_samples; // Compute the next buffer length based in the new period of the PRN sequence and the code phase error estimation T_chip_seconds = 1 / static_cast(d_code_freq_chips); T_prn_seconds = T_chip_seconds * GPS_L1_CA_CODE_LENGTH_CHIPS; T_prn_samples = T_prn_seconds * static_cast(d_fs_in); K_blk_samples = T_prn_samples + d_rem_code_phase_samples + static_cast(code_error_filt_secs) * static_cast(d_fs_in); //d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error < 1 sample // ####### CN0 ESTIMATION AND LOCK DETECTORS ###### if (d_cn0_estimation_counter < CN0_ESTIMATION_SAMPLES) { // fill buffer with prompt correlator output values d_Prompt_buffer[d_cn0_estimation_counter] = *d_Prompt; d_cn0_estimation_counter++; } else { d_cn0_estimation_counter = 0; // Code lock indicator d_CN0_SNV_dB_Hz = cn0_svn_estimator(d_Prompt_buffer, CN0_ESTIMATION_SAMPLES, d_fs_in, GPS_L1_CA_CODE_LENGTH_CHIPS); // Carrier lock indicator d_carrier_lock_test = carrier_lock_detector(d_Prompt_buffer, CN0_ESTIMATION_SAMPLES); // Loss of lock detection if (d_carrier_lock_test < d_carrier_lock_threshold or d_CN0_SNV_dB_Hz < MINIMUM_VALID_CN0) { d_carrier_lock_fail_counter++; } else { if (d_carrier_lock_fail_counter > 0) d_carrier_lock_fail_counter--; } if (d_carrier_lock_fail_counter > MAXIMUM_LOCK_FAIL_COUNTER) { std::cout << "Loss of lock in channel " << d_channel << "!" << std::endl; LOG(INFO) << "Loss of lock in channel " << d_channel << "!"; std::unique_ptr cmf(new ControlMessageFactory()); if (d_queue != gr::msg_queue::sptr()) { d_queue->handle(cmf->GetQueueMessage(d_channel, 2)); } d_carrier_lock_fail_counter = 0; d_enable_tracking = false; // TODO: check if disabling tracking is consistent with the channel state machine } } // ########### Output the tracking data to navigation and PVT ########## current_synchro_data.Prompt_I = static_cast((*d_Prompt).real()); current_synchro_data.Prompt_Q = static_cast((*d_Prompt).imag()); // Tracking_timestamp_secs is aligned with the NEXT PRN start sample (Hybridization problem!) //compute remnant code phase samples BEFORE the Tracking timestamp //d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error < 1 sample //current_synchro_data.Tracking_timestamp_secs = ((double)d_sample_counter + (double)d_current_prn_length_samples + (double)d_rem_code_phase_samples)/static_cast(d_fs_in); // Tracking_timestamp_secs is aligned with the CURRENT PRN start sample (Hybridization OK!, but some glitches??) current_synchro_data.Tracking_timestamp_secs = (static_cast(d_sample_counter) + static_cast(d_rem_code_phase_samples)) / static_cast(d_fs_in); //compute remnant code phase samples AFTER the Tracking timestamp d_rem_code_phase_samples = K_blk_samples - d_current_prn_length_samples; //rounding error < 1 sample //current_synchro_data.Tracking_timestamp_secs = ((double)d_sample_counter)/static_cast(d_fs_in); // This tracking block aligns the Tracking_timestamp_secs with the start sample of the PRN, thus, Code_phase_secs=0 current_synchro_data.Code_phase_secs = 0; current_synchro_data.Carrier_phase_rads = static_cast(d_acc_carrier_phase_rad); current_synchro_data.Carrier_Doppler_hz = static_cast(d_carrier_doppler_hz); current_synchro_data.CN0_dB_hz = static_cast(d_CN0_SNV_dB_Hz); current_synchro_data.Flag_valid_pseudorange = false; *out[0] = current_synchro_data; // ########## DEBUG OUTPUT /*! * \todo The stop timer has to be moved to the signal source! */ // debug: Second counter in channel 0 if (d_channel == 0) { if (floor(d_sample_counter / d_fs_in) != d_last_seg) { d_last_seg = floor(d_sample_counter / d_fs_in); std::cout << "Current input signal time = " << d_last_seg << " [s]" << std::endl; DLOG(INFO) << "GPS L1 C/A Tracking CH " << d_channel << ": Satellite " << Gnss_Satellite(systemName[sys], d_acquisition_gnss_synchro->PRN) << ", CN0 = " << d_CN0_SNV_dB_Hz << " [dB-Hz]" << std::endl; //if (d_last_seg==5) d_carrier_lock_fail_counter=500; //DEBUG: force unlock! } } else { if (floor(d_sample_counter / d_fs_in) != d_last_seg) { d_last_seg = floor(d_sample_counter / d_fs_in); DLOG(INFO) << "Tracking CH " << d_channel << ": Satellite " << Gnss_Satellite(systemName[sys], d_acquisition_gnss_synchro->PRN) << ", CN0 = " << d_CN0_SNV_dB_Hz << " [dB-Hz]"; } } } else { // ########## DEBUG OUTPUT (TIME ONLY for channel 0 when tracking is disabled) /*! * \todo The stop timer has to be moved to the signal source! */ // stream to collect cout calls to improve thread safety std::stringstream tmp_str_stream; if (floor(d_sample_counter / d_fs_in) != d_last_seg) { d_last_seg = floor(d_sample_counter / d_fs_in); if (d_channel == 0) { // debug: Second counter in channel 0 tmp_str_stream << "Current input signal time = " << d_last_seg << " [s]" << std::endl << std::flush; std::cout << tmp_str_stream.rdbuf() << std::flush; } } *d_Early = gr_complex(0,0); *d_Prompt = gr_complex(0,0); *d_Late = gr_complex(0,0); current_synchro_data.System = {'G'}; current_synchro_data.Flag_valid_pseudorange = false; *out[0] = current_synchro_data; } if(d_dump) { // MULTIPLEXED FILE RECORDING - Record results to file float prompt_I; float prompt_Q; float tmp_E, tmp_P, tmp_L; float tmp_float; double tmp_double; prompt_I = (*d_Prompt).real(); prompt_Q = (*d_Prompt).imag(); tmp_E = std::abs(*d_Early); tmp_P = std::abs(*d_Prompt); tmp_L = std::abs(*d_Late); try { // EPR d_dump_file.write(reinterpret_cast(&tmp_E), sizeof(float)); d_dump_file.write(reinterpret_cast(&tmp_P), sizeof(float)); d_dump_file.write(reinterpret_cast(&tmp_L), sizeof(float)); // PROMPT I and Q (to analyze navigation symbols) d_dump_file.write(reinterpret_cast(&prompt_I), sizeof(float)); d_dump_file.write(reinterpret_cast(&prompt_Q), sizeof(float)); // PRN start sample stamp //tmp_float=(float)d_sample_counter; d_dump_file.write(reinterpret_cast(&d_sample_counter), sizeof(unsigned long int)); // accumulated carrier phase d_dump_file.write(reinterpret_cast(&d_acc_carrier_phase_rad), sizeof(float)); // carrier and code frequency d_dump_file.write(reinterpret_cast(&d_carrier_doppler_hz), sizeof(float)); tmp_float=d_code_freq_chips; d_dump_file.write(reinterpret_cast(&tmp_float), sizeof(float)); //PLL commands d_dump_file.write(reinterpret_cast(&carr_error_hz), sizeof(float)); d_dump_file.write(reinterpret_cast(&carr_error_filt_hz), sizeof(float)); //DLL commands d_dump_file.write(reinterpret_cast(&code_error_chips), sizeof(float)); d_dump_file.write(reinterpret_cast(&code_error_filt_chips), sizeof(float)); // CN0 and carrier lock test d_dump_file.write(reinterpret_cast(&d_CN0_SNV_dB_Hz), sizeof(float)); d_dump_file.write(reinterpret_cast(&d_carrier_lock_test), sizeof(float)); // AUX vars (for debug purposes) tmp_float = d_rem_code_phase_samples; d_dump_file.write(reinterpret_cast(&tmp_float), sizeof(float)); tmp_double = static_cast(d_sample_counter + d_current_prn_length_samples); d_dump_file.write(reinterpret_cast(&tmp_double), sizeof(double)); } catch (std::ifstream::failure e) { LOG(WARNING) << "Exception writing trk dump file " << e.what(); } } consume_each(d_current_prn_length_samples); // this is necessary in gr::block derivates d_sample_counter += d_current_prn_length_samples; //count for the processed samples //LOG(INFO)<<"GPS tracking output end on CH="<d_channel << " SAMPLE STAMP="<(d_channel)); d_dump_filename.append(".dat"); d_dump_file.exceptions (std::ifstream::failbit | std::ifstream::badbit); d_dump_file.open(d_dump_filename.c_str(), std::ios::out | std::ios::binary); LOG(INFO) << "Tracking dump enabled on channel " << d_channel << " Log file: " << d_dump_filename.c_str() << std::endl; } catch (std::ifstream::failure e) { LOG(WARNING) << "channel " << d_channel << " Exception opening trk dump file " << e.what() << std::endl; } } } } void Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::set_channel_queue(concurrent_queue *channel_internal_queue) { d_channel_internal_queue = channel_internal_queue; } void Gps_L1_Ca_Dll_Pll_Tracking_GPU_cc::set_gnss_synchro(Gnss_Synchro* p_gnss_synchro) { d_acquisition_gnss_synchro = p_gnss_synchro; }