/**
*
* \ 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 "srsran/common/band_helper.h"
# include "srsran/common/string_helpers.h"
# include "srsran/common/test_common.h"
# include "srsran/interfaces/phy_interface_types.h"
# include "srsran/radio/radio.h"
# include "srsran/srslog/srslog.h"
# include "srsue/hdr/phy/scell/intra_measure_nr.h"
# include <boost/program_options.hpp>
# include <boost/program_options/parsers.hpp>
# include <iostream>
# include <map>
# include <memory>
# include <vector>
// Test gNb class
class test_gnb
{
private :
uint32_t pci ;
uint32_t sf_len = 0 ;
srsran_ssb_t ssb = { } ;
std : : vector < cf_t > signal_buffer = { } ;
srslog : : basic_logger & logger ;
srsran : : channel channel ;
std : : vector < cf_t > buffer ;
public :
struct args_t {
uint32_t pci = 500 ;
double srate_hz = 11.52e6 ;
double center_freq_hz = 3.5e9 ;
double ssb_freq_hz = 3.5e9 - 960e3 ;
srsran_subcarrier_spacing_t ssb_scs = srsran_subcarrier_spacing_30kHz ;
uint32_t ssb_period_ms = 20 ;
uint16_t band ;
srsran : : channel : : args_t channel ;
std : : string log_level = " error " ;
srsran_ssb_patern_t get_ssb_pattern ( ) const { return srsran : : srsran_band_helper ( ) . get_ssb_pattern ( band , ssb_scs ) ; }
srsran_duplex_mode_t get_duplex_mode ( ) const { return srsran : : srsran_band_helper ( ) . get_duplex_mode ( band ) ; }
} ;
test_gnb ( const args_t & args ) :
logger ( srslog : : fetch_basic_logger ( " PCI= " + std : : to_string ( args . pci ) ) ) , channel ( args . channel , 1 , logger )
{
logger . set_level ( srslog : : str_to_basic_level ( args . log_level ) ) ;
// Initialise internals
pci = args . pci ;
sf_len = ( uint32_t ) round ( args . srate_hz / 1000 ) ;
// Allocate buffer
buffer . resize ( sf_len ) ;
// Initialise SSB
srsran_ssb_args_t ssb_args = { } ;
ssb_args . max_srate_hz = args . srate_hz ;
ssb_args . min_scs = args . ssb_scs ;
ssb_args . enable_encode = true ;
if ( srsran_ssb_init ( & ssb , & ssb_args ) < SRSRAN_SUCCESS ) {
logger . error ( " Error initialising SSB " ) ;
return ;
}
// Configure SSB
srsran_ssb_cfg_t ssb_cfg = { } ;
ssb_cfg . srate_hz = args . srate_hz ;
ssb_cfg . center_freq_hz = args . center_freq_hz ;
ssb_cfg . ssb_freq_hz = args . ssb_freq_hz ;
ssb_cfg . scs = args . ssb_scs ;
ssb_cfg . pattern = args . get_ssb_pattern ( ) ;
ssb_cfg . duplex_mode = args . get_duplex_mode ( ) ;
ssb_cfg . periodicity_ms = args . ssb_period_ms ;
if ( srsran_ssb_set_cfg ( & ssb , & ssb_cfg ) < SRSRAN_SUCCESS ) {
logger . error ( " Error configuring SSB " ) ;
return ;
}
// Configure channel
channel . set_srate ( ( uint32_t ) args . srate_hz ) ;
}
int work ( uint32_t sf_idx , std : : vector < cf_t > & baseband_buffer , const srsran : : rf_timestamp_t & ts )
{
logger . set_context ( sf_idx ) ;
// Zero buffer
srsran_vec_cf_zero ( buffer . data ( ) , ( uint32_t ) buffer . size ( ) ) ;
// Check if SSB needs to be sent
if ( srsran_ssb_send ( & ssb , sf_idx ) ) {
// Prepare PBCH message
srsran_pbch_msg_nr_t msg = { } ;
// Add SSB
if ( srsran_ssb_add ( & ssb , pci , & msg , buffer . data ( ) , buffer . data ( ) ) < SRSRAN_SUCCESS ) {
logger . error ( " Error adding SSB " ) ;
return SRSRAN_ERROR ;
}
}
// Run channel
cf_t * in [ SRSRAN_MAX_CHANNELS ] = { } ;
cf_t * out [ SRSRAN_MAX_CHANNELS ] = { } ;
in [ 0 ] = buffer . data ( ) ;
out [ 0 ] = buffer . data ( ) ;
channel . run ( in , out , ( uint32_t ) buffer . size ( ) , ts . get ( 0 ) ) ;
// Add buffer to baseband buffer
srsran_vec_sum_ccc ( baseband_buffer . data ( ) , buffer . data ( ) , baseband_buffer . data ( ) , ( uint32_t ) buffer . size ( ) ) ;
return SRSRAN_SUCCESS ;
}
~ test_gnb ( ) { srsran_ssb_free ( & ssb ) ; }
} ;
struct args_t {
// General
std : : string log_level = " warning " ;
uint32_t duration_s = 1 ;
double srate_hz = 11.52e6 ;
uint32_t carier_arfcn = 634240 ;
uint32_t ssb_arfcn = 634176 ;
std : : string ssb_scs_str = " 30 " ;
// Measurement parameters
std : : set < uint32_t > pcis_to_meas ;
uint32_t meas_len_ms = 1 ;
uint32_t meas_period_ms = 20 ;
float thr_snr_db = 5.0f ;
srsran_subcarrier_spacing_t ssb_scs = srsran_subcarrier_spacing_30kHz ;
// Simulation parameters
std : : set < uint32_t > pcis_to_simulate ;
uint32_t ssb_period_ms = 20 ;
float channel_delay_min = 0.0f ; // Set to non-zero value to stir the delay from zero to this value in usec
float channel_delay_max = 0.0f ; // Set to non-zero value to stir the delay from zero to this value in usec
// On the Fly parameters
std : : string radio_device_name = " auto " ;
std : : string radio_device_args = " auto " ;
std : : string radio_log_level = " info " ;
float rx_gain = 60.0f ;
// File parameters
std : : string filename = " " ;
double file_freq_offset_hz = 0.0 ;
} ;
class meas_itf_listener : public srsue : : scell : : intra_measure_base : : meas_itf
{
public :
typedef struct {
float rsrp_avg ;
float rsrp_min ;
float rsrp_max ;
float rsrq_avg ;
float rsrq_min ;
float rsrq_max ;
uint32_t count ;
} cell_meas_t ;
std : : map < uint32_t , cell_meas_t > cells ;
void cell_meas_reset ( uint32_t cc_idx ) override { }
void new_cell_meas ( uint32_t cc_idx , const std : : vector < srsue : : phy_meas_t > & meas ) override
{
for ( const srsue : : phy_meas_t & m : meas ) {
uint32_t pci = m . pci ;
if ( ! cells . count ( pci ) ) {
cells [ pci ] . rsrp_min = m . rsrp ;
cells [ pci ] . rsrp_max = m . rsrp ;
cells [ pci ] . rsrp_avg = m . rsrp ;
cells [ pci ] . rsrq_min = m . rsrq ;
cells [ pci ] . rsrq_max = m . rsrq ;
cells [ pci ] . rsrq_avg = m . rsrq ;
cells [ pci ] . count = 1 ;
} else {
cells [ pci ] . rsrp_min = SRSRAN_MIN ( cells [ pci ] . rsrp_min , m . rsrp ) ;
cells [ pci ] . rsrp_max = SRSRAN_MAX ( cells [ pci ] . rsrp_max , m . rsrp ) ;
cells [ pci ] . rsrp_avg = ( m . rsrp + cells [ pci ] . rsrp_avg * cells [ pci ] . count ) / ( cells [ pci ] . count + 1 ) ;
cells [ pci ] . rsrq_min = SRSRAN_MIN ( cells [ pci ] . rsrq_min , m . rsrq ) ;
cells [ pci ] . rsrq_max = SRSRAN_MAX ( cells [ pci ] . rsrq_max , m . rsrq ) ;
cells [ pci ] . rsrq_avg = ( m . rsrq + cells [ pci ] . rsrq_avg * cells [ pci ] . count ) / ( cells [ pci ] . count + 1 ) ;
cells [ pci ] . count + + ;
}
}
}
bool print_stats ( args_t args )
{
printf ( " \n -- Statistics: \n " ) ;
uint32_t true_counts = 0 ;
uint32_t false_counts = 0 ;
uint32_t tti_count = ( 1000 * args . duration_s ) / args . meas_period_ms ;
uint32_t ideal_true_counts = args . pcis_to_simulate . size ( ) * tti_count ;
uint32_t ideal_false_counts = tti_count * cells . size ( ) - ideal_true_counts ;
for ( auto & e : cells ) {
bool false_alarm = args . pcis_to_simulate . find ( e . first ) = = args . pcis_to_simulate . end ( ) ;
if ( args . pcis_to_simulate . empty ( ) ) {
false_alarm = ( args . pcis_to_meas . count ( e . first ) = = 0 ) ;
ideal_true_counts = args . pcis_to_meas . size ( ) * tti_count ;
}
if ( false_alarm ) {
false_counts + = e . second . count ;
} else {
true_counts + = e . second . count ;
}
printf ( " pci=%03d; count=%3d; false=%s; rsrp=%+.1f|%+.1f|%+.1fdBfs; rsrq=%+.1f|%+.1f|%+.1fdB; \n " ,
e . first ,
e . second . count ,
false_alarm ? " y " : " n " ,
e . second . rsrp_min ,
e . second . rsrp_avg ,
e . second . rsrp_max ,
e . second . rsrq_min ,
e . second . rsrq_avg ,
e . second . rsrq_max ) ;
}
float prob_detection = ( ideal_true_counts ) ? ( float ) true_counts / ( float ) ideal_true_counts : 0.0f ;
float prob_false_alarm = ( ideal_false_counts ) ? ( float ) false_counts / ( float ) ideal_false_counts : 0.0f ;
printf ( " \n " ) ;
printf ( " Probability of detection: %.6f \n " , prob_detection ) ;
printf ( " Probability of false alarm: %.6f \n " , prob_false_alarm ) ;
return ( prob_detection > = 0.9f & & prob_false_alarm < = 0.1f ) ;
}
} ;
static void pci_list_parse_helper ( std : : string & list_str , std : : set < uint32_t > & list )
{
if ( list_str = = " all " ) {
// Add all possible cells
for ( int i = 0 ; i < SRSRAN_NOF_NID_NR ; i + + ) {
list . insert ( i ) ;
}
} else if ( list_str = = " none " ) {
list . clear ( ) ;
} else if ( not list_str . empty ( ) ) {
// Remove spaces from neightbour cell list
list_str = srsran : : string_remove_char ( list_str , ' ' ) ;
// Add cell to known cells
srsran : : string_parse_list ( list_str , ' , ' , list ) ;
}
}
// shorten boost program options namespace
namespace bpo = boost : : program_options ;
int parse_args ( int argc , char * * argv , args_t & args )
{
int ret = SRSRAN_SUCCESS ;
std : : string active_cell_list = " 500 " ;
std : : string simulation_cell_list = " " ;
std : : string ssb_scs = " 30 " ;
bpo : : options_description options ( " General options " ) ;
bpo : : options_description measure ( " Measurement options " ) ;
bpo : : options_description over_the_air ( " Mode 1: Over the air options (Default) " ) ;
bpo : : options_description simulation ( " Mode 2: Simulation options (enabled if simulation_cell_list is not empty) " ) ;
bpo : : options_description file ( " Mode 3: File (enabled if filename is provided) " ) ;
// clang-format off
measure . add_options ( )
( " meas_len_ms " , bpo : : value < uint32_t > ( & args . meas_len_ms ) - > default_value ( args . meas_len_ms ) , " Measurement length " )
( " meas_period_ms " , bpo : : value < uint32_t > ( & args . meas_period_ms ) - > default_value ( args . meas_period_ms ) , " Measurement period " )
( " active_cell_list " , bpo : : value < std : : string > ( & active_cell_list ) - > default_value ( active_cell_list ) , " Comma separated PCI cell list to measure " )
( " thr_snr_db " , bpo : : value < float > ( & args . thr_snr_db ) - > default_value ( args . thr_snr_db ) , " Detection threshold for SNR in dB " )
;
over_the_air . add_options ( )
( " rf.device_name " , bpo : : value < std : : string > ( & args . radio_device_name ) - > default_value ( args . radio_device_name ) , " RF Device Name " )
( " rf.device_args " , bpo : : value < std : : string > ( & args . radio_device_args ) - > default_value ( args . radio_device_args ) , " RF Device arguments " )
( " rf.log_level " , bpo : : value < std : : string > ( & args . radio_log_level ) - > default_value ( args . radio_log_level ) , " RF Log level (none, warning, info, debug) " )
( " rf.rx_gain " , bpo : : value < float > ( & args . rx_gain ) - > default_value ( args . rx_gain ) , " RF Receiver gain in dB " )
;
simulation . add_options ( )
( " simulation_cell_list " , bpo : : value < std : : string > ( & simulation_cell_list ) - > default_value ( simulation_cell_list ) , " Comma separated PCI cell list to simulate " )
( " ssb_period " , bpo : : value < uint32_t > ( & args . ssb_period_ms ) - > default_value ( args . ssb_period_ms ) , " SSB period in ms " )
( " channel.delay_min " , bpo : : value < float > ( & args . channel_delay_min ) - > default_value ( args . channel_delay_min ) , " Channel delay minimum in usec. " )
( " channel.delay_max " , bpo : : value < float > ( & args . channel_delay_max ) - > default_value ( args . channel_delay_max ) , " Channel delay maximum in usec. Set to 0 to disable, otherwise it will steer the delay for the duration of the simulation " )
;
file . add_options ( )
( " file.name " , bpo : : value < std : : string > ( & args . filename ) - > default_value ( args . filename ) , " File name providing baseband " )
( " file.freq_offset " , bpo : : value < double > ( & args . file_freq_offset_hz ) - > default_value ( args . file_freq_offset_hz ) , " File name providing baseband " )
;
options . add ( measure ) . add ( over_the_air ) . add ( simulation ) . add ( file ) . add_options ( )
( " help,h " , " Show this message " )
( " log_level " , bpo : : value < std : : string > ( & args . log_level ) - > default_value ( args . log_level ) , " Intra measurement log level (none, warning, info, debug) " )
( " duration " , bpo : : value < uint32_t > ( & args . duration_s ) - > default_value ( args . duration_s ) , " Duration of the test in seconds " )
( " srate " , bpo : : value < double > ( & args . srate_hz ) - > default_value ( args . srate_hz ) , " Sampling Rate in Hz " )
( " carrier_arfcn " , bpo : : value < uint32_t > ( & args . carier_arfcn ) - > default_value ( args . carier_arfcn ) , " Carrier center frequency ARFCN " )
( " ssb_arfcn " , bpo : : value < uint32_t > ( & args . ssb_arfcn ) - > default_value ( args . ssb_arfcn ) , " SSB center frequency in ARFCN " )
( " ssb_scs " , bpo : : value < std : : string > ( & ssb_scs ) - > default_value ( ssb_scs ) , " SSB subcarrier spacing in kHz " )
;
// clang-format on
bpo : : variables_map vm ;
try {
bpo : : store ( bpo : : command_line_parser ( argc , argv ) . options ( options ) . run ( ) , vm ) ;
bpo : : notify ( vm ) ;
} catch ( bpo : : error & e ) {
std : : cerr < < e . what ( ) < < std : : endl ;
ret = SRSRAN_ERROR ;
}
// help option was given or error - print usage and exit
if ( vm . count ( " help " ) | | ret ) {
std : : cout < < " Usage: " < < argv [ 0 ] < < " [OPTIONS] config_file " < < std : : endl < < std : : endl ;
std : : cout < < options < < std : : endl < < std : : endl ;
ret = SRSRAN_ERROR ;
}
// Parse PCI lists
pci_list_parse_helper ( active_cell_list , args . pcis_to_meas ) ;
pci_list_parse_helper ( simulation_cell_list , args . pcis_to_simulate ) ;
// Parse SSB SCS
args . ssb_scs = srsran_subcarrier_spacing_from_str ( ssb_scs . c_str ( ) ) ;
if ( args . ssb_scs = = srsran_subcarrier_spacing_invalid ) {
ret = SRSRAN_ERROR ;
}
return ret ;
}
int main ( int argc , char * * argv )
{
int ret ;
// Parse args
args_t args = { } ;
if ( parse_args ( argc , argv , args ) < SRSRAN_SUCCESS ) {
return SRSRAN_ERROR ;
}
// Initiate logging
srslog : : init ( ) ;
srslog : : basic_logger & logger = srslog : : fetch_basic_logger ( " PHY " ) ;
logger . set_level ( srslog : : str_to_basic_level ( args . log_level ) ) ;
// Deduce base-band parameters
double srate_hz = args . srate_hz ;
uint32_t sf_len = ( uint32_t ) round ( srate_hz / 1000.0 ) ;
double center_freq_hz = srsran : : srsran_band_helper ( ) . nr_arfcn_to_freq ( args . carier_arfcn ) ;
double ssb_freq_hz = srsran : : srsran_band_helper ( ) . nr_arfcn_to_freq ( args . ssb_arfcn ) ;
uint16_t band = srsran : : srsran_band_helper ( ) . get_band_from_dl_freq_Hz ( center_freq_hz ) ;
logger . debug ( " Band: %d; srate: %.2f MHz; center_freq: %.1f MHz; ssb_freq: %.1f MHz; " ,
band ,
srate_hz / 1e6 ,
center_freq_hz / 1e6 ,
ssb_freq_hz / 1e6 ) ;
// Allocate buffer
std : : vector < cf_t > baseband_buffer ( sf_len ) ;
// Create measurement callback
meas_itf_listener rrc ;
// Create measurement instance
srsue : : scell : : intra_measure_nr intra_measure ( logger , rrc ) ;
// Initialise measurement instance
srsue : : scell : : intra_measure_nr : : args_t meas_args = { } ;
meas_args . rx_gain_offset_dB = 0.0f ;
meas_args . max_len_ms = args . meas_len_ms ;
meas_args . max_srate_hz = srate_hz ;
meas_args . min_scs = args . ssb_scs ;
meas_args . thr_snr_db = args . thr_snr_db ;
TESTASSERT ( intra_measure . init ( 0 , meas_args ) ) ;
// Setup measurement
srsue : : scell : : intra_measure_nr : : config_t meas_cfg = { } ;
meas_cfg . arfcn = args . carier_arfcn ;
meas_cfg . srate_hz = srate_hz ;
meas_cfg . len_ms = args . meas_len_ms ;
meas_cfg . period_ms = args . meas_period_ms ;
meas_cfg . tti_period = args . meas_period_ms ;
meas_cfg . tti_offset = 0 ;
meas_cfg . rx_gain_offset_db = 0 ;
meas_cfg . center_freq_hz = center_freq_hz ;
meas_cfg . ssb_freq_hz = ssb_freq_hz ;
meas_cfg . scs = srsran_subcarrier_spacing_30kHz ;
meas_cfg . serving_cell_pci = - 1 ;
TESTASSERT ( intra_measure . set_config ( meas_cfg ) ) ;
// Simulation only
std : : vector < std : : unique_ptr < test_gnb > > test_gnb_v ;
// Over-the-air only
std : : unique_ptr < srsran : : radio > radio = nullptr ;
// File read only
srsran_filesource_t filesource = { } ;
// Setup raio if the list of PCIs to simulate is empty
if ( not args . filename . empty ( ) ) {
if ( srsran_filesource_init ( & filesource , args . filename . c_str ( ) , SRSRAN_COMPLEX_FLOAT ) < SRSRAN_SUCCESS ) {
return SRSRAN_ERROR ;
}
} else if ( args . pcis_to_simulate . empty ( ) ) {
// Create radio log
auto & radio_logger = srslog : : fetch_basic_logger ( " RF " , false ) ;
radio_logger . set_level ( srslog : : str_to_basic_level ( args . radio_log_level ) ) ;
// Create radio
radio = std : : unique_ptr < srsran : : radio > ( new srsran : : radio ) ;
// Init radio
srsran : : rf_args_t radio_args = { } ;
radio_args . device_args = args . radio_device_args ;
radio_args . device_name = args . radio_device_name ;
radio_args . nof_carriers = 1 ;
radio_args . nof_antennas = 1 ;
radio - > init ( radio_args , nullptr ) ;
// Set sampling rate
radio - > set_rx_srate ( srate_hz ) ;
// Set frequency
radio - > set_rx_freq ( 0 , center_freq_hz ) ;
} else {
// Create test eNb's if radio is not available
for ( const uint32_t & pci : args . pcis_to_simulate ) {
// Initialise channel and push back
test_gnb : : args_t gnb_args = { } ;
gnb_args . pci = pci ;
gnb_args . srate_hz = srate_hz ;
gnb_args . center_freq_hz = center_freq_hz ;
gnb_args . ssb_freq_hz = ssb_freq_hz ;
gnb_args . ssb_scs = args . ssb_scs ;
gnb_args . ssb_period_ms = args . ssb_period_ms ;
gnb_args . band = band ;
gnb_args . log_level = args . log_level ;
gnb_args . channel . delay_enable = std : : isnormal ( args . channel_delay_max ) ;
gnb_args . channel . delay_min_us = args . channel_delay_min ;
gnb_args . channel . delay_max_us = args . channel_delay_max ;
gnb_args . channel . delay_period_s = args . duration_s ;
gnb_args . channel . delay_init_time_s = 0.0f ;
gnb_args . channel . enable = ( gnb_args . channel . delay_enable | | gnb_args . channel . awgn_enable | |
gnb_args . channel . fading_enable | | gnb_args . channel . hst_enable ) ;
test_gnb_v . push_back ( std : : unique_ptr < test_gnb > ( new test_gnb ( gnb_args ) ) ) ;
}
}
// pass cells to measure to intra_measure object
intra_measure . set_cells_to_meas ( args . pcis_to_meas ) ;
// Run loop
srsran : : rf_timestamp_t ts = { } ;
for ( uint32_t sf_idx = 0 ; sf_idx < args . duration_s * 1000 ; sf_idx + + ) {
logger . set_context ( sf_idx ) ;
// Clean buffer
srsran_vec_cf_zero ( baseband_buffer . data ( ) , sf_len ) ;
if ( not args . filename . empty ( ) ) {
if ( srsran_filesource_read ( & filesource , baseband_buffer . data ( ) , ( int ) sf_len ) < SRSRAN_SUCCESS ) {
ERROR ( " Error reading from file " ) ;
srsran_filesource_free ( & filesource ) ;
return SRSRAN_ERROR ;
}
srsran_vec_apply_cfo ( baseband_buffer . data ( ) , args . file_freq_offset_hz / args . srate_hz , baseband_buffer . data ( ) , ( int ) sf_len ) ;
} else if ( radio ) {
// Receive radio
srsran : : rf_buffer_t radio_buffer ( baseband_buffer . data ( ) , sf_len ) ;
radio - > rx_now ( radio_buffer , ts ) ;
} else {
// Run gNb simulator
for ( auto & gnb : test_gnb_v ) {
gnb - > work ( sf_idx , baseband_buffer , ts ) ;
}
// if it measuring, wait for avoiding overflowing
intra_measure . wait_meas ( ) ;
// Increase Time counter
ts . add ( 0.001 ) ;
}
// Give data to intra measure component
intra_measure . run_tti ( 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 ( ) ;
logger . warning ( " NR intra frequency performance %d Msps \n " , intra_measure . get_perf ( ) ) ;
ret = rrc . print_stats ( args ) ? SRSRAN_SUCCESS : SRSRAN_ERROR ;
if ( radio ) {
radio - > stop ( ) ;
}
if ( not args . filename . empty ( ) ) {
srsran_filesource_free ( & filesource ) ;
}
srslog : : flush ( ) ;
if ( ret = = SRSRAN_SUCCESS ) {
printf ( " Ok \n " ) ;
} else {
printf ( " Error \n " ) ;
}
return ret ;
}