/** * * \section COPYRIGHT * * Copyright 2013-2021 Software Radio Systems Limited * * By using this file, you agree to the terms and conditions set * forth in the LICENSE file which can be found at the top level of * the distribution. * */ #include "dummy_gnb_stack.h" #include "dummy_ue_stack.h" #include "srsran/common/phy_cfg_nr_default.h" #include "srsran/common/test_common.h" #include "test_bench.h" #include #include // shorten boost program options namespace namespace bpo = boost::program_options; static double assert_sr_detection_min = 1.000; static double assert_cqi_detection_min = 1.000; static double assert_pusch_bler_max = 0.000; static double assert_pdsch_bler_max = 0.000; static double assert_prach_detection_min = 1.000; static double assert_prach_ta_min = 0.000; static double assert_prach_ta_max = 0.000; static double assert_pucch_snr_min = 0.000; test_bench::args_t::args_t(int argc, char** argv) { std::string config_file; std::string reference_cfg_str; bpo::options_description options; bpo::options_description options_tb("Test bench options"); bpo::options_description options_gnb_stack("gNb stack and scheduling related options"); bpo::options_description options_gnb_phy("gNb PHY related options"); bpo::options_description options_ue_stack("UE stack options"); bpo::options_description options_ue_phy("UE stack options"); bpo::options_description options_assertion("Test assertions"); bpo::options_description options_conf_file("Configuration file"); uint16_t rnti = 17921; gnb_stack.pdsch.slots = "0,1,2,3,4,5"; gnb_stack.pusch.slots = "6,7,8,9"; // clang-format off options_tb.add_options() ("rnti", bpo::value(&rnti)->default_value(rnti), "UE RNTI") ("duration", bpo::value(&durations_slots)->default_value(durations_slots), "Test duration in slots") ("lib.log.level", bpo::value(&phy_lib_log_level)->default_value(phy_lib_log_level), "PHY library log level") ("reference", bpo::value(&reference_cfg_str)->default_value(reference_cfg_str), "Reference PHY configuration arguments") ("dl_channel.awgn_enable", bpo::value(&dl_channel.awgn_enable)->default_value(dl_channel.awgn_enable), "DL Channel AWGN enable / disable") ("dl_channel.awgn_snr", bpo::value(&dl_channel.awgn_snr_dB)->default_value(dl_channel.awgn_snr_dB), "DL Channel AWGN SNR in dB") ("ul_channel.awgn_enable", bpo::value(&ul_channel.awgn_enable)->default_value(ul_channel.awgn_enable), "UL Channel AWGN enable / disable") ("ul_channel.awgn_snr", bpo::value(&ul_channel.awgn_snr_dB)->default_value(ul_channel.awgn_snr_dB), "UL Channel AWGN SNR in dB") ("ul_channel.signal_power_dBfs", bpo::value(&ul_channel.awgn_signal_power_dBfs)->default_value(ul_channel.awgn_signal_power_dBfs), "UL Channel expected signal power") ("channel.cfo", bpo::value(&ul_channel.hst_fd_hz)->default_value(0), "Channel HST Doppler frequency") ; options_gnb_stack.add_options() ("gnb.stack.pdcch.aggregation_level", bpo::value(&gnb_stack.pdcch_aggregation_level)->default_value(gnb_stack.pdcch_aggregation_level), "PDCCH aggregation level") ("gnb.stack.pdsch.candidate", bpo::value(&gnb_stack.pdcch_dl_candidate)->default_value(gnb_stack.pdcch_dl_candidate), "PDCCH candidate index for PDSCH") ("gnb.stack.pdsch.start", bpo::value(&gnb_stack.pdsch.rb_start)->default_value(0), "PDSCH scheduling frequency allocation start") ("gnb.stack.pdsch.length", bpo::value(&gnb_stack.pdsch.rb_length)->default_value(gnb_stack.pdsch.rb_length), "PDSCH scheduling frequency allocation length") ("gnb.stack.pdsch.slots", bpo::value(&gnb_stack.pdsch.slots)->default_value(gnb_stack.pdsch.slots), "Slots enabled for PDSCH") ("gnb.stack.pdsch.mcs", bpo::value(&gnb_stack.pdsch.mcs)->default_value(gnb_stack.pdsch.mcs), "PDSCH scheduling modulation code scheme") ("gnb.stack.pusch.candidate", bpo::value(&gnb_stack.pdcch_ul_candidate)->default_value(gnb_stack.pdcch_ul_candidate), "PDCCH candidate index for PUSCH") ("gnb.stack.pusch.start", bpo::value(&gnb_stack.pusch.rb_start)->default_value(0), "PUSCH scheduling frequency allocation start") ("gnb.stack.pusch.length", bpo::value(&gnb_stack.pusch.rb_length)->default_value(gnb_stack.pusch.rb_length), "PUSCH scheduling frequency allocation length") ("gnb.stack.pusch.slots", bpo::value(&gnb_stack.pusch.slots)->default_value(gnb_stack.pusch.slots), "Slots enabled for PUSCH") ("gnb.stack.pusch.mcs", bpo::value(&gnb_stack.pusch.mcs)->default_value(gnb_stack.pusch.mcs), "PUSCH scheduling modulation code scheme") ("gnb.stack.log.level", bpo::value(&gnb_stack.log_level)->default_value(gnb_stack.log_level), "Stack log level") ("gnb.stack.use_dummy_mac", bpo::value(&gnb_stack.use_dummy_mac)->default_value("dummymac"), "Use dummy or real NR scheduler (dummymac or realmac)") ; options_gnb_phy.add_options() ("gnb.phy.nof_threads", bpo::value(&gnb_phy.nof_phy_threads)->default_value(1), "Number of threads") ("gnb.phy.log.level", bpo::value(&gnb_phy.log.phy_level)->default_value("warning"), "gNb PHY log level") ("gnb.phy.log.hex_limit", bpo::value(&gnb_phy.log.phy_hex_limit)->default_value(0), "gNb PHY log hex limit") ("gnb.phy.log.id_preamble", bpo::value(&gnb_phy.log.id_preamble)->default_value("GNB/"), "gNb PHY log ID preamble") ("gnb.phy.pusch.max_iter", bpo::value(&gnb_phy.pusch_max_its)->default_value(10), "PUSCH LDPC max number of iterations") ; options_ue_phy.add_options() ("ue.phy.nof_threads", bpo::value(&ue_phy.nof_phy_threads)->default_value(1), "Number of threads") ("ue.phy.log.level", bpo::value(&ue_phy.log.phy_level)->default_value("warning"), "UE PHY log level") ("ue.phy.log.hex_limit", bpo::value(&ue_phy.log.phy_hex_limit)->default_value(0), "UE PHY log hex limit") ("ue.phy.log.id_preamble", bpo::value(&ue_phy.log.id_preamble)->default_value(" UE/"), "UE PHY log ID preamble") ; options_ue_stack.add_options() ("ue.stack.sr.period", bpo::value(&ue_stack.sr_period)->default_value(ue_stack.sr_period), "SR period in number of opportunities. Set 0 to disable and 1 for all.") ("ue.stack.prach.period", bpo::value(&ue_stack.prach_period)->default_value(ue_stack.prach_period), "PRACH period in SFN. Set 0 to disable and 1 for all.") ; options_assertion.add_options() ("assert.sr.detection.min", bpo::value(&assert_sr_detection_min)->default_value(assert_sr_detection_min), "Scheduling request minimum detection threshold") ("assert.cqi.detection.min", bpo::value(&assert_cqi_detection_min)->default_value(assert_cqi_detection_min), "CQI report minimum detection threshold") ("assert.pusch.bler.max", bpo::value(&assert_pusch_bler_max)->default_value(assert_pusch_bler_max), "PUSCH maximum BLER threshold") ("assert.pdsch.bler.max", bpo::value(&assert_pdsch_bler_max)->default_value(assert_pdsch_bler_max), "PDSCH maximum BLER threshold") ("assert.prach.ta.min", bpo::value(&assert_prach_ta_min)->default_value(assert_prach_ta_min), "PRACH estimated TA minimum value threshold") ("assert.prach.ta.max", bpo::value(&assert_prach_ta_max)->default_value(assert_prach_ta_max), "PRACH estimated TA maximum value threshold") ("assert.pucch.snr.min", bpo::value(&assert_pucch_snr_min)->default_value(assert_pucch_snr_min), "PUCCH DMRS minimum SNR allowed threshold") ; options_conf_file.add_options() ("config_file", bpo::value(&config_file), "Configuration file") ; bpo::positional_options_description p; p.add("config_file", -1); options.add(options_tb).add(options_assertion).add(options_gnb_stack).add(options_gnb_phy).add(options_ue_stack).add(options_ue_phy).add(options_conf_file).add_options() ("help", "Show this message") ; // clang-format on bpo::variables_map vm; try { bpo::store(bpo::command_line_parser(argc, argv).options(options).positional(p).run(), vm); bpo::notify(vm); // Apply the High Speed Train args to the DL channel as well ul_channel.hst_enable = std::isnormal(ul_channel.hst_fd_hz); dl_channel.hst_enable = ul_channel.hst_enable; dl_channel.hst_fd_hz = ul_channel.hst_fd_hz; } catch (bpo::error& e) { std::cerr << e.what() << std::endl; return; } // help option was given or error - print usage and exit if (vm.count("help")) { std::cout << "Usage: " << argv[0] << " [OPTIONS] config_file" << std::endl << std::endl; std::cout << options_tb << std::endl << options_assertion << std::endl; std::cout << options_gnb_phy << std::endl << options_gnb_stack << std::endl; std::cout << options_ue_phy << std::endl << options_ue_stack << std::endl; exit(0); } // if config file given if (vm.count("config_file") != 0U) { std::cout << "Reading configuration file " << config_file << "..." << std::endl; std::ifstream conf(config_file.c_str(), std::ios::in); if (conf.fail()) { std::cout << "Failed to read configuration file " << config_file << " - exiting" << std::endl; exit(1); } // parse config file and handle errors gracefully try { bpo::store(bpo::parse_config_file(conf, options), vm); bpo::notify(vm); } catch (const boost::program_options::error& e) { std::cerr << e.what() << std::endl; exit(1); } } // Load default reference configuration phy_cfg = srsran::phy_cfg_nr_default_t(srsran::phy_cfg_nr_default_t::reference_cfg_t(reference_cfg_str)); // Calculate the DL signal power from the number of PRBs dl_channel.awgn_signal_power_dBfs = srsran_gnb_dl_get_maximum_signal_power_dBfs(phy_cfg.carrier.nof_prb); // Reverses the Doppler shift for the UL ul_channel.hst_init_time_s = 0.5 * dl_channel.hst_period_s; // Calculate sampling rate in Hz srate_hz = (double)(srsran_min_symbol_sz_rb(phy_cfg.carrier.nof_prb) * SRSRAN_SUBC_SPACING_NR(phy_cfg.carrier.scs)); cell_list.resize(1); cell_list[0].carrier = phy_cfg.carrier; cell_list[0].rf_port = 0; cell_list[0].cell_id = 0; cell_list[0].pdcch = phy_cfg.pdcch; ue_stack.rnti = rnti; gnb_stack.rnti = rnti; gnb_stack.phy_cfg = phy_cfg; gnb_stack.wait_preamble = ue_stack.prach_period > 0; if (gnb_stack.pdsch.rb_length == 0) { gnb_stack.pdsch.rb_length = phy_cfg.carrier.nof_prb; gnb_stack.pdsch.rb_start = 0; } if (gnb_stack.pusch.rb_length == 0) { gnb_stack.pusch.rb_length = phy_cfg.carrier.nof_prb; gnb_stack.pdsch.rb_start = 0; } // Flag configuration as valid valid = true; } int main(int argc, char** argv) { srslog::init(); // Parse test bench arguments test_bench::args_t args(argc, argv); // Parse arguments TESTASSERT(args.valid); // Create test bench test_bench tb(args); // Assert bench is initialised correctly TESTASSERT(tb.is_initialised()); // Run per TTI basis while (tb.run_tti()) { ; // Do nothing } // Stop test bench tb.stop(); // Flush log srslog::flush(); // Retrieve MAC metrics test_bench::metrics_t metrics = tb.get_metrics(); // Print PRACH double prach_detection = 0.0; double prach_ta = 0.0; uint32_t prach_tx_count = 0; uint32_t prach_rx_count = 0; if (metrics.ue_stack.prach.size() > 0) { srsran::console("PRACH:\n"); srsran::console( " +------------+------------+------------+------------+------------+------------+------------+\n"); srsran::console(" | %10s | %10s | %10s | %10s | %10s | %10s | %10s |\n", "Preamble", "Transmit'd", "Received", "Detection", "Avg TA", "Min TA", "Max TA"); srsran::console( " +------------+------------+------------+------------+------------+------------+------------+\n"); for (const auto& p : metrics.ue_stack.prach) { // Ensure the detected count matches with transmission // TESTASSERT(metrics.gnb_stack.prach.count(p.first)); // TESTASSERT(metrics.gnb_stack.prach[p.first].count == p.second.count); TESTASSERT(p.second.count != 0); prach_tx_count += p.second.count; gnb_dummy_stack::prach_metrics_t gnb_prach = {}; if (metrics.gnb_stack.prach.count(p.first) > 0) { gnb_prach = metrics.gnb_stack.prach[p.first]; prach_ta = SRSRAN_VEC_SAFE_CMA(gnb_prach.avg_ta, prach_ta, prach_rx_count); } else { gnb_prach.avg_ta = NAN; gnb_prach.min_ta = NAN; gnb_prach.max_ta = NAN; } prach_rx_count += gnb_prach.count; double detection = (double)gnb_prach.count / (double)p.second.count; srsran::console(" | %10d | %10d | %10d | %10.3f | %10.1f | %10.1f | %10.1f |\n", p.first, p.second.count, gnb_prach.count, detection, gnb_prach.avg_ta, gnb_prach.min_ta, gnb_prach.max_ta); } srsran::console( " +------------+------------+------------+------------+------------+------------+------------+\n"); } if (prach_tx_count > 0) { prach_detection = (double)prach_rx_count / (double)prach_tx_count; } // Print PUCCH if (metrics.gnb_stack.pucch.count > 0) { srsran::console("PUCCH DMRS Receiver metrics:\n"); srsran::console(" +------------+------------+------------+------------+\n"); srsran::console(" | %10s | %10s | %10s | %10s |\n", "Measure", "Average", "Min", "Max"); srsran::console(" +------------+------------+------------+------------+\n"); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "EPRE (dB)", metrics.gnb_stack.pucch.epre_db_avg, metrics.gnb_stack.pucch.epre_db_min, metrics.gnb_stack.pucch.epre_db_max); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "RSRP (dB)", metrics.gnb_stack.pucch.rsrp_db_avg, metrics.gnb_stack.pucch.rsrp_db_min, metrics.gnb_stack.pucch.rsrp_db_max); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "SINR (dB)", metrics.gnb_stack.pucch.snr_db_avg, metrics.gnb_stack.pucch.snr_db_min, metrics.gnb_stack.pucch.snr_db_max); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "TA (us)", metrics.gnb_stack.pucch.ta_us_avg, metrics.gnb_stack.pucch.ta_us_min, metrics.gnb_stack.pucch.ta_us_max); srsran::console(" +------------+------------+------------+------------+\n"); } // Print PDSCH metrics if scheduled double pdsch_bler = 0.0; if (metrics.gnb_stack.mac.tx_pkts > 0) { pdsch_bler = (double)metrics.gnb_stack.mac.tx_errors / (double)metrics.gnb_stack.mac.tx_pkts; float pdsch_shed_rate = 0.0f; pdsch_shed_rate = (float)metrics.gnb_stack.mac.tx_brate / (float)metrics.gnb_stack.mac.tx_pkts / 1000.0f; srsran::console("PDSCH:\n"); srsran::console(" Count: %d\n", metrics.gnb_stack.mac.tx_pkts); srsran::console(" BLER: %f\n", pdsch_bler); srsran::console(" Sched Rate: %f Mbps\n", pdsch_shed_rate); srsran::console(" Net Rate: %f Mbps\n", (1.0f - pdsch_bler) * pdsch_shed_rate); srsran::console(" Retx Rate: %f Mbps\n", pdsch_bler * pdsch_shed_rate); srsran::console("\n"); } // Print PUSCH metrics if scheduled double pusch_bler = 0.0; if (metrics.gnb_stack.mac.rx_pkts > 0) { if (metrics.gnb_stack.mac.rx_pkts != 0) { pusch_bler = (double)metrics.gnb_stack.mac.rx_errors / (double)metrics.gnb_stack.mac.rx_pkts; } float pusch_shed_rate = 0.0f; if (metrics.gnb_stack.mac.rx_pkts != 0) { pusch_shed_rate = (float)metrics.gnb_stack.mac.rx_brate / (float)metrics.gnb_stack.mac.rx_pkts / 1000.0f; } srsran::console("PUSCH:\n"); srsran::console(" Count: %d\n", metrics.gnb_stack.mac.rx_pkts); srsran::console(" BLER: %f\n", pusch_bler); srsran::console(" Sched Rate: %f Mbps\n", pusch_shed_rate); srsran::console(" Net Rate: %f Mbps\n", (1.0f - pusch_bler) * pusch_shed_rate); srsran::console(" Retx Rate: %f Mbps\n", pusch_bler * pusch_shed_rate); srsran::console("\n"); } // Print PUSCH if (metrics.gnb_stack.pusch.count > 0) { srsran::console("PUSCH DMRS Receiver metrics:\n"); srsran::console(" +------------+------------+------------+------------+\n"); srsran::console(" | %10s | %10s | %10s | %10s |\n", "Measure", "Average", "Min", "Max"); srsran::console(" +------------+------------+------------+------------+\n"); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "EPRE (dB)", metrics.gnb_stack.pusch.epre_db_avg, metrics.gnb_stack.pusch.epre_db_min, metrics.gnb_stack.pusch.epre_db_max); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "RSRP (dB)", metrics.gnb_stack.pusch.rsrp_db_avg, metrics.gnb_stack.pusch.rsrp_db_min, metrics.gnb_stack.pusch.rsrp_db_max); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "SINR (dB)", metrics.gnb_stack.pusch.snr_db_avg, metrics.gnb_stack.pusch.snr_db_min, metrics.gnb_stack.pusch.snr_db_max); srsran::console(" | %10s | %+10.2f | %+10.2f | %+10.2f |\n", "TA (us)", metrics.gnb_stack.pusch.ta_us_avg, metrics.gnb_stack.pusch.ta_us_min, metrics.gnb_stack.pusch.ta_us_max); srsran::console(" +------------+------------+------------+------------+\n"); } srsran::console("UCI stats:\n"); srsran::console(" +------------+------------+------------+------------+------------+\n"); srsran::console( " | %10s | %10s | %10s | %10s | %10s |\n", "Field", "Transmit'd", "Received", "Detection", "Avg. Val."); srsran::console(" +------------+------------+------------+------------+------------+\n"); // Print SR double sr_detection = 0.0; if (metrics.ue_stack.sr_count > 0) { sr_detection = (double)metrics.gnb_stack.sr_count / (double)metrics.ue_stack.sr_count; srsran::console(" | %10s | %10d | %10d | %10.5f | %10s |\n", "SR", metrics.ue_stack.sr_count, metrics.gnb_stack.sr_count, sr_detection, "-"); } // Print SR double cqi_detection = 0.0; if (metrics.gnb_stack.cqi_count > 0) { cqi_detection = (double)metrics.gnb_stack.cqi_valid_count / (double)metrics.gnb_stack.cqi_count; srsran::console(" | %10s | %10d | %10d | %10.5f | %10.5f |\n", "CQI", metrics.gnb_stack.cqi_count, metrics.gnb_stack.cqi_valid_count, cqi_detection, metrics.gnb_stack.mac.dl_cqi); } srsran::console(" +------------+------------+------------+------------+------------+\n"); // Assert metrics srsran_assert(metrics.gnb_stack.mac.tx_pkts == 0 or pdsch_bler <= assert_pdsch_bler_max, "PDSCH BLER (%f) exceeds the assertion maximum (%f)", pdsch_bler, assert_pusch_bler_max); srsran_assert(metrics.gnb_stack.mac.rx_pkts == 0 or pusch_bler <= assert_pusch_bler_max, "PUSCH BLER (%f) exceeds the assertion maximum (%f)", pusch_bler, assert_pusch_bler_max); srsran_assert(metrics.ue_stack.sr_count == 0 or sr_detection >= assert_sr_detection_min, "SR detection probability (%f) did not reach the assertion minimum (%f)", sr_detection, assert_sr_detection_min); srsran_assert(metrics.gnb_stack.cqi_count == 0 or cqi_detection >= assert_cqi_detection_min, "CQI report detection probability (%f) did not reach the assertion minimum (%f)", cqi_detection, assert_sr_detection_min); srsran_assert(prach_tx_count == 0 or prach_detection >= assert_prach_detection_min, "PRACH detection probability (%f) did not reach the assertion minimum (%f)", prach_detection, assert_prach_detection_min); srsran_assert(prach_tx_count == 0 or (prach_ta >= assert_prach_ta_min and prach_ta <= assert_prach_ta_max), "PRACH TA average measurement %f is higher than minimum (%d) or above maximum (%f)", prach_ta, assert_prach_ta_min, assert_prach_ta_max); srsran_assert(metrics.gnb_stack.pucch.count == 0 or (metrics.gnb_stack.pucch.snr_db_min >= assert_pucch_snr_min), "Minimum PUCCH DMRS SNR %f is below the minimum (%d)", metrics.gnb_stack.pucch.snr_db_min, assert_pucch_snr_min); // If reached here, the test is successful return SRSRAN_SUCCESS; }