/**
*
* \ section COPYRIGHT
*
* Copyright 2013 - 2015 Software Radio Systems Limited
*
* \ section LICENSE
*
* This file is part of the srsUE library .
*
* srsUE 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 .
*
* srsUE 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/.
*
*/
# include <iostream>
# include <stdlib.h>
# include <pthread.h>
# include "srslte/common/log_filter.h"
# include "srslte/common/logger_stdout.h"
# include "srslte/common/threads.h"
# include "srslte/common/rlc_pcap.h"
# include "srslte/upper/rlc.h"
# include <boost/program_options.hpp>
# include <boost/program_options/parsers.hpp>
# include <assert.h>
# include <srslte/upper/rlc_interface.h>
# define SDU_SIZE 1500
using namespace std ;
using namespace srsue ;
using namespace srslte ;
namespace bpo = boost : : program_options ;
typedef struct {
std : : string mode ;
uint32_t test_duration_sec ;
float error_rate ;
uint32_t sdu_gen_delay_usec ;
uint32_t pdu_tx_delay_usec ;
bool reestablish ;
uint32_t log_level ;
bool single_tx ;
bool write_pcap ;
float opp_sdu_ratio ;
} stress_test_args_t ;
void parse_args ( stress_test_args_t * args , int argc , char * argv [ ] ) {
// Command line only options
bpo : : options_description general ( " General options " ) ;
general . add_options ( )
( " help,h " , " Produce help message " )
( " version,v " , " Print version information and exit " ) ;
// Command line or config file options
bpo : : options_description common ( " Configuration options " ) ;
common . add_options ( )
( " mode " , bpo : : value < std : : string > ( & args - > mode ) - > default_value ( " AM " ) , " Whether to test RLC acknowledged or unacknowledged mode (AM/UM) " )
( " duration " , bpo : : value < uint32_t > ( & args - > test_duration_sec ) - > default_value ( 5 ) , " Duration (sec) " )
( " sdu_gen_delay " , bpo : : value < uint32_t > ( & args - > sdu_gen_delay_usec ) - > default_value ( 0 ) , " SDU generation delay (usec) " )
( " pdu_tx_delay " , bpo : : value < uint32_t > ( & args - > pdu_tx_delay_usec ) - > default_value ( 0 ) , " Delay in MAC for transfering PDU from tx'ing RLC to rx'ing RLC (usec) " )
( " error_rate " , bpo : : value < float > ( & args - > error_rate ) - > default_value ( 0.1 ) , " Rate at which RLC PDUs are dropped " )
( " opp_sdu_ratio " , bpo : : value < float > ( & args - > opp_sdu_ratio ) - > default_value ( 0.0 ) , " Ratio between MAC opportunity and SDU size (0==random) " )
( " reestablish " , bpo : : value < bool > ( & args - > reestablish ) - > default_value ( false ) , " Mimic RLC reestablish during execution " )
( " loglevel " , bpo : : value < uint32_t > ( & args - > log_level ) - > default_value ( srslte : : LOG_LEVEL_DEBUG ) , " Log level (1=Error,2=Warning,3=Info,4=Debug) " )
( " singletx " , bpo : : value < bool > ( & args - > single_tx ) - > default_value ( false ) , " If set to true, only one node is generating data " )
( " pcap " , bpo : : value < bool > ( & args - > write_pcap ) - > default_value ( false ) , " Whether to write all RLC PDU to PCAP file " ) ;
// these options are allowed on the command line
bpo : : options_description cmdline_options ;
cmdline_options . add ( common ) . add ( general ) ;
// parse the command line and store result in vm
bpo : : variables_map vm ;
bpo : : store ( bpo : : command_line_parser ( argc , argv ) . options ( cmdline_options ) . run ( ) , vm ) ;
bpo : : notify ( vm ) ;
// help option was given - print usage and exit
if ( vm . count ( " help " ) ) {
cout < < " Usage: " < < argv [ 0 ] < < " [OPTIONS] config_file " < < endl < < endl ;
cout < < common < < endl < < general < < endl ;
exit ( 0 ) ;
}
if ( args - > log_level > 4 ) {
args - > log_level = 4 ;
printf ( " Set log level to %d (%s) \n " , args - > log_level , srslte : : log_level_text [ args - > log_level ] ) ;
}
}
class mac_reader
: public thread
{
public :
mac_reader ( rlc_interface_mac * rlc1_ , rlc_interface_mac * rlc2_ , float fail_rate_ , float opp_sdu_ratio_ , uint32_t pdu_tx_delay_usec_ , rlc_pcap * pcap_ , uint32_t lcid_ , bool is_dl_ = true )
{
rlc1 = rlc1_ ;
rlc2 = rlc2_ ;
fail_rate = fail_rate_ ;
opp_sdu_ratio = opp_sdu_ratio_ ;
run_enable = true ;
running = false ;
pdu_tx_delay_usec = pdu_tx_delay_usec_ ;
pcap = pcap_ ;
is_dl = is_dl_ ;
lcid = lcid_ ;
}
void stop ( )
{
run_enable = false ;
int cnt = 0 ;
while ( running & & cnt < 100 ) {
usleep ( 10000 ) ;
cnt + + ;
}
if ( running ) {
thread_cancel ( ) ;
}
wait_thread_finish ( ) ;
}
private :
void run_thread ( )
{
running = true ;
byte_buffer_t * pdu = byte_buffer_pool : : get_instance ( ) - > allocate ( " mac_reader::run_thread " ) ;
if ( ! pdu ) {
printf ( " Fatal Error: Could not allocate PDU in mac_reader::run_thread \n " ) ;
exit ( - 1 ) ;
}
while ( run_enable ) {
// generate MAC opportunities of random size or with fixed ratio
float r = opp_sdu_ratio ? opp_sdu_ratio : ( float ) rand ( ) / RAND_MAX ;
int opp_size = r * SDU_SIZE ;
uint32_t buf_state = rlc1 - > get_buffer_state ( lcid ) ;
if ( buf_state ) {
int read = rlc1 - > read_pdu ( lcid , pdu - > msg , opp_size ) ;
if ( pdu_tx_delay_usec ) usleep ( pdu_tx_delay_usec ) ;
if ( ( ( float ) rand ( ) / RAND_MAX > fail_rate ) & & read > 0 ) {
pdu - > N_bytes = read ;
rlc2 - > write_pdu ( lcid , pdu - > msg , pdu - > N_bytes ) ;
if ( is_dl ) {
pcap - > write_dl_am_ccch ( pdu - > msg , pdu - > N_bytes ) ;
} else {
pcap - > write_ul_am_ccch ( pdu - > msg , pdu - > N_bytes ) ;
}
}
}
}
running = false ;
byte_buffer_pool : : get_instance ( ) - > deallocate ( pdu ) ;
}
rlc_interface_mac * rlc1 ;
rlc_interface_mac * rlc2 ;
float fail_rate ;
float opp_sdu_ratio ;
uint32_t pdu_tx_delay_usec ;
rlc_pcap * pcap ;
uint32_t lcid ;
bool is_dl ;
bool run_enable ;
bool running ;
} ;
class mac_dummy
: public srslte : : mac_interface_timers
{
public :
mac_dummy ( rlc_interface_mac * rlc1_ , rlc_interface_mac * rlc2_ , float fail_rate_ , float opp_sdu_ratio_ , int32_t pdu_tx_delay , uint32_t lcid , rlc_pcap * pcap = NULL )
: r1 ( rlc1_ , rlc2_ , fail_rate_ , opp_sdu_ratio_ , pdu_tx_delay , pcap , lcid , true )
, r2 ( rlc2_ , rlc1_ , fail_rate_ , opp_sdu_ratio_ , pdu_tx_delay , pcap , lcid , false )
{
}
void start ( )
{
r1 . start ( 7 ) ;
r2 . start ( 7 ) ;
}
void stop ( )
{
r1 . stop ( ) ;
r2 . stop ( ) ;
}
srslte : : timers : : timer * timer_get ( uint32_t timer_id )
{
return & t ;
}
uint32_t timer_get_unique_id ( ) { return 0 ; }
void timer_release_id ( uint32_t id ) { }
private :
srslte : : timers : : timer t ;
mac_reader r1 ;
mac_reader r2 ;
} ;
class rlc_tester
: public pdcp_interface_rlc
, public rrc_interface_rlc
, public thread
{
public :
rlc_tester ( rlc_interface_pdcp * rlc_ , std : : string name_ , uint32_t sdu_gen_delay_usec_ , uint32_t lcid_ ) {
rlc = rlc_ ;
run_enable = true ;
running = false ;
rx_pdus = 0 ;
name = name_ ;
sdu_gen_delay_usec = sdu_gen_delay_usec_ ;
lcid = lcid_ ;
}
void stop ( )
{
run_enable = false ;
int cnt = 0 ;
while ( running & & cnt < 100 ) {
usleep ( 10000 ) ;
cnt + + ;
}
if ( running ) {
thread_cancel ( ) ;
}
wait_thread_finish ( ) ;
}
// PDCP interface
void write_pdu ( uint32_t rx_lcid , byte_buffer_t * sdu )
{
assert ( rx_lcid = = lcid ) ;
if ( sdu - > N_bytes ! = SDU_SIZE ) {
printf ( " Received PDU with size %d, expected %d. Exiting. \n " , sdu - > N_bytes , SDU_SIZE ) ;
exit ( - 1 ) ;
}
byte_buffer_pool : : get_instance ( ) - > deallocate ( sdu ) ;
rx_pdus + + ;
}
void write_pdu_bcch_bch ( byte_buffer_t * sdu ) { }
void write_pdu_bcch_dlsch ( byte_buffer_t * sdu ) { }
void write_pdu_pcch ( byte_buffer_t * sdu ) { }
// RRC interface
void max_retx_attempted ( ) { }
std : : string get_rb_name ( uint32_t rx_lcid ) { return std : : string ( " " ) ; }
int get_nof_rx_pdus ( ) { return rx_pdus ; }
private :
void run_thread ( )
{
uint8_t sn = 0 ;
running = true ;
while ( run_enable ) {
byte_buffer_t * pdu = byte_buffer_pool : : get_instance ( ) - > allocate ( " rlc_tester::run_thread " ) ;
if ( ! pdu ) {
printf ( " Fatal Error: Could not allocate PDU in rlc_tester::run_thread \n " ) ;
exit ( - 1 ) ;
}
for ( uint32_t i = 0 ; i < SDU_SIZE ; i + + ) {
pdu - > msg [ i ] = sn ;
}
sn + + ;
pdu - > N_bytes = SDU_SIZE ;
rlc - > write_sdu ( lcid , pdu ) ;
if ( sdu_gen_delay_usec ) usleep ( sdu_gen_delay_usec ) ;
}
running = false ;
}
bool run_enable ;
bool running ;
long rx_pdus ;
uint32_t lcid ;
std : : string name ;
uint32_t sdu_gen_delay_usec ;
rlc_interface_pdcp * rlc ;
} ;
void stress_test ( stress_test_args_t args )
{
srslte : : log_filter log1 ( " RLC_1 " ) ;
srslte : : log_filter log2 ( " RLC_2 " ) ;
log1 . set_level ( ( LOG_LEVEL_ENUM ) args . log_level ) ;
log2 . set_level ( ( LOG_LEVEL_ENUM ) args . log_level ) ;
log1 . set_hex_limit ( - 1 ) ;
log2 . set_hex_limit ( - 1 ) ;
rlc_pcap pcap ;
uint32_t lcid = 1 ;
if ( args . write_pcap ) {
pcap . open ( " rlc_stress_test.pcap " , 0 ) ;
}
srslte_rlc_config_t cnfg_ ;
if ( args . mode = = " AM " ) {
// config RLC AM bearer
cnfg_ . rlc_mode = LIBLTE_RRC_RLC_MODE_AM ;
cnfg_ . am . max_retx_thresh = 4 ;
cnfg_ . am . poll_byte = 25 * 1000 ;
cnfg_ . am . poll_pdu = 4 ;
cnfg_ . am . t_poll_retx = 5 ;
cnfg_ . am . t_reordering = 5 ;
cnfg_ . am . t_status_prohibit = 5 ;
} else if ( args . mode = = " UM " ) {
// config UM bearer
cnfg_ . rlc_mode = LIBLTE_RRC_RLC_MODE_UM_BI ;
cnfg_ . um . t_reordering = 5 ;
cnfg_ . um . rx_mod = 32 ;
cnfg_ . um . rx_sn_field_length = RLC_UMD_SN_SIZE_5_BITS ;
cnfg_ . um . rx_window_size = 16 ;
cnfg_ . um . tx_sn_field_length = RLC_UMD_SN_SIZE_5_BITS ;
cnfg_ . um . tx_mod = 32 ;
} else if ( args . mode = = " TM " ) {
// use default LCID in TM
lcid = 0 ;
} else {
cout < < " Unsupported RLC mode " < < args . mode < < " , exiting. " < < endl ;
exit ( - 1 ) ;
}
rlc rlc1 ;
rlc rlc2 ;
rlc_tester tester1 ( & rlc1 , " tester1 " , args . sdu_gen_delay_usec , lcid ) ;
rlc_tester tester2 ( & rlc2 , " tester2 " , args . sdu_gen_delay_usec , lcid ) ;
mac_dummy mac ( & rlc1 , & rlc2 , args . error_rate , args . opp_sdu_ratio , args . pdu_tx_delay_usec , lcid , & pcap ) ;
ue_interface ue ;
rlc1 . init ( & tester1 , & tester1 , & ue , & log1 , & mac , 0 ) ;
rlc2 . init ( & tester2 , & tester2 , & ue , & log2 , & mac , 0 ) ;
// only add AM and UM bearers
if ( args . mode ! = " TM " ) {
rlc1 . add_bearer ( lcid , cnfg_ ) ;
rlc2 . add_bearer ( lcid , cnfg_ ) ;
}
tester1 . start ( 7 ) ;
if ( ! args . single_tx ) {
tester2 . start ( 7 ) ;
}
mac . start ( ) ;
for ( uint32_t i = 0 ; i < args . test_duration_sec ; i + + ) {
// if enabled, mimic reestablishment every second
if ( args . reestablish ) {
rlc1 . reestablish ( ) ;
rlc2 . reestablish ( ) ;
}
usleep ( 1e6 ) ;
}
tester1 . stop ( ) ;
tester2 . stop ( ) ;
mac . stop ( ) ;
if ( args . write_pcap ) {
pcap . close ( ) ;
}
printf ( " RLC1 received %d SDUs in %ds (%.2f PDU/s) \n " ,
tester1 . get_nof_rx_pdus ( ) ,
args . test_duration_sec ,
( float ) tester1 . get_nof_rx_pdus ( ) / args . test_duration_sec ) ;
printf ( " RLC2 received %d SDUs in %ds (%.2f PDU/s) \n " ,
tester2 . get_nof_rx_pdus ( ) ,
args . test_duration_sec ,
( float ) tester2 . get_nof_rx_pdus ( ) / args . test_duration_sec ) ;
}
int main ( int argc , char * * argv ) {
stress_test_args_t args ;
parse_args ( & args , argc , argv ) ;
stress_test ( args ) ;
byte_buffer_pool : : get_instance ( ) - > cleanup ( ) ;
exit ( 0 ) ;
}