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459 lines
16 KiB
C++
459 lines
16 KiB
C++
/**
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*
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* \section COPYRIGHT
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*
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* Copyright 2013-2021 Software Radio Systems Limited
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*
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* By using this file, you agree to the terms and conditions set
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* forth in the LICENSE file which can be found at the top level of
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* the distribution.
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*
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*/
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#include "srsran/common/band_helper.h"
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#include "srsran/common/string_helpers.h"
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#include "srsran/common/test_common.h"
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#include "srsran/interfaces/phy_interface_types.h"
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#include "srsran/radio/radio.h"
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#include "srsran/srslog/srslog.h"
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#include "srsue/hdr/phy/scell/intra_measure_nr.h"
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#include <boost/program_options.hpp>
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#include <boost/program_options/parsers.hpp>
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#include <iostream>
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#include <map>
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#include <memory>
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#include <vector>
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// Test gNb class
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class test_gnb
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{
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private:
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uint32_t pci;
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srsran_ssb_t ssb = {};
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std::vector<cf_t> signal_buffer = {};
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srslog::basic_logger& logger;
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public:
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struct args_t {
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uint32_t pci = 500;
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double srate_hz = 11.52e6;
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double center_freq_hz = 3.5e9;
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double ssb_freq_hz = 3.5e9 - 960e3;
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srsran_subcarrier_spacing_t ssb_scs = srsran_subcarrier_spacing_30kHz;
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uint32_t ssb_period_ms = 20;
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uint16_t band;
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srsran_ssb_patern_t get_ssb_pattern() const { return srsran::srsran_band_helper().get_ssb_pattern(band, ssb_scs); }
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srsran_duplex_mode_t get_duplex_mode() const { return srsran::srsran_band_helper().get_duplex_mode(band); }
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};
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test_gnb(const args_t& args) : logger(srslog::fetch_basic_logger("PCI=" + std::to_string(args.pci)))
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{
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// Initialise internals
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pci = args.pci;
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// Initialise SSB
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srsran_ssb_args_t ssb_args = {};
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ssb_args.max_srate_hz = args.srate_hz;
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ssb_args.min_scs = args.ssb_scs;
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ssb_args.enable_encode = true;
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if (srsran_ssb_init(&ssb, &ssb_args) < SRSRAN_SUCCESS) {
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logger.error("Error initialising SSB");
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return;
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}
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// Configure SSB
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srsran_ssb_cfg_t ssb_cfg = {};
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ssb_cfg.srate_hz = args.srate_hz;
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ssb_cfg.center_freq_hz = args.center_freq_hz;
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ssb_cfg.ssb_freq_hz = args.ssb_freq_hz;
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ssb_cfg.scs = args.ssb_scs;
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ssb_cfg.pattern = args.get_ssb_pattern();
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ssb_cfg.position[0] = true;
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ssb_cfg.duplex_mode = args.get_duplex_mode();
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ssb_cfg.periodicity_ms = args.ssb_period_ms;
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if (srsran_ssb_set_cfg(&ssb, &ssb_cfg) < SRSRAN_SUCCESS) {
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logger.error("Error configuring SSB");
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return;
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}
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}
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int work(uint32_t sf_idx, std::vector<cf_t>& baseband_buffer)
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{
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logger.set_context(sf_idx);
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// Check if SSB needs to be sent
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if (srsran_ssb_send(&ssb, sf_idx)) {
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// Prepare PBCH message
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srsran_pbch_msg_nr_t msg = {};
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// Add SSB
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if (srsran_ssb_add(&ssb, pci, &msg, baseband_buffer.data(), baseband_buffer.data()) < SRSRAN_SUCCESS) {
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logger.error("Error adding SSB");
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return SRSRAN_ERROR;
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}
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}
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return SRSRAN_SUCCESS;
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}
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~test_gnb() { srsran_ssb_free(&ssb); }
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};
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struct args_t {
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// Common execution parameters
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uint32_t duration_s = 1;
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uint32_t nof_prb = 52;
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std::string log_level = "info";
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std::string active_cell_list = "500";
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std::string simulation_cell_list = "500";
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uint32_t meas_len_ms = 1;
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uint32_t meas_period_ms = 20;
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uint32_t carier_arfcn = 634240;
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uint32_t ssb_arfcn = 634176;
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srsran_subcarrier_spacing_t carrier_scs = srsran_subcarrier_spacing_15kHz;
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srsran_subcarrier_spacing_t ssb_scs = srsran_subcarrier_spacing_30kHz;
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float thr_snr_db = 5.0f;
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// On the Fly parameters
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std::string radio_device_name = "auto";
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std::string radio_device_args = "auto";
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std::string radio_log_level = "info";
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float rx_gain = 60.0f;
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// Parsed PCI lists
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std::set<uint32_t> pcis_to_meas;
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std::set<uint32_t> pcis_to_simulate;
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};
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class meas_itf_listener : public srsue::scell::intra_measure_base::meas_itf
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{
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public:
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typedef struct {
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float rsrp_avg;
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float rsrp_min;
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float rsrp_max;
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float rsrq_avg;
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float rsrq_min;
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float rsrq_max;
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uint32_t count;
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} cell_meas_t;
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std::map<uint32_t, cell_meas_t> cells;
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void cell_meas_reset(uint32_t cc_idx) override {}
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void new_cell_meas(uint32_t cc_idx, const std::vector<srsue::phy_meas_t>& meas) override
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{
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for (auto& m : meas) {
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uint32_t pci = m.pci;
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if (!cells.count(pci)) {
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cells[pci].rsrp_min = m.rsrp;
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cells[pci].rsrp_max = m.rsrp;
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cells[pci].rsrp_avg = m.rsrp;
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cells[pci].rsrq_min = m.rsrq;
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cells[pci].rsrq_max = m.rsrq;
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cells[pci].rsrq_avg = m.rsrq;
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cells[pci].count = 1;
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} else {
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cells[pci].rsrp_min = SRSRAN_MIN(cells[pci].rsrp_min, m.rsrp);
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cells[pci].rsrp_max = SRSRAN_MAX(cells[pci].rsrp_max, m.rsrp);
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cells[pci].rsrp_avg = (m.rsrp + cells[pci].rsrp_avg * cells[pci].count) / (cells[pci].count + 1);
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cells[pci].rsrq_min = SRSRAN_MIN(cells[pci].rsrq_min, m.rsrq);
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cells[pci].rsrq_max = SRSRAN_MAX(cells[pci].rsrq_max, m.rsrq);
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cells[pci].rsrq_avg = (m.rsrq + cells[pci].rsrq_avg * cells[pci].count) / (cells[pci].count + 1);
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cells[pci].count++;
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}
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}
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}
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bool print_stats(args_t args)
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{
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printf("\n-- Statistics:\n");
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uint32_t true_counts = 0;
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uint32_t false_counts = 0;
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uint32_t tti_count = (1000 * args.duration_s) / args.meas_period_ms;
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uint32_t ideal_true_counts = args.pcis_to_simulate.size() * tti_count;
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uint32_t ideal_false_counts = tti_count * cells.size() - ideal_true_counts;
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for (auto& e : cells) {
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bool false_alarm = args.pcis_to_simulate.find(e.first) == args.pcis_to_simulate.end();
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if (false_alarm) {
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false_counts += e.second.count;
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} else {
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true_counts += e.second.count;
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}
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printf(" pci=%03d; count=%3d; false=%s; rsrp=%+.1f|%+.1f|%+.1fdBfs; rsrq=%+.1f|%+.1f|%+.1fdB;\n",
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e.first,
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e.second.count,
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false_alarm ? "y" : "n",
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e.second.rsrp_min,
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e.second.rsrp_avg,
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e.second.rsrp_max,
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e.second.rsrq_min,
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e.second.rsrq_avg,
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e.second.rsrq_max);
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}
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float prob_detection = (ideal_true_counts) ? (float)true_counts / (float)ideal_true_counts : 0.0f;
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float prob_false_alarm = (ideal_false_counts) ? (float)false_counts / (float)ideal_false_counts : 0.0f;
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printf("\n");
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printf(" Probability of detection: %.6f\n", prob_detection);
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printf(" Probability of false alarm: %.6f\n", prob_false_alarm);
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return (prob_detection >= 0.9f && prob_false_alarm <= 0.1f);
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}
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};
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// shorten boost program options namespace
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namespace bpo = boost::program_options;
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int parse_args(int argc, char** argv, args_t& args)
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{
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int ret = SRSRAN_SUCCESS;
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bpo::options_description options;
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bpo::options_description common("Measurement options");
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bpo::options_description over_the_air("Over the air options");
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bpo::options_description simulation("Simulation execution options");
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// clang-format off
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common.add_options()
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("duration", bpo::value<uint32_t>(&args.duration_s), "Duration of the test in seconds")
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("nof_prb", bpo::value<uint32_t>(&args.nof_prb), "Cell Number of PRB")
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("log_level", bpo::value<std::string>(&args.log_level), "Intra measurement log level (none, warning, info, debug)")
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("meas_len_ms", bpo::value<uint32_t>(&args.meas_len_ms), "Measurement length")
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("meas_period_ms", bpo::value<uint32_t>(&args.meas_period_ms), "Measurement period")
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("active_cell_list", bpo::value<std::string>(&args.active_cell_list), "Comma separated PCI cell list to measure")
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("carrier_arfcn", bpo::value<std::uint32_t>(&args.carier_arfcn), "Carrier center frequency ARFCN")
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("ssb_arfcn", bpo::value<std::uint32_t>(&args.ssb_arfcn), "SSB center frequency in ARFCN")
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("thr_snr_db", bpo::value<float>(&args.thr_snr_db), "Detection threshold for SNR in dB")
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;
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over_the_air.add_options()
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("rf.device_name", bpo::value<std::string>(&args.radio_device_name), "RF Device Name")
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("rf.device_args", bpo::value<std::string>(&args.radio_device_args), "RF Device arguments")
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("rf.log_level", bpo::value<std::string>(&args.radio_log_level), "RF Log level (none, warning, info, debug)")
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("rf.rx_gain", bpo::value<float>(&args.rx_gain), "RF Receiver gain in dB")
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;
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simulation.add_options()
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("simulation_cell_list", bpo::value<std::string>(&args.simulation_cell_list), "Comma separated PCI cell list to simulate")
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;
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options.add(common).add(over_the_air).add(simulation).add_options()
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("help", "Show this message")
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;
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// clang-format on
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bpo::variables_map vm;
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try {
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bpo::store(bpo::command_line_parser(argc, argv).options(options).run(), vm);
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bpo::notify(vm);
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} catch (bpo::error& e) {
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std::cerr << e.what() << std::endl;
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ret = SRSRAN_ERROR;
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}
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// help option was given or error - print usage and exit
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if (vm.count("help") || ret) {
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std::cout << "Usage: " << argv[0] << " [OPTIONS] config_file" << std::endl << std::endl;
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std::cout << options << std::endl << std::endl;
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ret = SRSRAN_ERROR;
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}
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return ret;
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}
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static void pci_list_parse_helper(std::string& list_str, std::set<uint32_t>& list)
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{
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if (list_str == "all") {
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// Add all possible cells
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for (int i = 0; i < SRSRAN_NOF_NID_NR; i++) {
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list.insert(i);
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}
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} else if (list_str == "none") {
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list.clear();
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} else if (not list_str.empty()) {
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// Remove spaces from neightbour cell list
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list_str = srsran::string_remove_char(list_str, ' ');
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// Add cell to known cells
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srsran::string_parse_list(list_str, ',', list);
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}
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}
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int main(int argc, char** argv)
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{
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int ret;
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// Parse args
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args_t args = {};
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if (parse_args(argc, argv, args) < SRSRAN_SUCCESS) {
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return SRSRAN_ERROR;
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}
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// Initiate logging
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srslog::init();
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srslog::basic_logger& logger = srslog::fetch_basic_logger("PHY");
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logger.set_level(srslog::str_to_basic_level(args.log_level));
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// Deduce base-band parameters
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uint32_t sf_len = srsran_min_symbol_sz_rb(args.nof_prb) * SRSRAN_SUBC_SPACING_NR(args.carrier_scs) / 1000U;
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double srate_hz = (double)sf_len * 1000.0;
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double center_freq_hz = srsran::srsran_band_helper().nr_arfcn_to_freq(args.carier_arfcn);
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double ssb_freq_hz = srsran::srsran_band_helper().nr_arfcn_to_freq(args.ssb_arfcn);
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uint16_t band = srsran::srsran_band_helper().get_band_from_dl_freq_Hz(center_freq_hz);
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logger.debug("Band: %d; srate: %.2f MHz; center_freq: %.1f MHz; ssb_freq: %.1f MHz;",
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band,
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srate_hz / 1e6,
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center_freq_hz / 1e6,
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ssb_freq_hz / 1e6);
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// Allocate buffer
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std::vector<cf_t> baseband_buffer(sf_len);
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// Create measurement callback
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meas_itf_listener rrc;
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// Create measurement instance
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srsue::scell::intra_measure_nr intra_measure(logger, rrc);
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// Initialise measurement instance
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srsue::scell::intra_measure_nr::args_t meas_args = {};
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meas_args.rx_gain_offset_dB = 0.0f;
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meas_args.max_len_ms = args.meas_len_ms;
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meas_args.max_srate_hz = srate_hz;
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meas_args.min_scs = args.ssb_scs;
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meas_args.thr_snr_db = args.thr_snr_db;
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TESTASSERT(intra_measure.init(0, meas_args));
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// Setup measurement
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srsue::scell::intra_measure_nr::config_t meas_cfg = {};
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meas_cfg.arfcn = args.carier_arfcn;
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meas_cfg.srate_hz = srate_hz;
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meas_cfg.len_ms = args.meas_len_ms;
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meas_cfg.periodicity_ms = args.meas_period_ms;
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meas_cfg.rx_gain_offset_db = 0;
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meas_cfg.center_freq_hz = center_freq_hz;
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meas_cfg.ssb_freq_hz = ssb_freq_hz;
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meas_cfg.scs = srsran_subcarrier_spacing_30kHz;
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meas_cfg.serving_cell_pci = -1;
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TESTASSERT(intra_measure.set_config(args.carier_arfcn, meas_cfg));
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// Simulation only
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std::vector<std::unique_ptr<test_gnb> > test_gnb_v;
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// Over-the-air only
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std::unique_ptr<srsran::radio> radio = nullptr;
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// Parse PCI lists
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pci_list_parse_helper(args.active_cell_list, args.pcis_to_meas);
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pci_list_parse_helper(args.simulation_cell_list, args.pcis_to_simulate);
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// Setup raio if the list of PCIs to simulate is empty
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if (args.pcis_to_simulate.empty()) {
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// Create radio log
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auto& radio_logger = srslog::fetch_basic_logger("RF", false);
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radio_logger.set_level(srslog::str_to_basic_level(args.radio_log_level));
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// Create radio
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radio = std::unique_ptr<srsran::radio>(new srsran::radio);
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// Init radio
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srsran::rf_args_t radio_args = {};
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radio_args.device_args = args.radio_device_args;
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radio_args.device_name = args.radio_device_name;
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radio_args.nof_carriers = 1;
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radio_args.nof_antennas = 1;
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radio->init(radio_args, nullptr);
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// Set sampling rate
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radio->set_rx_srate(srate_hz);
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// Set frequency
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radio->set_rx_freq(0, center_freq_hz);
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} else {
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// Create test eNb's if radio is not available
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for (const uint32_t& pci : args.pcis_to_simulate) {
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// Initialise channel and push back
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test_gnb::args_t gnb_args = {};
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gnb_args.pci = pci;
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gnb_args.srate_hz = srate_hz;
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gnb_args.center_freq_hz = center_freq_hz;
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gnb_args.ssb_freq_hz = ssb_freq_hz;
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gnb_args.ssb_scs = args.ssb_scs;
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gnb_args.ssb_period_ms = args.meas_period_ms;
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gnb_args.band = band;
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test_gnb_v.push_back(std::unique_ptr<test_gnb>(new test_gnb(gnb_args)));
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// Add cell to known cells
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if (args.active_cell_list.empty()) {
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args.pcis_to_meas.insert(pci);
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}
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}
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}
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// pass cells to measure to intra_measure object
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intra_measure.set_cells_to_meas(args.pcis_to_meas);
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// Run loop
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for (uint32_t sf_idx = 0; sf_idx < args.duration_s * 1000; sf_idx++) {
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logger.set_context(sf_idx);
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srsran::rf_timestamp_t ts = {};
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// Clean buffer
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srsran_vec_cf_zero(baseband_buffer.data(), sf_len);
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if (radio) {
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// Receive radio
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srsran::rf_buffer_t radio_buffer(baseband_buffer.data(), sf_len);
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radio->rx_now(radio_buffer, ts);
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} else {
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// Run gNb simulator
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for (auto& gnb : test_gnb_v) {
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gnb->work(sf_idx, baseband_buffer);
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}
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// if it measuring, wait for avoiding overflowing
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intra_measure.wait_meas();
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// Increase Time counter
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ts.add(0.001);
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}
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// Give data to intra measure component
|
|
intra_measure.write(sf_idx % 10240, baseband_buffer.data(), sf_len);
|
|
if (sf_idx % 1000 == 0) {
|
|
logger.info("Done %.1f%%", (double)sf_idx * 100.0 / ((double)args.duration_s * 1000.0));
|
|
}
|
|
}
|
|
|
|
// make sure last measurement has been received before stopping
|
|
if (not radio) {
|
|
intra_measure.wait_meas();
|
|
}
|
|
|
|
// Stop, it will block until the asynchronous thread quits
|
|
intra_measure.stop();
|
|
|
|
ret = rrc.print_stats(args) ? SRSRAN_SUCCESS : SRSRAN_ERROR;
|
|
|
|
if (radio) {
|
|
radio->stop();
|
|
}
|
|
|
|
srslog::flush();
|
|
|
|
if (ret && radio == nullptr) {
|
|
printf("Error\n");
|
|
} else {
|
|
printf("Ok\n");
|
|
}
|
|
|
|
return ret;
|
|
}
|