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C

/**
* Copyright 2013-2021 Software Radio Systems Limited
*
* This file is part of srsRAN.
*
* srsRAN is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as
* published by the Free Software Foundation, either version 3 of
* the License, or (at your option) any later version.
*
* srsRAN 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 Affero General Public License for more details.
*
* A copy of the GNU Affero General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#ifndef SRSRAN_TEST_BENCH_H
#define SRSRAN_TEST_BENCH_H
#include "dummy_phy_common.h"
#include "srsenb/hdr/phy/nr/worker_pool.h"
#include "srsue/hdr/phy/nr/worker_pool.h"
class test_bench
{
private:
const std::string UE_PHY_COM_LOG_NAME = "UE /PHY/COM";
const std::string GNB_PHY_COM_LOG_NAME = "GNB/PHY/COM";
uint32_t slot_idx = 0;
uint64_t slot_count = 0;
uint64_t duration_slots = 0;
gnb_dummy_stack gnb_stack;
srsenb::nr::worker_pool gnb_phy;
phy_common gnb_phy_com;
ue_dummy_stack ue_stack;
srsue::nr::worker_pool ue_phy;
phy_common ue_phy_com;
bool initialised = false;
uint32_t sf_sz = 0;
public:
struct args_t {
double srate_hz = (double)(768 * SRSRAN_SUBC_SPACING_NR(0));
uint32_t nof_channels = 1;
uint32_t buffer_sz_ms = 10;
bool valid = false;
srsran::phy_cfg_nr_t phy_cfg = {};
srsenb::phy_cell_cfg_list_nr_t cell_list = {};
srsenb::nr::worker_pool::args_t gnb_phy;
gnb_dummy_stack::args_t gnb_stack;
srsue::phy_args_nr_t ue_phy;
ue_dummy_stack::args_t ue_stack;
std::string phy_com_log_level = "info";
std::string phy_lib_log_level = "none";
uint64_t durations_slots = 100;
args_t(int argc, char** argv);
};
struct metrics_t {
gnb_dummy_stack::metrics_t gnb_stack = {};
ue_dummy_stack::metrics_t ue_stack = {};
};
test_bench(const args_t& args) :
gnb_stack(args.gnb_stack),
gnb_phy(gnb_phy_com, gnb_stack, srslog::get_default_sink(), args.gnb_phy.nof_phy_threads),
ue_stack(args.ue_stack, ue_phy),
ue_phy(args.ue_phy.nof_phy_threads),
ue_phy_com(phy_common::args_t(args.srate_hz, args.buffer_sz_ms, args.nof_channels),
srslog::fetch_basic_logger(UE_PHY_COM_LOG_NAME, srslog::get_default_sink(), false)),
gnb_phy_com(phy_common::args_t(args.srate_hz, args.buffer_sz_ms, args.nof_channels),
srslog::fetch_basic_logger(GNB_PHY_COM_LOG_NAME, srslog::get_default_sink(), false)),
sf_sz((uint32_t)std::round(args.srate_hz * 1e-3)),
duration_slots(args.durations_slots)
{
srslog::fetch_basic_logger(UE_PHY_COM_LOG_NAME).set_level(srslog::str_to_basic_level(args.phy_com_log_level));
srslog::fetch_basic_logger(GNB_PHY_COM_LOG_NAME).set_level(srslog::str_to_basic_level(args.phy_com_log_level));
if (not gnb_phy.init(args.gnb_phy, args.cell_list)) {
return;
}
srsenb::phy_interface_rrc_nr::common_cfg_t common_cfg = {};
common_cfg.carrier = args.phy_cfg.carrier;
common_cfg.pdcch = args.phy_cfg.pdcch;
common_cfg.prach = args.phy_cfg.prach;
common_cfg.duplex_mode = args.phy_cfg.duplex.mode;
common_cfg.ssb = args.phy_cfg.get_ssb_cfg();
if (gnb_phy.set_common_cfg(common_cfg) < SRSRAN_SUCCESS) {
return;
}
// Initialise UE PHY
if (not ue_phy.init(args.ue_phy, ue_phy_com, &ue_stack, 31)) {
return;
}
// Set UE configuration
if (not ue_phy.set_config(args.phy_cfg)) {
return;
}
// Make sure PHY log is not set by UE or gNb PHY
handler_registered = 0;
if (args.phy_lib_log_level == "info") {
srsran_verbose = SRSRAN_VERBOSE_INFO;
} else if (args.phy_lib_log_level == "debug") {
srsran_verbose = SRSRAN_VERBOSE_DEBUG;
} else {
srsran_verbose = SRSRAN_VERBOSE_NONE;
}
initialised = true;
}
void stop()
{
ue_phy_com.stop();
gnb_phy_com.stop();
gnb_phy.stop();
ue_phy.stop();
}
~test_bench() = default;
bool is_initialised() const { return ue_stack.is_valid() and gnb_stack.is_valid() and initialised; }
bool run_tti()
{
// Get gNb worker
srsenb::nr::slot_worker* gnb_worker = gnb_phy.wait_worker(slot_idx);
if (gnb_worker == nullptr) {
return false;
}
// Feed gNb the UE transmitted signal
srsran::rf_timestamp_t gnb_time = {};
std::vector<cf_t*> gnb_rx_buffers(1);
gnb_rx_buffers[0] = gnb_worker->get_buffer_rx(0);
ue_phy_com.read(gnb_rx_buffers, sf_sz, gnb_time);
// Set gNb time
gnb_time.add(TX_ENB_DELAY * 1e-3);
// Set gnb context
srsran::phy_common_interface::worker_context_t gnb_context;
gnb_context.sf_idx = slot_idx;
gnb_context.worker_ptr = gnb_worker;
gnb_context.last = true; // Set last if standalone
gnb_context.tx_time.copy(gnb_time);
gnb_worker->set_context(gnb_context);
// Start gNb work
gnb_phy_com.push_semaphore(gnb_worker);
gnb_phy.start_worker(gnb_worker);
// Get UE worker
srsue::nr::sf_worker* ue_worker = ue_phy.wait_worker(slot_idx);
if (ue_worker == nullptr) {
return false;
}
// Feed UE the gNb transmitted signal
srsran::rf_timestamp_t ue_time = {};
std::vector<cf_t*> ue_rx_buffers(1);
ue_rx_buffers[0] = ue_worker->get_buffer(0, 0);
gnb_phy_com.read(ue_rx_buffers, sf_sz, ue_time);
// Set UE time
ue_time.add(TX_ENB_DELAY * 1e-3);
// Set gnb context
srsran::phy_common_interface::worker_context_t ue_context;
ue_context.sf_idx = slot_idx;
ue_context.worker_ptr = ue_worker;
ue_context.last = true; // Set last if standalone
ue_context.tx_time.copy(gnb_time);
ue_worker->set_context(ue_context);
// Run UE stack
ue_stack.run_tti(slot_idx);
// Start UE work
ue_phy_com.push_semaphore(ue_worker);
ue_phy.start_worker(ue_worker);
slot_count++;
slot_idx = slot_count % (1024 * SRSRAN_NSLOTS_PER_FRAME_NR(srsran_subcarrier_spacing_15kHz));
return slot_count <= duration_slots;
}
metrics_t get_gnb_metrics()
{
metrics_t metrics = {};
metrics.gnb_stack = gnb_stack.get_metrics();
metrics.ue_stack = ue_stack.get_metrics();
return metrics;
}
};
#endif // SRSRAN_TEST_BENCH_H