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C++

/**
*
* \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 "channel_mapping.h"
#include "radio_metrics.h"
#include "rf_buffer.h"
#include "rf_timestamp.h"
#include "srsran/common/interfaces_common.h"
#include "srsran/interfaces/radio_interfaces.h"
#include "srsran/phy/resampling/resampler.h"
#include "srsran/phy/rf/rf.h"
#include "srsran/radio/radio_base.h"
#include "srsran/srslog/srslog.h"
#include "srsran/srsran.h"
#include <condition_variable>
#include <list>
#include <string>
#ifndef SRSRAN_RADIO_DUMMY_H
#define SRSRAN_RADIO_DUMMY_H
namespace srsran {
/**
* Implementation of the radio interface for the PHY
*
* It uses the rf C library object to access the underlying radio. This implementation uses a flat array to
* transmit/receive samples for all RF channels. The N carriers and P antennas are mapped into M=NP RF channels (M <=
* SRSRAN_MAX_CHANNELS). Note that all carriers must have the same number of antennas.
*
* The underlying radio receives and transmits M RF channels synchronously from possibly multiple radios using the same
* rf driver object. In the current implementation, the mapping between N carriers and P antennas is sequentially, eg:
* [carrier_0_port_0, carrier_0_port_1, carrier_1_port_0, carrier_1_port_1, ..., carrier_N_port_N]
*/
class radio_dummy : public srsran::radio_base, public srsran::radio_interface_phy
{
private:
static const uint32_t TEMP_BUFFER_SZ = SRSRAN_SF_LEN_MAX * SRSRAN_NOF_SF_X_FRAME;
srslog::basic_logger& logger;
std::vector<srsran_ringbuffer_t> rx_ring_buffers;
std::vector<srsran_ringbuffer_t> tx_ring_buffers;
std::mutex tx_mutex;
double srate_hz = 0.0f;
std::atomic<float> rx_gain = {1.0f};
std::atomic<float> tx_gain = {1.0f};
cf_t* temp_buffer = nullptr;
uint64_t rx_timestamp = 0;
uint64_t tx_timestamp = 0;
srsran_rf_info_t rf_info = {};
std::atomic<bool> is_initialised = {false};
std::atomic<bool> quit = {false};
void write_ring_buffers(std::vector<srsran_ringbuffer_t>& buffers, cf_t** buffer, uint32_t nsamples)
{
for (uint32_t i = 0; i < buffers.size(); i++) {
int ret = SRSRAN_SUCCESS;
do {
if (ret != SRSRAN_SUCCESS) {
logger.error("Ring buffer write failed (full). Trying again.");
}
ret = srsran_ringbuffer_write_timed(&buffers[i], buffer[i], (int)(sizeof(cf_t) * nsamples), 1000);
} while (ret == SRSRAN_ERROR_TIMEOUT and not quit);
}
}
void read_ring_buffers(std::vector<srsran_ringbuffer_t>& buffers, cf_t** buffer, uint32_t nsamples)
{
for (uint32_t i = 0; i < buffers.size(); i++) {
int ret = SRSRAN_SUCCESS;
do {
if (ret != SRSRAN_SUCCESS) {
logger.error("Ring buffer read failed. Trying again.");
}
ret = srsran_ringbuffer_read_timed(&buffers[i], buffer[i], (int)(sizeof(cf_t) * nsamples), 1000);
} while (ret == SRSRAN_ERROR_TIMEOUT and not quit);
}
}
void write_zeros_ring_buffers(std::vector<srsran_ringbuffer_t>& buffers, uint32_t nsamples)
{
uint32_t n = SRSRAN_MIN(nsamples, TEMP_BUFFER_SZ);
srsran_vec_cf_zero(temp_buffer, n);
std::array<cf_t*, SRSRAN_MAX_CHANNELS> zero_buffer_pointers = {};
for (cf_t*& ptr : zero_buffer_pointers) {
ptr = temp_buffer;
}
while (nsamples > 0) {
// Get new number of samples
n = SRSRAN_MIN(nsamples, TEMP_BUFFER_SZ);
// Write zeros in the buffers
write_ring_buffers(buffers, zero_buffer_pointers.data(), n);
nsamples -= n;
}
}
void advance_tx_timestamp(uint64_t ts)
{
std::lock_guard<std::mutex> lock(tx_mutex);
// Make sure new timestamp has not passed
if (ts < tx_timestamp) {
return;
}
// Calculate transmission gap in samples
uint32_t tx_gap = (uint32_t)(ts - tx_timestamp);
// Skip zeros if there is no gap
if (tx_gap == 0) {
return;
}
// Write zeros in tx ring buffer
write_zeros_ring_buffers(tx_ring_buffers, tx_gap);
// Update new transmit timestamp
tx_timestamp = ts;
}
public:
radio_dummy() : logger(srslog::fetch_basic_logger("RF", false)) {}
~radio_dummy()
{
for (auto& rb : rx_ring_buffers) {
srsran_ringbuffer_free(&rb);
}
if (temp_buffer) {
free(temp_buffer);
}
}
std::string get_type() override { return "dummy"; }
int init(const rf_args_t& args_, phy_interface_radio* phy_) override
{
// Set logger level
logger.set_level(srslog::str_to_basic_level(args_.log_level));
// Get base sampling rate and assert the value is valid
srate_hz = args_.srate_hz;
if (not std::isnormal(srate_hz)) {
logger.error("A valid sampling rate is missing");
return SRSRAN_ERROR;
}
// Create receiver ring buffers
rx_ring_buffers.resize(args_.nof_carriers * args_.nof_antennas);
for (auto& rb : rx_ring_buffers) {
if (srsran_ringbuffer_init(&rb, (int)sizeof(cf_t) * TEMP_BUFFER_SZ) != SRSRAN_SUCCESS) {
perror("init softbuffer");
}
}
// Create transmitter ring buffers
tx_ring_buffers.resize(args_.nof_carriers * args_.nof_antennas);
for (auto& rb : tx_ring_buffers) {
if (srsran_ringbuffer_init(&rb, (int)sizeof(cf_t) * TEMP_BUFFER_SZ) != SRSRAN_SUCCESS) {
perror("init softbuffer");
}
}
// Create temporal buffer
temp_buffer = srsran_vec_cf_malloc(TEMP_BUFFER_SZ);
if (!temp_buffer) {
perror("malloc");
}
// Set RF Info (in dB)
rf_info.min_rx_gain = 0.0f;
rf_info.max_rx_gain = 90.0f;
rf_info.min_tx_gain = 0.0f;
rf_info.max_tx_gain = 90.0f;
// Finally, the radio is initialised
is_initialised = true;
return SRSRAN_SUCCESS;
}
void stop() override { quit = true; }
bool get_metrics(rf_metrics_t* metrics) override { return false; }
void set_loglevel(std::string& str) { logger.set_level(srslog::str_to_basic_level(str)); }
void write_rx(cf_t** buffer, uint32_t nsamples) { write_ring_buffers(rx_ring_buffers, buffer, nsamples); }
void read_tx(cf_t** buffer, uint32_t nsamples) { read_ring_buffers(tx_ring_buffers, buffer, nsamples); }
bool tx(srsran::rf_buffer_interface& buffer, const srsran::rf_timestamp_interface& tx_time) override
{
bool ret = true;
// Convert timestamp to samples
uint64_t tx_time_n = srsran_timestamp_uint64(&tx_time.get(0), srate_hz);
// Check if the transmission is in the past
if (tx_time_n < tx_timestamp) {
logger.error("Error transmission in the past");
return false;
}
// Advance TX to timestamp
advance_tx_timestamp(tx_time_n);
// From now on, protect buffers
std::lock_guard<std::mutex> lock(tx_mutex);
// Write transmission buffers into the ring buffer
write_ring_buffers(tx_ring_buffers, buffer.to_cf_t(), buffer.get_nof_samples());
// Increment transmit timestamp
tx_timestamp += buffer.get_nof_samples();
return ret;
}
void release_freq(const uint32_t& carrier_idx) override{};
void tx_end() override {}
bool rx_now(srsran::rf_buffer_interface& buffer, srsran::rf_timestamp_interface& rxd_time) override
{
// Advance Tx buffer
advance_tx_timestamp(rx_timestamp + buffer.get_nof_samples());
// Read samples
read_ring_buffers(rx_ring_buffers, buffer.to_cf_t(), buffer.get_nof_samples());
// Apply Rx gain
for (uint32_t i = 0; i < rx_ring_buffers.size(); i++) {
cf_t* ptr = buffer.get(i);
srsran_vec_sc_prod_cfc(ptr, rx_gain, ptr, buffer.get_nof_samples());
}
// Set Rx timestamp
srsran_timestamp_init_uint64(rxd_time.get_ptr(0), rx_timestamp, (double)srate_hz);
// Advance timestamp
rx_timestamp += buffer.get_nof_samples();
return true;
}
void set_tx_freq(const uint32_t& channel_idx, const double& freq) override
{
logger.info("Set Tx freq to %+.0f MHz.", freq * 1.0e-6);
}
void set_rx_freq(const uint32_t& channel_idx, const double& freq) override
{
logger.info("Set Rx freq to %+.0f MHz.", freq * 1.0e-6);
}
void set_rx_gain_th(const float& gain) override
{
rx_gain = srsran_convert_dB_to_amplitude(gain);
logger.info("Set Rx gain-th to %+.1f dB (%.6f).", gain, rx_gain.load());
}
void set_tx_gain(const float& gain) override
{
tx_gain = srsran_convert_dB_to_amplitude(gain);
logger.info("Set Tx gain to %+.1f dB (%.6f).", gain, tx_gain.load());
}
void set_rx_gain(const float& gain) override
{
rx_gain = srsran_convert_dB_to_amplitude(gain);
logger.info("Set Rx gain to %+.1f dB (%.6f).", gain, rx_gain.load());
}
void set_tx_srate(const double& srate) override { logger.info("Set Tx sampling rate to %+.3f MHz.", srate * 1.0e-6); }
void set_rx_srate(const double& srate) override { logger.info("Set Rx sampling rate to %+.3f MHz.", srate * 1.0e-6); }
void set_channel_rx_offset(uint32_t ch, int32_t offset_samples) override{};
float get_rx_gain() override { return srsran_convert_amplitude_to_dB(rx_gain); }
double get_freq_offset() override { return 0; }
bool is_continuous_tx() override { return false; }
bool get_is_start_of_burst() override { return false; }
bool is_init() override { return is_initialised; }
void reset() override {}
srsran_rf_info_t* get_info() override { return &rf_info; }
};
} // namespace srsran
#endif // SRSRAN_RADIO_DUMMY_H