Ported the all radio classes to use srslog.

master
faluco 4 years ago committed by faluco
parent ddd1f28820
commit 62fcf04083

@ -43,8 +43,7 @@ namespace srslte {
class radio : public radio_interface_phy, public srslte::radio_base
{
public:
radio(srslte::log_filter* log_h);
radio(srslte::logger* logger_h);
radio();
~radio();
int init(const rf_args_t& args_, phy_interface_radio* phy_) final;
@ -90,9 +89,7 @@ private:
std::vector<srslte_rf_info_t> rf_info = {};
std::vector<int32_t> rx_offset_n = {};
rf_metrics_t rf_metrics = {};
log_filter log_local = {};
log_filter* log_h = nullptr;
srslte::logger* logger = nullptr;
srslog::basic_logger& logger = srslog::fetch_basic_logger("RF", false);
phy_interface_radio* phy = nullptr;
cf_t* zeros = nullptr;
std::array<cf_t*, SRSLTE_MAX_CHANNELS> dummy_buffers;

@ -29,7 +29,6 @@ class phy_interface_radio;
class radio_base
{
public:
radio_base(srslte::logger* logger_ = nullptr) {}
virtual ~radio_base() = default;
virtual std::string get_type() = 0;

@ -31,14 +31,13 @@ namespace srslte {
class radio_null final : public radio_base, public radio_interface_phy
{
public:
explicit radio_null(srslte::logger* logger_);
~radio_null() final = default;
std::string get_type() override { return "null"; }
int init(const rf_args_t& args_, phy_interface_radio* phy_) override
{
log->set_level(args.log_level);
logger.set_level(srslog::str_to_basic_level(args.log_level));
running = true;
return SRSLTE_SUCCESS;
@ -58,60 +57,60 @@ public:
bool is_continuous_tx() override { return false; }
bool tx(rf_buffer_interface& buffer, const rf_timestamp_interface& tx_time) override
{
log->info("%s\n", __PRETTY_FUNCTION__);
logger.info("%s", __PRETTY_FUNCTION__);
return true;
}
void tx_end() override { log->info("%s\n", __PRETTY_FUNCTION__); }
void tx_end() override { logger.info("%s", __PRETTY_FUNCTION__); }
bool rx_now(rf_buffer_interface& buffer, rf_timestamp_interface& rxd_time) override
{
log->info("%s\n", __PRETTY_FUNCTION__);
logger.info("%s", __PRETTY_FUNCTION__);
return true;
}
void set_rx_gain(const float& gain) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_rx_gain(const float& gain) override { logger.info("%s", __PRETTY_FUNCTION__); }
void set_rx_gain_th(const float& gain) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_rx_gain_th(const float& gain) override { logger.info("%s", __PRETTY_FUNCTION__); }
float get_rx_gain() override
{
log->info("%s\n", __PRETTY_FUNCTION__);
logger.info("%s", __PRETTY_FUNCTION__);
return 0.0;
}
void set_tx_gain(const float& gain) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_tx_gain(const float& gain) override { logger.info("%s", __PRETTY_FUNCTION__); }
void set_tx_freq(const uint32_t& channel_idx, const double& freq) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_tx_freq(const uint32_t& channel_idx, const double& freq) override { logger.info("%s", __PRETTY_FUNCTION__); }
void set_rx_freq(const uint32_t& channel_idx, const double& freq) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_rx_freq(const uint32_t& channel_idx, const double& freq) override { logger.info("%s", __PRETTY_FUNCTION__); }
double get_freq_offset() override
{
log->info("%s\n", __PRETTY_FUNCTION__);
logger.info("%s", __PRETTY_FUNCTION__);
return 0.0;
}
void set_tx_srate(const double& srate) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_tx_srate(const double& srate) override { logger.info("%s", __PRETTY_FUNCTION__); }
void set_rx_srate(const double& srate) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_rx_srate(const double& srate) override { logger.info("%s", __PRETTY_FUNCTION__); }
void set_channel_rx_offset(uint32_t ch, int32_t offset_samples) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void set_channel_rx_offset(uint32_t ch, int32_t offset_samples) override { logger.info("%s", __PRETTY_FUNCTION__); }
srslte_rf_info_t* get_info() override
{
log->info("%s\n", __PRETTY_FUNCTION__);
logger.info("%s", __PRETTY_FUNCTION__);
return nullptr;
}
bool get_is_start_of_burst() override { return true; }
void release_freq(const uint32_t& carrier_idx) override { log->info("%s\n", __PRETTY_FUNCTION__); }
void release_freq(const uint32_t& carrier_idx) override { logger.info("%s", __PRETTY_FUNCTION__); }
protected:
rf_args_t args = {};
srslte::log_ref log;
srslog::basic_logger& logger = srslog::fetch_basic_logger("RF", false);
bool running = false;
srslte::rf_metrics_t rf_metrics = {};

@ -7,7 +7,7 @@
#
if(RF_FOUND)
add_library(srslte_radio STATIC radio.cc radio_null.cc channel_mapping.cc)
add_library(srslte_radio STATIC radio.cc channel_mapping.cc)
target_link_libraries(srslte_radio srslte_rf srslte_common)
INSTALL(TARGETS srslte_radio DESTINATION ${LIBRARY_DIR})
endif(RF_FOUND)

@ -27,7 +27,7 @@ bool channel_mapping::allocate_freq(const uint32_t& logical_ch, const float& fre
std::lock_guard<std::mutex> lock(mutex);
if (allocated_channels.count(logical_ch)) {
ERROR("allocate_freq: Carrier logical_ch=%d already allocated to channel=%d\n",
ERROR("allocate_freq: Carrier logical_ch=%d already allocated to channel=%d",
logical_ch,
allocated_channels[logical_ch].carrier_idx);
return false;
@ -41,7 +41,7 @@ bool channel_mapping::allocate_freq(const uint32_t& logical_ch, const float& fre
return true;
}
}
ERROR("allocate_freq: No channels available for frequency=%.1f %s\n", freq, to_string().c_str());
ERROR("allocate_freq: No channels available for frequency=%.1f %s", freq, to_string().c_str());
return false;
}

@ -19,7 +19,7 @@
namespace srslte {
radio::radio(srslte::log_filter* log_h_) : logger(nullptr), log_h(log_h_), zeros(nullptr)
radio::radio() : zeros(nullptr)
{
zeros = srslte_vec_cf_malloc(SRSLTE_SF_LEN_MAX);
srslte_vec_cf_zero(zeros, SRSLTE_SF_LEN_MAX);
@ -29,15 +29,6 @@ radio::radio(srslte::log_filter* log_h_) : logger(nullptr), log_h(log_h_), zeros
}
}
radio::radio(srslte::logger* logger_) : logger(logger_), log_h(nullptr), zeros(nullptr)
{
zeros = srslte_vec_cf_malloc(SRSLTE_SF_LEN_MAX);
srslte_vec_cf_zero(zeros, SRSLTE_SF_LEN_MAX);
for (uint32_t i = 0; i < SRSLTE_MAX_CHANNELS; i++) {
dummy_buffers[i] = srslte_vec_cf_malloc(SRSLTE_SF_LEN_MAX);
}
}
radio::~radio()
{
if (zeros) {
@ -65,24 +56,15 @@ int radio::init(const rf_args_t& args, phy_interface_radio* phy_)
phy = phy_;
// Init log
if (log_h == nullptr) {
if (logger != nullptr) {
log_local.init("RF ", logger);
log_local.set_level(args.log_level);
log_h = &log_local;
} else {
fprintf(stderr, "Must all radio constructor with either logger or log_filter\n");
return SRSLTE_ERROR;
}
}
logger.set_level(srslog::str_to_basic_level(args.log_level));
if (args.nof_antennas > SRSLTE_MAX_PORTS) {
log_h->error("Maximum number of antennas exceeded (%d > %d)\n", args.nof_antennas, SRSLTE_MAX_PORTS);
logger.error("Maximum number of antennas exceeded (%d > %d)", args.nof_antennas, SRSLTE_MAX_PORTS);
return SRSLTE_ERROR;
}
if (args.nof_carriers > SRSLTE_MAX_CARRIERS) {
log_h->error("Maximum number of carriers exceeded (%d > %d)\n", args.nof_carriers, SRSLTE_MAX_CARRIERS);
logger.error("Maximum number of carriers exceeded (%d > %d)", args.nof_carriers, SRSLTE_MAX_CARRIERS);
return SRSLTE_ERROR;
}
@ -134,7 +116,7 @@ int radio::init(const rf_args_t& args, phy_interface_radio* phy_)
// Init and start Radios
for (uint32_t device_idx = 0; device_idx < (uint32_t)device_args_list.size(); device_idx++) {
if (not open_dev(device_idx, args.device_name, device_args_list[device_idx])) {
log_h->error("Error opening RF device %d\n", device_idx);
logger.error("Error opening RF device %d", device_idx);
return SRSLTE_ERROR;
}
}
@ -179,11 +161,11 @@ int radio::init(const rf_args_t& args, phy_interface_radio* phy_)
uint32_t rf_device_idx = phys_antenna_idx / nof_channels_x_dev;
uint32_t rf_channel_idx = phys_antenna_idx % nof_channels_x_dev;
log_h->info(
"Setting individual tx_gain=%.1f on dev=%d ch=%d\n", args.tx_gain_ch[i], rf_device_idx, rf_channel_idx);
logger.info(
"Setting individual tx_gain=%.1f on dev=%d ch=%d", args.tx_gain_ch[i], rf_device_idx, rf_channel_idx);
if (srslte_rf_set_tx_gain_ch(&rf_devices[rf_device_idx], rf_channel_idx, args.tx_gain_ch[i]) < 0) {
log_h->error(
"Setting channel tx_gain=%.1f on dev=%d ch=%d\n", args.tx_gain_ch[i], rf_device_idx, rf_channel_idx);
logger.error(
"Setting channel tx_gain=%.1f on dev=%d ch=%d", args.tx_gain_ch[i], rf_device_idx, rf_channel_idx);
}
}
}
@ -199,11 +181,11 @@ int radio::init(const rf_args_t& args, phy_interface_radio* phy_)
uint32_t rf_device_idx = phys_antenna_idx / nof_channels_x_dev;
uint32_t rf_channel_idx = phys_antenna_idx % nof_channels_x_dev;
log_h->info(
"Setting individual rx_gain=%.1f on dev=%d ch=%d\n", args.rx_gain_ch[i], rf_device_idx, rf_channel_idx);
logger.info(
"Setting individual rx_gain=%.1f on dev=%d ch=%d", args.rx_gain_ch[i], rf_device_idx, rf_channel_idx);
if (srslte_rf_set_rx_gain_ch(&rf_devices[rf_device_idx], rf_channel_idx, args.rx_gain_ch[i]) < 0) {
log_h->error(
"Setting channel rx_gain=%.1f on dev=%d ch=%d\n", args.rx_gain_ch[i], rf_device_idx, rf_channel_idx);
logger.error(
"Setting channel rx_gain=%.1f on dev=%d ch=%d", args.rx_gain_ch[i], rf_device_idx, rf_channel_idx);
}
}
}
@ -284,7 +266,7 @@ bool radio::start_agc(bool tx_gain_same_rx)
}
for (srslte_rf_t& rf_device : rf_devices) {
if (srslte_rf_start_gain_thread(&rf_device, tx_gain_same_rx)) {
ERROR("Error starting AGC Thread RF device\n");
ERROR("Error starting AGC Thread RF device");
return false;
}
}
@ -354,7 +336,7 @@ bool radio::rx_dev(const uint32_t& device_idx, const rf_buffer_interface& buffer
}
if (not map_channels(rx_channel_mapping, device_idx, 0, buffer, radio_buffers)) {
log_h->error("Mapping logical channels to physical channels for transmission\n");
logger.error("Mapping logical channels to physical channels for transmission");
return false;
}
@ -442,7 +424,7 @@ bool radio::open_dev(const uint32_t& device_idx, const std::string& device_name,
dev_args ? dev_args : "default");
if (srslte_rf_open_devname(rf_device, dev_name, dev_args, nof_channels_x_dev)) {
log_h->error("Error opening RF device\n");
logger.error("Error opening RF device");
return false;
}
@ -499,7 +481,7 @@ bool radio::tx_dev(const uint32_t& device_idx, rf_buffer_interface& buffer, cons
nof_samples = nof_samples - past_nsamples; // Subtracts the number of trimmed samples
// Prints discarded samples
log_h->debug("Detected RF overlap of %.1f us. Discarding %d samples. Power=%+.1f dBfs\n",
logger.debug("Detected RF overlap of %.1f us. Discarding %d samples. Power=%+.1f dBfs",
srslte_timestamp_real(&ts_overlap) * 1.0e6,
past_nsamples,
srslte_convert_power_to_dB(srslte_vec_avg_power_cf(&buffer.get(0)[nof_samples], past_nsamples)));
@ -507,10 +489,10 @@ bool radio::tx_dev(const uint32_t& device_idx, rf_buffer_interface& buffer, cons
} else if (past_nsamples < 0 and not is_start_of_burst) {
// if the gap is bigger than TX_MAX_GAP_ZEROS, stop burst
if (fabs(srslte_timestamp_real(&ts_overlap)) > tx_max_gap_zeros) {
log_h->info("Detected RF gap of %.1f us. Sending end-of-burst.\n", srslte_timestamp_real(&ts_overlap) * 1.0e6);
logger.info("Detected RF gap of %.1f us. Sending end-of-burst.", srslte_timestamp_real(&ts_overlap) * 1.0e6);
tx_end();
} else {
log_h->debug("Detected RF gap of %.1f us. Tx'ing zeroes.\n", srslte_timestamp_real(&ts_overlap) * 1.0e6);
logger.debug("Detected RF gap of %.1f us. Tx'ing zeroes.", srslte_timestamp_real(&ts_overlap) * 1.0e6);
// Otherwise, transmit zeros
uint32_t gap_nsamples = abs(past_nsamples);
while (gap_nsamples > 0) {
@ -550,7 +532,7 @@ bool radio::tx_dev(const uint32_t& device_idx, rf_buffer_interface& buffer, cons
}
if (not map_channels(tx_channel_mapping, device_idx, sample_offset, buffer, radio_buffers)) {
log_h->error("Mapping logical channels to physical channels for transmission\n");
logger.error("Mapping logical channels to physical channels for transmission");
return false;
}
@ -597,7 +579,7 @@ void radio::set_rx_freq(const uint32_t& carrier_idx, const double& freq)
// Map carrier index to physical channel
if (rx_channel_mapping.allocate_freq(carrier_idx, freq)) {
channel_mapping::device_mapping_t device_mapping = rx_channel_mapping.get_device_mapping(carrier_idx);
log_h->info("Mapping RF channel %d (device=%d, channel=%d) to logical carrier %d on f_rx=%.1f MHz\n",
logger.info("Mapping RF channel %d (device=%d, channel=%d) to logical carrier %d on f_rx=%.1f MHz",
device_mapping.carrier_idx,
device_mapping.device_idx,
device_mapping.channel_idx,
@ -611,16 +593,16 @@ void radio::set_rx_freq(const uint32_t& carrier_idx, const double& freq)
srslte_rf_set_rx_freq(&rf_devices[dm.device_idx], dm.channel_idx, freq + freq_offset);
}
} else {
log_h->error("set_rx_freq: physical_channel_idx=%d for %d antennas exceeds maximum channels (%d)\n",
logger.error("set_rx_freq: physical_channel_idx=%d for %d antennas exceeds maximum channels (%d)",
device_mapping.carrier_idx,
nof_antennas,
nof_channels);
}
} else {
log_h->info("RF Rx channel %d already on freq\n", device_mapping.carrier_idx);
logger.info("RF Rx channel %d already on freq", device_mapping.carrier_idx);
}
} else {
log_h->error("set_rx_freq: Could not allocate frequency %.1f MHz to carrier %d\n", freq / 1e6, carrier_idx);
logger.error("set_rx_freq: Could not allocate frequency %.1f MHz to carrier %d", freq / 1e6, carrier_idx);
}
}
@ -646,7 +628,6 @@ void radio::set_rx_gain_th(const float& gain)
void radio::set_rx_srate(const double& srate)
{
if (!is_initialized) {
return;
}
@ -714,7 +695,7 @@ void radio::set_tx_freq(const uint32_t& carrier_idx, const double& freq)
// Map carrier index to physical channel
if (tx_channel_mapping.allocate_freq(carrier_idx, freq)) {
channel_mapping::device_mapping_t device_mapping = tx_channel_mapping.get_device_mapping(carrier_idx);
log_h->info("Mapping RF channel %d (device=%d, channel=%d) to logical carrier %d on f_tx=%.1f MHz\n",
logger.info("Mapping RF channel %d (device=%d, channel=%d) to logical carrier %d on f_tx=%.1f MHz",
device_mapping.carrier_idx,
device_mapping.device_idx,
device_mapping.channel_idx,
@ -729,16 +710,16 @@ void radio::set_tx_freq(const uint32_t& carrier_idx, const double& freq)
srslte_rf_set_tx_freq(&rf_devices[device_mapping.device_idx], device_mapping.channel_idx, freq + freq_offset);
}
} else {
log_h->error("set_tx_freq: physical_channel_idx=%d for %d antennas exceeds maximum channels (%d)\n",
logger.error("set_tx_freq: physical_channel_idx=%d for %d antennas exceeds maximum channels (%d)",
device_mapping.carrier_idx,
nof_antennas,
nof_channels);
}
} else {
log_h->info("RF Tx channel %d already on freq\n", device_mapping.carrier_idx);
logger.info("RF Tx channel %d already on freq", device_mapping.carrier_idx);
}
} else {
log_h->error("set_tx_freq: Could not allocate frequency %.1f MHz to carrier %d\n", freq / 1e6, carrier_idx);
logger.error("set_tx_freq: Could not allocate frequency %.1f MHz to carrier %d", freq / 1e6, carrier_idx);
}
}
@ -770,11 +751,9 @@ double radio::get_dev_cal_tx_adv_sec(const std::string& device_name)
int nsamples = 0;
/* Set time advance for each known device if in auto mode */
if (tx_adv_auto) {
/* This values have been calibrated using the prach_test_usrp tool in srsLTE */
if (device_name == "uhd_b200") {
double srate_khz = round(cur_tx_srate / 1e3);
if (srate_khz == 1.92e3) {
// 6 PRB
@ -847,11 +826,9 @@ double radio::get_dev_cal_tx_adv_sec(const std::string& device_name)
}
} else if (device_name == "uhd_x300") {
// In X300 TX/RX offset is independent of sampling rate
nsamples = 45;
} else if (device_name == "bladerf") {
double srate_khz = round(cur_tx_srate / 1e3);
if (srate_khz == 1.92e3) {
nsamples = 16;
@ -943,27 +920,26 @@ void radio::handle_rf_msg(srslte_rf_error_t error)
if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_OVERFLOW) {
rf_metrics.rf_o++;
rf_metrics.rf_error = true;
log_h->info("Overflow\n");
logger.info("Overflow");
// inform PHY about overflow
phy->radio_overflow();
} else if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_UNDERFLOW) {
rf_metrics.rf_u++;
rf_metrics.rf_error = true;
log_h->info("Underflow\n");
logger.info("Underflow");
} else if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_LATE) {
rf_metrics.rf_l++;
rf_metrics.rf_error = true;
log_h->info("Late (detected in %s)\n", error.opt ? "rx call" : "asynchronous thread");
logger.info("Late (detected in %s)", error.opt ? "rx call" : "asynchronous thread");
} else if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_RX) {
log_h->error("Fatal radio error occured.\n");
logger.error("Fatal radio error occured.");
phy->radio_failure();
} else if (error.type == srslte_rf_error_t::SRSLTE_RF_ERROR_OTHER) {
std::string str(error.msg);
str.erase(std::remove(str.begin(), str.end(), '\n'), str.end());
str.erase(std::remove(str.begin(), str.end(), '\r'), str.end());
str.push_back('\n');
log_h->info("%s\n", str.c_str());
logger.info("%s", str.c_str());
}
}
@ -1028,7 +1004,7 @@ bool radio::config_rf_channels(const rf_args_t& args)
// Parse DL band for this channel
c.band.set(args.ch_rx_bands[i].min, args.ch_rx_bands[i].max);
dl_rf_channels.push_back(c);
log_h->info("Configuring physical DL channel %d with band-pass filter (%.1f, %.1f)\n",
logger.info("Configuring physical DL channel %d with band-pass filter (%.1f, %.1f)",
i,
c.band.get_low(),
c.band.get_high());
@ -1036,7 +1012,7 @@ bool radio::config_rf_channels(const rf_args_t& args)
// Parse UL band for this channel
c.band.set(args.ch_tx_bands[i].min, args.ch_tx_bands[i].max);
ul_rf_channels.push_back(c);
log_h->info("Configuring physical UL channel %d with band-pass filter (%.1f, %.1f)\n",
logger.info("Configuring physical UL channel %d with band-pass filter (%.1f, %.1f)",
i,
c.band.get_low(),
c.band.get_high());

@ -1,20 +0,0 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2020 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 "srslte/radio/radio_null.h"
#include <mutex>
namespace srslte {
radio_null::radio_null(srslte::logger* logger_) : log("RF"), radio_base(logger_) {}
} // namespace srslte

@ -35,7 +35,6 @@ using namespace srslte;
static std::array<std::string, SRSLTE_MAX_RADIOS> radios_args = {};
static char radio_device[64];
static log_filter log_h;
static std::string file_pattern = "radio%d.dat";
static double freq = 2630e6;
static uint32_t nof_radios = 1;
@ -207,7 +206,6 @@ static void* plot_thread_run(void* arg)
static int init_plots(uint32_t frame_size)
{
if (sem_init(&plot_sem, 0, 0)) {
perror("sem_init");
exit(-1);
@ -218,7 +216,7 @@ static int init_plots(uint32_t frame_size)
uint32_t plot_idx = r * nof_ports + p;
fft_plot_buffer[plot_idx] = srslte_vec_cf_malloc(frame_size);
if (!fft_plot_buffer[plot_idx]) {
ERROR("Error: Allocating buffer\n");
ERROR("Error: Allocating buffer");
return SRSLTE_ERROR;
}
}
@ -226,12 +224,12 @@ static int init_plots(uint32_t frame_size)
fft_plot_temp = srslte_vec_f_malloc(frame_size);
if (!fft_plot_temp) {
ERROR("Error: Allocating buffer\n");
ERROR("Error: Allocating buffer");
return SRSLTE_ERROR;
}
if (srslte_dft_plan_c(&dft_spectrum, frame_size, SRSLTE_DFT_FORWARD)) {
ERROR("Creating DFT spectrum plan\n");
ERROR("Creating DFT spectrum plan");
return SRSLTE_ERROR;
}
@ -293,7 +291,7 @@ static void* radio_thread_run(void* arg)
/* Instanciate and allocate memory */
printf("Instantiating objects and allocating memory...\n");
for (uint32_t r = 0; r < nof_radios; r++) {
radio_h[r] = new radio(&log_h);
radio_h[r] = new radio;
if (!radio_h[r]) {
fprintf(stderr, "Error: Calling radio constructor\n");
goto clean_exit;
@ -308,7 +306,7 @@ static void* radio_thread_run(void* arg)
for (uint32_t p = 0; p < nof_ports; p++) {
buffers[r][p] = srslte_vec_cf_malloc(frame_size);
if (!buffers[r][p]) {
ERROR("Error: Allocating buffer (%d,%d)\n", r, p);
ERROR("Error: Allocating buffer (%d,%d)", r, p);
goto clean_exit;
}
}
@ -364,7 +362,7 @@ static void* radio_thread_run(void* arg)
snprintf(filename, 256, file_pattern.c_str(), r);
INFO("Opening filesink %s for radio %d", filename, r);
if (srslte_filesink_init(&filesink[r], filename, SRSLTE_COMPLEX_FLOAT_BIN)) {
ERROR("Initiating filesink for radio %d\n", r);
ERROR("Initiating filesink for radio %d", r);
goto clean_exit;
}
}
@ -374,11 +372,11 @@ static void* radio_thread_run(void* arg)
if (measure_delay) {
if (nof_radios > 1) {
if (srslte_dft_plan_c(&dft_plan, frame_size, SRSLTE_DFT_FORWARD)) {
ERROR("Creating DFT plan\n");
ERROR("Creating DFT plan");
goto clean_exit;
}
if (srslte_dft_plan_c(&idft_plan, frame_size, SRSLTE_DFT_BACKWARD)) {
ERROR("Creating IDFT plan\n");
ERROR("Creating IDFT plan");
goto clean_exit;
}
} else {
@ -603,6 +601,8 @@ int main(int argc, char** argv)
// Parse args
parse_args(argc, argv);
srslog::init();
if (pthread_create(&radio_thread, NULL, radio_thread_run, NULL)) {
perror("pthread_create");
exit(-1);

@ -62,7 +62,7 @@ int enb::init(const all_args_t& args_, srslte::logger* logger_)
return SRSLTE_ERROR;
}
std::unique_ptr<srslte::radio> lte_radio = std::unique_ptr<srslte::radio>(new srslte::radio(logger));
std::unique_ptr<srslte::radio> lte_radio = std::unique_ptr<srslte::radio>(new srslte::radio);
if (!lte_radio) {
srslte::console("Error creating radio multi instance.\n");
return SRSLTE_ERROR;
@ -103,7 +103,7 @@ int enb::init(const all_args_t& args_, srslte::logger* logger_)
} else if (args.stack.type == "nr") {
#ifdef HAVE_5GNR
std::unique_ptr<srsenb::gnb_stack_nr> nr_stack(new srsenb::gnb_stack_nr(logger));
std::unique_ptr<srslte::radio_null> nr_radio(new srslte::radio_null(logger));
std::unique_ptr<srslte::radio_null> nr_radio(new srslte::radio_null);
std::unique_ptr<srsenb::vnf_phy_nr> nr_phy(new srsenb::vnf_phy_nr);
// Init layers

@ -78,7 +78,7 @@ int ue::init(const all_args_t& args_, srslte::logger* logger_)
return SRSLTE_ERROR;
}
std::unique_ptr<srslte::radio> lte_radio = std::unique_ptr<srslte::radio>(new srslte::radio(old_logger));
std::unique_ptr<srslte::radio> lte_radio = std::unique_ptr<srslte::radio>(new srslte::radio);
if (!lte_radio) {
srslte::console("Error creating radio multi instance.\n");
return SRSLTE_ERROR;
@ -128,7 +128,7 @@ int ue::init(const all_args_t& args_, srslte::logger* logger_)
logger.info("Initializing NR stack");
#ifdef HAVE_5GNR
std::unique_ptr<srsue::ue_stack_nr> nr_stack(new srsue::ue_stack_nr(old_logger));
std::unique_ptr<srslte::radio_null> nr_radio(new srslte::radio_null(old_logger));
std::unique_ptr<srslte::radio_null> nr_radio(new srslte::radio_null);
std::unique_ptr<srsue::vnf_phy_nr> nr_phy(new srsue::vnf_phy_nr);
std::unique_ptr<gw> gw_ptr(new gw());

@ -480,11 +480,11 @@ int main(int argc, char** argv)
if (earfcn_dl >= 0) {
// Create radio log
radio_log = std::unique_ptr<srslte::log_filter>(new srslte::log_filter("Radio"));
radio_log->set_level(radio_log_level);
auto& radio_logger = srslog::fetch_basic_logger("RF", false);
radio_logger.set_level(srslog::str_to_basic_level(radio_log_level));
// Create radio
radio = std::unique_ptr<srslte::radio>(new srslte::radio(radio_log.get()));
radio = std::unique_ptr<srslte::radio>(new srslte::radio);
// Init radio
srslte::rf_args_t radio_args = {};

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