/*
* Licensed to the OpenAirInterface (OAI) Software Alliance under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The OpenAirInterface Software Alliance licenses this file to You under
* the OAI Public License, Version 1.1 (the "License"); you may not use this file
* except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.openairinterface.org/?page_id=698
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*-------------------------------------------------------------------------------
* For more information about the OpenAirInterface (OAI) Software Alliance:
* contact@openairinterface.org
*/
/*! \file rfsim.c
* \brief function for simulated RF device
* \author R. Knopp
* \date 2018
* \version 1.0
* \company Eurecom
* \email: openair_tech@eurecom.fr
* \note
* \warning
*/
#include <stdlib.h>
#include <unistd.h>
#include <stdio.h>
#include <signal.h>
#include <execinfo.h>
#include <time.h>
#include <mcheck.h>
#include <sys/timerfd.h>
#include "assertions.h"
#include "rfsim.h"
#include "openair1/SIMULATION/TOOLS/sim.h"
#include "enb_config.h"
#include "enb_paramdef.h"
#include "common/platform_constants.h"
#include "common/config/config_paramdesc.h"
#include "common/config/config_userapi.h"
#include "common/ran_context.h"
#include "PHY/defs_UE.h"
#include "PHY/defs_eNB.h"
#include "PHY/defs_RU.h"
#include "common/utils/LOG/vcd_signal_dumper.h"
RAN_CONTEXT_t RC;
extern PHY_VARS_UE ***PHY_vars_UE_g;
// put all of these in a common structure after
sim_t sim;
void init_ru_devices(void);
void init_RU(char *,int send_dmrssync);
void *rfsim_top(void *n_frames);
void wait_RUs(void) {
int i;
// wait for all RUs to be configured over fronthaul
pthread_mutex_lock(&RC.ru_mutex);
while (RC.ru_mask>0) {
pthread_cond_wait(&RC.ru_cond,&RC.ru_mutex);
}
pthread_mutex_unlock(&RC.ru_mutex);
// copy frame parameters from RU to UEs
for (i=0; i<NB_UE_INST; i++) {
sim.current_UE_rx_timestamp[i][0] = RC.ru[0]->frame_parms->samples_per_tti + RC.ru[0]->frame_parms->ofdm_symbol_size + RC.ru[0]->frame_parms->nb_prefix_samples0;
}
for (int ru_id=0; ru_id<RC.nb_RU; ru_id++) sim.current_ru_rx_timestamp[ru_id][0] = RC.ru[ru_id]->frame_parms->samples_per_tti;
printf("RUs are ready, let's go\n");
}
void wait_eNBs(void) {
return;
}
void RCConfig_sim(void) {
paramlist_def_t RUParamList = {CONFIG_STRING_RU_LIST,NULL,0};
// Get num RU instances
config_getlist( &RUParamList,NULL,0, NULL);
RC.nb_RU = RUParamList.numelt;
AssertFatal(RC.nb_RU>0,"we need at least 1 RU for simulation\n");
printf("returned with %d rus\n",RC.nb_RU);
init_RU(NULL,0);
printf("Waiting for RUs to get set up\n");
wait_RUs();
init_ru_devices();
static int nframes = 100000;
AssertFatal(0 == pthread_create(&sim.rfsim_thread,
NULL,
rfsim_top,
(void *)&nframes), "");
}
int ru_trx_start(openair0_device *device) {
return(0);
}
void ru_trx_end(openair0_device *device) {
return;
}
int ru_trx_stop(openair0_device *device) {
return(0);
}
int UE_trx_start(openair0_device *device) {
return(0);
}
void UE_trx_end(openair0_device *device) {
return;
}
int UE_trx_stop(openair0_device *device) {
return(0);
}
int ru_trx_set_freq(openair0_device *device, openair0_config_t *openair0_cfg, int dummy) {
return(0);
}
int ru_trx_set_gains(openair0_device *device, openair0_config_t *openair0_cfg) {
return(0);
}
int UE_trx_set_freq(openair0_device *device, openair0_config_t *openair0_cfg, int dummy) {
return(0);
}
int UE_trx_set_gains(openair0_device *device, openair0_config_t *openair0_cfg) {
return(0);
}
extern pthread_mutex_t subframe_mutex;
extern int subframe_ru_mask,subframe_UE_mask;
int ru_trx_read(openair0_device *device, openair0_timestamp *ptimestamp, void **buff, int nsamps, int cc) {
int ru_id = device->Mod_id;
int CC_id = device->CC_id;
int subframe;
int sample_count=0;
*ptimestamp = sim.last_ru_rx_timestamp[ru_id][CC_id];
LOG_D(SIM,"RU_trx_read nsamps %d TS(%llu,%llu) => subframe %d\n",nsamps,
(unsigned long long)sim.current_ru_rx_timestamp[ru_id][CC_id],
(unsigned long long)sim.last_ru_rx_timestamp[ru_id][CC_id],
(int)((*ptimestamp/RC.ru[ru_id]->frame_parms->samples_per_tti)%10));
// if we're at a subframe boundary generate UL signals for this ru
while (sample_count<nsamps) {
while (sim.current_ru_rx_timestamp[ru_id][CC_id]<
(nsamps+sim.last_ru_rx_timestamp[ru_id][CC_id])) {
LOG_D(SIM,"RU: current TS %"PRIi64", last TS %"PRIi64", sleeping\n",sim.current_ru_rx_timestamp[ru_id][CC_id],sim.last_ru_rx_timestamp[ru_id][CC_id]);
usleep(500);
}
subframe = (sim.last_ru_rx_timestamp[ru_id][CC_id]/RC.ru[ru_id]->frame_parms->samples_per_tti)%10;
if (subframe_select(RC.ru[ru_id]->frame_parms,subframe) != SF_DL || RC.ru[ru_id]->frame_parms->frame_type == FDD) {
LOG_D(SIM,"RU_trx_read generating UL subframe %d (Ts %llu, current TS %llu)\n",
subframe,(unsigned long long)*ptimestamp,
(unsigned long long)sim.current_ru_rx_timestamp[ru_id][CC_id]);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_SIM_DO_UL_SIGNAL,1);
do_UL_sig(&sim,
subframe,
0, // abstraction_flag
RC.ru[ru_id]->frame_parms,
0, // frame is only used for abstraction
ru_id,
CC_id,
1);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_SIM_DO_UL_SIGNAL,0);
}
sim.last_ru_rx_timestamp[ru_id][CC_id] += RC.ru[ru_id]->frame_parms->samples_per_tti;
sample_count += RC.ru[ru_id]->frame_parms->samples_per_tti;
}
return(nsamps);
}
int UE_trx_read(openair0_device *device, openair0_timestamp *ptimestamp, void **buff, int nsamps, int cc) {
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_SIM_UE_TRX_READ,1);
int UE_id = device->Mod_id;
int CC_id = device->CC_id;
int subframe;
int sample_count=0;
int read_size;
int sptti = PHY_vars_UE_g[UE_id][CC_id]->frame_parms.samples_per_tti;
*ptimestamp = sim.last_UE_rx_timestamp[UE_id][CC_id];
LOG_D(PHY,"UE %d DL simulation 0: UE_trx_read nsamps %d TS %llu (%llu, offset %d) antenna %d\n",
UE_id,
nsamps,
(unsigned long long)sim.current_UE_rx_timestamp[UE_id][CC_id],
(unsigned long long)sim.last_UE_rx_timestamp[UE_id][CC_id],
(int)(sim.last_UE_rx_timestamp[UE_id][CC_id]%sptti),
cc);
if (nsamps < sptti)
read_size = nsamps;
else
read_size = sptti;
while (sample_count<nsamps) {
LOG_D(SIM,"UE %d: DL simulation 1: UE_trx_read : current TS now %"PRIi64", last TS %"PRIi64"\n",UE_id,sim.current_UE_rx_timestamp[UE_id][CC_id],sim.last_UE_rx_timestamp[UE_id][CC_id]);
while (sim.current_UE_rx_timestamp[UE_id][CC_id] <
(sim.last_UE_rx_timestamp[UE_id][CC_id]+read_size)) {
LOG_D(SIM,"UE %d: DL simulation 2: UE_trx_read : current TS %"PRIi64", last TS %"PRIi64", sleeping\n",UE_id,sim.current_UE_rx_timestamp[UE_id][CC_id],sim.last_UE_rx_timestamp[UE_id][CC_id]);
usleep(500);
}
LOG_D(SIM,"UE %d: DL simulation 3: UE_trx_read : current TS now %"PRIi64", last TS %"PRIi64"\n",UE_id,sim.current_UE_rx_timestamp[UE_id][CC_id],sim.last_UE_rx_timestamp[UE_id][CC_id]);
// if we cross a subframe-boundary
subframe = (sim.last_UE_rx_timestamp[UE_id][CC_id]/sptti)%10;
// tell top-level we are busy
pthread_mutex_lock(&sim.subframe_mutex);
sim.subframe_UE_mask|=(1<<UE_id);
LOG_D(SIM,"Setting UE_id %d mask to busy (%d)\n",UE_id,sim.subframe_UE_mask);
pthread_mutex_unlock(&sim.subframe_mutex);
LOG_D(PHY,"UE %d: DL simulation 4: UE_trx_read generating DL subframe %d (Ts %llu, current TS %llu,nsamps %d)\n",
UE_id,subframe,(unsigned long long)*ptimestamp,
(unsigned long long)sim.current_UE_rx_timestamp[UE_id][CC_id],
nsamps);
LOG_D(SIM,"UE %d: DL simulation 5: Doing DL simulation for %d samples starting in subframe %d at offset %d\n",
UE_id,nsamps,subframe,
(int)(sim.last_UE_rx_timestamp[UE_id][CC_id]%sptti));
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_SIM_DO_DL_SIGNAL,1);
do_DL_sig(&sim,
subframe,
sim.last_UE_rx_timestamp[UE_id][CC_id]%sptti,
sptti,
0, //abstraction_flag,
&PHY_vars_UE_g[UE_id][CC_id]->frame_parms,
UE_id,
CC_id);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_SIM_DO_DL_SIGNAL,0);
LOG_D(PHY,"UE %d: DL simulation 6: UE_trx_read @ TS %"PRIi64" (%"PRIi64")=> frame %d, subframe %d\n",
UE_id, sim.current_UE_rx_timestamp[UE_id][CC_id],
sim.last_UE_rx_timestamp[UE_id][CC_id],
(int)((sim.last_UE_rx_timestamp[UE_id][CC_id]/(sptti*10))&1023),
subframe);
sim.last_UE_rx_timestamp[UE_id][CC_id] += read_size;
sample_count += read_size;
}
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_SIM_UE_TRX_READ,0);
return(nsamps);
}
int ru_trx_write(openair0_device *device,openair0_timestamp timestamp, void **buff, int nsamps, int cc, int flags) {
int ru_id = device->Mod_id;
LTE_DL_FRAME_PARMS *frame_parms = RC.ru[ru_id]->frame_parms;
pthread_mutex_lock(&sim.subframe_mutex);
LOG_D(SIM,"[TXPATH] ru_trx_write: RU %d mask %d\n",ru_id,sim.subframe_ru_mask);
pthread_mutex_unlock(&sim.subframe_mutex);
// compute amplitude of TX signal from first symbol in subframe
// note: assumes that the packet is an entire subframe
sim.ru_amp[ru_id] = 0;
for (int aa=0; aa<RC.ru[ru_id]->nb_tx; aa++) {
sim.ru_amp[ru_id] += (double)signal_energy((int32_t *)buff[aa],frame_parms->ofdm_symbol_size)/(12*frame_parms->N_RB_DL);
}
sim.ru_amp[ru_id] = sqrt(sim.ru_amp[ru_id]);
LOG_D(PHY,"Setting amp for RU %d to %f (%d)\n",ru_id,sim.ru_amp[ru_id], dB_fixed((double)signal_energy((int32_t *)buff[0],frame_parms->ofdm_symbol_size)));
// tell top-level we are done
pthread_mutex_lock(&sim.subframe_mutex);
sim.subframe_ru_mask|=(1<<ru_id);
LOG_D(SIM,"Setting RU %d to busy\n",ru_id);
pthread_mutex_unlock(&sim.subframe_mutex);
return(nsamps);
}
int UE_trx_write(openair0_device *device,openair0_timestamp timestamp, void **buff, int nsamps, int cc, int flags) {
return(nsamps);
}
void init_ru_devices() {
module_id_t ru_id;
RU_t *ru;
// allocate memory for RU if not already done
if (RC.ru==NULL) RC.ru = (RU_t **)malloc(RC.nb_RU*sizeof(RU_t *));
for (ru_id=0; ru_id<RC.nb_RU; ru_id++) {
LOG_D(SIM,"Initiaizing rfdevice for RU %d\n",ru_id);
if (RC.ru[ru_id]==NULL) RC.ru[ru_id] = (RU_t *)malloc(sizeof(RU_t));
ru = RC.ru[ru_id];
ru->rfdevice.Mod_id = ru_id;
ru->rfdevice.CC_id = 0;
ru->rfdevice.trx_start_func = ru_trx_start;
ru->rfdevice.trx_read_func = ru_trx_read;
ru->rfdevice.trx_write_func = ru_trx_write;
ru->rfdevice.trx_end_func = ru_trx_end;
ru->rfdevice.trx_stop_func = ru_trx_stop;
ru->rfdevice.trx_set_freq_func = ru_trx_set_freq;
ru->rfdevice.trx_set_gains_func = ru_trx_set_gains;
sim.last_ru_rx_timestamp[ru_id][0] = 0;
}
}
void init_ue_devices(PHY_VARS_UE *UE) {
AssertFatal(UE!=NULL,"UE context is not allocated\n");
printf("Initializing UE %d.%d\n",UE->Mod_id,UE->CC_id);
UE->rfdevice.Mod_id = UE->Mod_id;
UE->rfdevice.CC_id = UE->CC_id;
UE->rfdevice.trx_start_func = UE_trx_start;
UE->rfdevice.trx_read_func = UE_trx_read;
UE->rfdevice.trx_write_func = UE_trx_write;
UE->rfdevice.trx_end_func = UE_trx_end;
UE->rfdevice.trx_stop_func = UE_trx_stop;
UE->rfdevice.trx_set_freq_func = UE_trx_set_freq;
UE->rfdevice.trx_set_gains_func = UE_trx_set_gains;
sim.last_UE_rx_timestamp[UE->Mod_id][UE->CC_id] = 0;
}
void init_ocm(void) {
module_id_t UE_id, ru_id;
int CC_id;
double DS_TDL = .03;
randominit(0);
set_taus_seed(0);
init_channelmod();
double snr_dB = channelmod_get_snr_dB();
double sinr_dB = channelmod_get_sinr_dB();
init_channel_vars ();//fp, &s_re, &s_im, &r_re, &r_im, &r_re0, &r_im0);
// initialize channel descriptors
LOG_I(PHY,"Initializing channel descriptors (nb_RU %d, nb_UE %d)\n",RC.nb_RU,NB_UE_INST);
for (ru_id = 0; ru_id < RC.nb_RU; ru_id++) {
for (UE_id = 0; UE_id < NB_UE_INST; UE_id++) {
for (CC_id=0; CC_id<MAX_NUM_CCs; CC_id++) {
LOG_I(PHY,"Initializing channel descriptors (RU %d, UE %d) for N_RB_DL %d\n",ru_id,UE_id,
RC.ru[ru_id]->frame_parms->N_RB_DL);
sim.RU2UE[ru_id][UE_id][CC_id] =
new_channel_desc_scm(RC.ru[ru_id]->nb_tx,
PHY_vars_UE_g[UE_id][CC_id]->frame_parms.nb_antennas_rx,
AWGN,
N_RB2sampling_rate(RC.ru[ru_id]->frame_parms->N_RB_DL),
N_RB2channel_bandwidth(RC.ru[ru_id]->frame_parms->N_RB_DL),
DS_TDL,
CORR_LEVEL_LOW,
0.0,
0,
0,
0);
random_channel(sim.RU2UE[ru_id][UE_id][CC_id],0);
LOG_D(OCM,"[SIM] Initializing channel (%s) from UE %d to ru %d\n", "AWGN", UE_id, ru_id);
sim.UE2RU[UE_id][ru_id][CC_id] =
new_channel_desc_scm(PHY_vars_UE_g[UE_id][CC_id]->frame_parms.nb_antennas_tx,
RC.ru[ru_id]->nb_rx,
AWGN,
N_RB2sampling_rate(RC.ru[ru_id]->frame_parms->N_RB_UL),
N_RB2channel_bandwidth(RC.ru[ru_id]->frame_parms->N_RB_UL),
DS_TDL,
CORR_LEVEL_LOW,
0.0,
0,
0,
0);
random_channel(sim.UE2RU[UE_id][ru_id][CC_id],0);
// to make channel reciprocal uncomment following line instead of previous. However this only works for SISO at the moment. For MIMO the channel would need to be transposed.
//UE2RU[UE_id][ru_id] = RU2UE[ru_id][UE_id];
AssertFatal(sim.RU2UE[ru_id][UE_id][CC_id]!=NULL,"RU2UE[%d][%d][%d] is null\n",ru_id,UE_id,CC_id);
AssertFatal(sim.UE2RU[UE_id][ru_id][CC_id]!=NULL,"UE2RU[%d][%d][%d] is null\n",UE_id,ru_id,CC_id);
//pathloss: -132.24 dBm/15kHz RE + target SNR - eNB TX power per RE
if (ru_id == (UE_id % RC.nb_RU)) {
sim.RU2UE[ru_id][UE_id][CC_id]->path_loss_dB = -132.24 + snr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
sim.UE2RU[UE_id][ru_id][CC_id]->path_loss_dB = -132.24 + snr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
} else {
sim.RU2UE[ru_id][UE_id][CC_id]->path_loss_dB = -132.24 + sinr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
sim.UE2RU[UE_id][ru_id][CC_id]->path_loss_dB = -132.24 + sinr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
}
LOG_I(OCM,"Path loss from eNB %d to UE %d (CCid %d)=> %f dB (eNB TX %d, SNR %f)\n",ru_id,UE_id,CC_id,
sim.RU2UE[ru_id][UE_id][CC_id]->path_loss_dB,
RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower,
snr_dB);
}
}
}
}
void update_ocm(double snr_dB,double sinr_dB) {
module_id_t UE_id, ru_id;
int CC_id;
for (ru_id = 0; ru_id < RC.nb_RU; ru_id++) {
for (UE_id = 0; UE_id < NB_UE_INST; UE_id++) {
for (CC_id=0; CC_id<MAX_NUM_CCs; CC_id++) {
AssertFatal(sim.RU2UE[ru_id][UE_id][CC_id]!=NULL,"RU2UE[%d][%d][%d] is null\n",ru_id,UE_id,CC_id);
AssertFatal(sim.UE2RU[UE_id][ru_id][CC_id]!=NULL,"UE2RU[%d][%d][%d] is null\n",UE_id,ru_id,CC_id);
//pathloss: -132.24 dBm/15kHz RE + target SNR - eNB TX power per RE
if (ru_id == (UE_id % RC.nb_RU)) {
sim.RU2UE[ru_id][UE_id][CC_id]->path_loss_dB = -132.24 + snr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
sim.UE2RU[UE_id][ru_id][CC_id]->path_loss_dB = -132.24 + snr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
} else {
sim.RU2UE[ru_id][UE_id][CC_id]->path_loss_dB = -132.24 + sinr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
sim.UE2RU[UE_id][ru_id][CC_id]->path_loss_dB = -132.24 + sinr_dB - RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower;
}
LOG_D(OCM,"Path loss from eNB %d to UE %d (CCid %d)=> %f dB (eNB TX %d, SNR %f)\n",ru_id,UE_id,CC_id,
sim.RU2UE[ru_id][UE_id][CC_id]->path_loss_dB,
RC.ru[ru_id]->frame_parms->pdsch_config_common.referenceSignalPower,
snr_dB);
}
}
}
}
void init_channel_vars(void) {
int i;
memset(sim.RU_output_mask,0,sizeof(int)*NUMBER_OF_UE_MAX);
for (i=0; i<NB_UE_INST; i++)
pthread_mutex_init(&sim.RU_output_mutex[i],NULL);
memset(sim.UE_output_mask,0,sizeof(int)*NUMBER_OF_RU_MAX);
for (i=0; i<RC.nb_RU; i++)
pthread_mutex_init(&sim.UE_output_mutex[i],NULL);
}
void *rfsim_top(void *n_frames) {
wait_sync("rfsim_top");
printf("Running rfsim with %d frames\n",*(int *)n_frames);
for (int frame = 0; frame < *(int *)n_frames; frame++) {
for (int sf = 0; sf < 10; sf++) {
int CC_id=0;
int all_done=0;
while (all_done==0) {
pthread_mutex_lock(&sim.subframe_mutex);
int subframe_ru_mask_local = (subframe_select(RC.ru[0]->frame_parms,(sf+4)%10)!=SF_UL) ? sim.subframe_ru_mask : ((1<<RC.nb_RU)-1);
int subframe_UE_mask_local = (RC.ru[0]->frame_parms->frame_type == FDD || subframe_select(RC.ru[0]->frame_parms,(sf+4)%10)!=SF_DL) ? sim.subframe_UE_mask : ((1<<NB_UE_INST)-1);
pthread_mutex_unlock(&sim.subframe_mutex);
LOG_D(SIM,"Frame %d, Subframe %d, NB_RU %d, NB_UE %d: Checking masks %x,%x\n",frame,sf,RC.nb_RU,NB_UE_INST,subframe_ru_mask_local,subframe_UE_mask_local);
if ((subframe_ru_mask_local == ((1<<RC.nb_RU)-1)) &&
(subframe_UE_mask_local == ((1<<NB_UE_INST)-1))) all_done=1;
else usleep(1500);
}
//clear subframe masks for next round
pthread_mutex_lock(&sim.subframe_mutex);
sim.subframe_ru_mask=0;
sim.subframe_UE_mask=0;
pthread_mutex_unlock(&sim.subframe_mutex);
// increment timestamps
for (int ru_id=0; ru_id<RC.nb_RU; ru_id++) {
sim.current_ru_rx_timestamp[ru_id][CC_id] += RC.ru[ru_id]->frame_parms->samples_per_tti;
LOG_D(SIM,"RU %d/%d: TS %"PRIi64"\n",ru_id,CC_id,sim.current_ru_rx_timestamp[ru_id][CC_id]);
}
for (int UE_inst = 0; UE_inst<NB_UE_INST; UE_inst++) {
sim.current_UE_rx_timestamp[UE_inst][CC_id] += PHY_vars_UE_g[UE_inst][CC_id]->frame_parms.samples_per_tti;
LOG_D(SIM,"UE %d/%d: TS %"PRIi64"\n",UE_inst,CC_id,sim.current_UE_rx_timestamp[UE_inst][CC_id]);
}
if (oai_exit == 1) return((void *)NULL);
}
}
return((void *)NULL);
}