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Commit af489a78 authored by Raymond Knopp's avatar Raymond Knopp
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addition of asynchronous RX threads and inter CC synchronization

parent 10ba1c00
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Showing with 407 additions and 305 deletions
openair1/PHY/defs.h
View file @ af489a78
...@@ -165,6 +165,12 @@ typedef enum { ...@@ -165,6 +165,12 @@ typedef enum {
NGFI_RCC_IF4 // NGFI_RCC (NGFI radio cloud center, currently split at common - ue_specific interface, IF4) NGFI_RCC_IF4 // NGFI_RCC (NGFI radio cloud center, currently split at common - ue_specific interface, IF4)
} eNB_func_t; } eNB_func_t;
typedef enum {
synch_to_ext_device=0, // synch to RF or Ethernet device
synch_to_other // synch to another source (timer, other CC_id)
} eNB_timing_t;
typedef struct UE_SCAN_INFO_s { typedef struct UE_SCAN_INFO_s {
/// 10 best amplitudes (linear) for each pss signals /// 10 best amplitudes (linear) for each pss signals
int32_t amp[3][10]; int32_t amp[3][10];
...@@ -211,7 +217,7 @@ typedef struct { ...@@ -211,7 +217,7 @@ typedef struct {
struct sched_param sched_param_rxtx; struct sched_param sched_param_rxtx;
} eNB_rxtx_proc_t; } eNB_rxtx_proc_t;
/// Context data structure for eNB subframe processing /// Context data structure for eNB subframe processing
typedef struct { typedef struct eNB_proc_t_s {
/// Component Carrier index /// Component Carrier index
uint8_t CC_id; uint8_t CC_id;
/// thread index /// thread index
...@@ -226,29 +232,46 @@ typedef struct { ...@@ -226,29 +232,46 @@ typedef struct {
int frame_rx; int frame_rx;
/// frame to act upon for PRACH /// frame to act upon for PRACH
int frame_prach; int frame_prach;
/// \brief Instance count for FH processing thread.
/// \internal This variable is protected by \ref mutex_FH.
int instance_cnt_FH;
/// \brief Instance count for rx processing thread. /// \brief Instance count for rx processing thread.
/// \internal This variable is protected by \ref mutex_prach. /// \internal This variable is protected by \ref mutex_prach.
int instance_cnt_prach; int instance_cnt_prach;
/// pthread structure for rx processing thread /// pthread structure for FH processing thread
pthread_t pthread_rx; pthread_t pthread_FH;
/// pthread structure for asychronous RX processing thread
pthread_t pthread_asynch_rx;
/// flag to indicate first RX acquisition /// flag to indicate first RX acquisition
int first_rx; int first_rx;
/// pthread attributes for rx processing thread /// pthread attributes for FH processing thread
pthread_attr_t attr_rx; pthread_attr_t attr_FH;
/// pthread attributes for prach processing thread /// pthread attributes for prach processing thread
pthread_attr_t attr_prach; pthread_attr_t attr_prach;
/// scheduling parameters for rx thread /// pthread attributes for asynchronous RX thread
struct sched_param sched_param_rx; pthread_attr_t attr_asynch_rx;
/// scheduling parameters for FH thread
struct sched_param sched_param_FH;
/// scheduling parameters for prach thread /// scheduling parameters for prach thread
struct sched_param sched_param_prach; struct sched_param sched_param_prach;
/// condition variable for prach processing thread /// scheduling parameters for asynch_rx thread
struct sched_param sched_param_asynch_rx;
/// condition variable for FH thread
pthread_t pthread_prach; pthread_t pthread_prach;
/// condition variable for rx processing thread; /// condition variable for FH thread
pthread_cond_t cond_FH;
/// condition variable for PRACH processing thread;
pthread_cond_t cond_prach; pthread_cond_t cond_prach;
/// mutex for tx processing thread /// mutex for FH
pthread_mutex_t mutex_FH;
/// mutex for PRACH thread
pthread_mutex_t mutex_prach; pthread_mutex_t mutex_prach;
/// set of scheduling variables RXn-TXnp4 threads /// set of scheduling variables RXn-TXnp4 threads
eNB_rxtx_proc_t proc_rxtx[2]; eNB_rxtx_proc_t proc_rxtx[2];
/// number of slave threads
int num_slaves;
/// array of pointers to slaves
struct eNB_proc_t_s **slave_proc;
} eNB_proc_t; } eNB_proc_t;
...@@ -311,6 +334,7 @@ typedef struct PHY_VARS_eNB_s { ...@@ -311,6 +334,7 @@ typedef struct PHY_VARS_eNB_s {
uint8_t CC_id; uint8_t CC_id;
eNB_proc_t proc; eNB_proc_t proc;
eNB_func_t node_function; eNB_func_t node_function;
eNB_timing_t node_timing;
uint8_t local_flag; uint8_t local_flag;
uint32_t rx_total_gain_dB; uint32_t rx_total_gain_dB;
LTE_DL_FRAME_PARMS frame_parms; LTE_DL_FRAME_PARMS frame_parms;
...@@ -456,11 +480,6 @@ typedef struct PHY_VARS_eNB_s { ...@@ -456,11 +480,6 @@ typedef struct PHY_VARS_eNB_s {
time_stats_t phy_proc; time_stats_t phy_proc;
time_stats_t phy_proc_tx; time_stats_t phy_proc_tx;
time_stats_t phy_proc_rx; time_stats_t phy_proc_rx;
/*
time_stats_t phy_proc_sf[10]; // for each subframe
time_stats_t phy_proc_tx_sf[10];
time_stats_t phy_proc_rx_sf[10];
*/
time_stats_t rx_prach; time_stats_t rx_prach;
time_stats_t ofdm_mod_stats; time_stats_t ofdm_mod_stats;
...@@ -505,11 +524,6 @@ typedef struct PHY_VARS_eNB_s { ...@@ -505,11 +524,6 @@ typedef struct PHY_VARS_eNB_s {
int32_t pusch_stats_mcs[NUMBER_OF_UE_MAX][10240]; int32_t pusch_stats_mcs[NUMBER_OF_UE_MAX][10240];
int32_t pusch_stats_bsr[NUMBER_OF_UE_MAX][10240]; int32_t pusch_stats_bsr[NUMBER_OF_UE_MAX][10240];
int32_t pusch_stats_BO[NUMBER_OF_UE_MAX][10240]; int32_t pusch_stats_BO[NUMBER_OF_UE_MAX][10240];
#if ENABLE_RAL
hash_table_t *ral_thresholds_timed;
SLIST_HEAD(ral_thresholds_gen_poll_enb_s, ral_threshold_phy_t) ral_thresholds_gen_polled[RAL_LINK_PARAM_GEN_MAX];
SLIST_HEAD(ral_thresholds_lte_poll_enb_s, ral_threshold_phy_t) ral_thresholds_lte_polled[RAL_LINK_PARAM_LTE_MAX];
#endif
/// RF and Interface devices per CC /// RF and Interface devices per CC
openair0_device rfdevice; openair0_device rfdevice;
...@@ -520,13 +534,6 @@ typedef struct PHY_VARS_eNB_s { ...@@ -520,13 +534,6 @@ typedef struct PHY_VARS_eNB_s {
} PHY_VARS_eNB; } PHY_VARS_eNB;
#define debug_msg if (((mac_xface->frame%100) == 0) || (mac_xface->frame < 50)) msg #define debug_msg if (((mac_xface->frame%100) == 0) || (mac_xface->frame < 50)) msg
//#define debug_msg msg
/*
typedef enum {
max_gain=0,med_gain,byp_gain
} rx_gain_t;
*/
/// Top-level PHY Data Structure for UE /// Top-level PHY Data Structure for UE
typedef struct { typedef struct {
......
openair1/SCHED/phy_procedures_lte_eNb.c
View file @ af489a78
...@@ -2519,29 +2519,17 @@ void phy_procedures_eNB_common_RX(PHY_VARS_eNB *eNB,const uint8_t abstraction_fl ...@@ -2519,29 +2519,17 @@ void phy_procedures_eNB_common_RX(PHY_VARS_eNB *eNB,const uint8_t abstraction_fl
int i,l; int i,l;
LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms; LTE_DL_FRAME_PARMS *fp=&eNB->frame_parms;
void *rxp[fp->nb_antennas_rx];
unsigned int rxs;
eNB_proc_t *proc = &eNB->proc; eNB_proc_t *proc = &eNB->proc;
int subframe = proc->subframe_rx; int subframe = proc->subframe_rx;
int frame = proc->frame_rx; int frame = proc->frame_rx;
int prach_rx;
uint8_t seqno=0; uint8_t seqno=0;
uint16_t packet_type; VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_COMMON, 1 );
uint32_t symbol_number=0;
uint32_t symbol_mask, symbol_mask_full;
if (subframe==9) {
subframe=0;
frame++;
frame&=1023;
} else {
subframe++;
}
// VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_COMMON_RX,1);
start_meas(&eNB->phy_proc_rx); start_meas(&eNB->phy_proc_rx);
#ifdef DEBUG_PHY_PROC #ifdef DEBUG_PHY_PROC
...@@ -2549,77 +2537,11 @@ void phy_procedures_eNB_common_RX(PHY_VARS_eNB *eNB,const uint8_t abstraction_fl ...@@ -2549,77 +2537,11 @@ void phy_procedures_eNB_common_RX(PHY_VARS_eNB *eNB,const uint8_t abstraction_fl
#endif #endif
if (abstraction_flag==0) { // grab signal in chunks of 500 us (1 slot) if (abstraction_flag==0) { // grab signal in chunks of 500 us (1 slot)
if ((eNB->node_function == NGFI_RRU_IF4) ||
(eNB->node_function == NGFI_RRU_IF5) ||
(eNB->node_function == eNodeB_3GPP)) { // acquisition from RF
for (i=0; i<fp->nb_antennas_rx; i++)
rxp[i] = (void*)&eNB->common_vars.rxdata[0][i][subframe*fp->samples_per_tti];
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_TRX_READ, 1 );
rxs = eNB->rfdevice.trx_read_func(&eNB->rfdevice,
&proc->timestamp_rx,
rxp,
fp->samples_per_tti,
fp->nb_antennas_rx);
proc->frame_rx = (proc->timestamp_rx / (fp->samples_per_tti*10))&1023;
proc->subframe_rx = (proc->timestamp_rx / fp->samples_per_tti)%10;
if (proc->first_rx == 0) {
if (proc->subframe_rx != subframe){
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->subframe_rx %d, subframe %d)\n",proc->subframe_rx,subframe);
exit_fun("Exiting");
}
if (proc->frame_rx != frame) {
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->frame_rx %d frame %d)\n",proc->frame_rx,frame);
exit_fun("Exiting");
}
} else {
proc->first_rx = 0;
}
// printf("timestamp_rx %lu, frame %d(%d), subframe %d(%d)\n",proc->timestamp_rx,proc->frame_rx,frame,proc->subframe_rx,subframe);
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_TRX_TS, proc->timestamp_rx&0xffffffff );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_SUBFRAME_NUMBER_RX_ENB, proc->subframe_rx );
if (rxs != fp->samples_per_tti)
exit_fun( "problem receiving samples" );
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_TRX_READ, 0 );
} else if(eNB->node_function == eNodeB_3GPP_BBU) { // acquisition from IF
/// **** recv_IF5 of rxdata from RRH **** ///
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF5, 1 );
recv_IF5(eNB, &proc->timestamp_rx, proc->subframe_rx, IF5_RRH_GW_UL);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF5, 0 );
proc->frame_rx = (proc->timestamp_rx / (fp->samples_per_tti*10))&1023;
proc->subframe_rx = (proc->timestamp_rx / fp->samples_per_tti)%10;
if (proc->first_rx == 0) {
if (proc->subframe_rx != subframe){
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->subframe_rx %d, subframe %d)\n",proc->subframe_rx,subframe);
//exit_fun("Exiting");
}
if (proc->frame_rx != frame) {
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->frame_rx %d frame %d)\n",proc->frame_rx,frame);
//exit_fun("Exiting");
}
} else {
proc->first_rx = 0;
}
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_TRX_TS, proc->timestamp_rx&0xffffffff );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_SUBFRAME_NUMBER_RX_ENB, proc->subframe_rx );
}
if ((eNB->node_function == NGFI_RRU_IF4) || if ((eNB->node_function == NGFI_RRU_IF4) ||
(eNB->node_function == eNodeB_3GPP) || (eNB->node_function == eNodeB_3GPP) ||
(eNB->node_function == eNodeB_3GPP_BBU)) { // front-end processing (eNB->node_function == eNodeB_3GPP_BBU)) { // front-end processing
// now do common RX processing for first slot in subframe // now do common RX processing for first slot in subframe
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_ENB_SLOT_FEP,1); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_ENB_SLOT_FEP,1);
...@@ -2641,131 +2563,61 @@ void phy_procedures_eNB_common_RX(PHY_VARS_eNB *eNB,const uint8_t abstraction_fl ...@@ -2641,131 +2563,61 @@ void phy_procedures_eNB_common_RX(PHY_VARS_eNB *eNB,const uint8_t abstraction_fl
0 0
); );
} }
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_ENB_SLOT_FEP,0);
if (eNB->node_function == NGFI_RRU_IF4 && is_prach_subframe(fp, proc->frame_rx, proc->subframe_rx)<=0) { VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_ENB_SLOT_FEP,0);
if (eNB->node_function == NGFI_RRU_IF4) {
/// **** send_IF4 of rxdataF to RCC (no prach now) **** /// /// **** send_IF4 of rxdataF to RCC (no prach now) **** ///
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF4, 1 ); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF4, 1 );
send_IF4(eNB, frame, subframe, IF4_PULFFT, 0); send_IF4(eNB, frame, subframe, IF4_PULFFT, 0);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF4, 0 ); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF4, 0 );
} }
/// **** send_IF4 of prach to RCC **** /// done in prach thread (below)
// check if we have to detect PRACH first
if (is_prach_subframe(fp,proc->frame_rx,proc->subframe_rx)>0) {
// wake up thread for PRACH RX
if (pthread_mutex_lock(&proc->mutex_prach) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_mutex_lock for eNB PRACH thread %d (IC %d)\n", proc->instance_cnt_prach );
exit_fun( "error locking mutex_prach" );
return;
}
int cnt_prach = ++proc->instance_cnt_prach;
// set timing for prach thread
proc->frame_prach = proc->frame_rx;
proc->subframe_prach = proc->subframe_rx;
pthread_mutex_unlock( &proc->mutex_prach );
if (cnt_prach == 0) {
// the thread was presumably waiting where it should and can now be woken up
if (pthread_cond_signal(&proc->cond_prach) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_cond_signal for eNB PRACH thread %d\n", proc->thread_index);
exit_fun( "ERROR pthread_cond_signal" );
return;
}
} else {
LOG_W( PHY,"[eNB] Frame %d Subframe %d, eNB PRACH thread busy (IC %d)!!\n", proc->frame_rx,proc->subframe_rx,cnt_prach);
exit_fun( "PRACH thread busy" );
return;
}
}
} else if (eNB->node_function == NGFI_RRU_IF5) { }
else if (eNB->node_function == NGFI_RRU_IF5) {
/// **** send_IF5 of rxdata to BBU **** /// /// **** send_IF5 of rxdata to BBU **** ///
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF5, 1 ); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF5, 1 );
send_IF5(eNB, proc->timestamp_rx, proc->subframe_rx, &seqno, IF5_RRH_GW_UL); send_IF5(eNB, proc->timestamp_rx, proc->subframe_rx, &seqno, IF5_RRH_GW_UL);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF5, 0 ); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_SEND_IF5, 0 );
}
} else if (eNB->node_function == NGFI_RCC_IF4) {
/// **** recv_IF4 of rxdataF from RRU **** /// /// **** send_IF4 of prach to RCC **** /// done in prach thread (below)
/// **** recv_IF4 of rxsigF from RRU **** /// // check if we have to detect PRACH first
// get frame/subframe information from IF4 interface if ((eNB->node_function != NGFI_RRU_IF5) &&
// timed loop (200 us) (is_prach_subframe(fp,proc->frame_rx,proc->subframe_rx)>0)) { // any other node must call prach procedure
// wake up thread for PRACH RX
symbol_number = 0; if (pthread_mutex_lock(&proc->mutex_prach) != 0) {
symbol_mask = 0; LOG_E( PHY, "[eNB] ERROR pthread_mutex_lock for eNB PRACH thread %d (IC %d)\n", proc->instance_cnt_prach );
symbol_mask_full = (1<<fp->symbols_per_tti)-1; exit_fun( "error locking mutex_prach" );
prach_rx = 0; return;
}
do {
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF4, 1 ); int cnt_prach = ++proc->instance_cnt_prach;
recv_IF4(eNB, &proc->frame_rx, &proc->subframe_rx, &packet_type, &symbol_number); // set timing for prach thread
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF4, 0 ); proc->frame_prach = proc->frame_rx;
proc->subframe_prach = proc->subframe_rx;
if (packet_type == IF4_PULFFT) {
symbol_mask = symbol_mask | (1<<symbol_number); pthread_mutex_unlock( &proc->mutex_prach );
} else if (packet_type == IF4_PRACH) { if (cnt_prach == 0) {
// wake up thread for PRACH RX // the thread was presumably waiting where it should and can now be woken up
prach_rx = 1; if (pthread_cond_signal(&proc->cond_prach) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_cond_signal for eNB PRACH thread %d\n", proc->thread_index);
if (pthread_mutex_lock(&proc->mutex_prach) != 0) { exit_fun( "ERROR pthread_cond_signal" );
LOG_E( PHY, "[eNB] ERROR pthread_mutex_lock for eNB PRACH thread %d (IC %d)\n", proc->instance_cnt_prach ); return;
exit_fun( "error locking mutex_prach" ); }
return;
}
int cnt_prach = ++proc->instance_cnt_prach;
// set timing for prach thread
proc->frame_prach = proc->frame_rx;
proc->subframe_prach = proc->subframe_rx;
pthread_mutex_unlock( &proc->mutex_prach );
if (cnt_prach == 0) {
// the thread was presumably waiting where it should and can now be woken up
if (pthread_cond_signal(&proc->cond_prach) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_cond_signal for eNB PRACH thread %d\n", proc->thread_index);
exit_fun( "ERROR pthread_cond_signal" );
return;
}
} else {
LOG_W( PHY,"[eNB] Frame %d, eNB PRACH thread busy!!\n", frame);
exit_fun( "PRACH thread busy" );
return;
}
}
} while( (symbol_mask != symbol_mask_full) && (prach_rx == 0));
if (proc->first_rx == 0) {
if (proc->subframe_rx != subframe){
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->subframe_rx %d, subframe %d)\n",proc->subframe_rx,subframe);
//exit_fun("Exiting");
}
if (proc->frame_rx != frame) {
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->frame_rx %d frame %d)\n",proc->frame_rx,frame);
//exit_fun("Exiting");
}
} else { } else {
proc->first_rx = 0; LOG_W( PHY,"[eNB] Frame %d Subframe %d, eNB PRACH thread busy (IC %d)!!\n", proc->frame_rx,proc->subframe_rx,cnt_prach);
exit_fun( "PRACH thread busy" );
return;
} }
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_TRX_TS, proc->timestamp_rx&0xffffffff );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_SUBFRAME_NUMBER_RX_ENB, proc->subframe_rx );
// Tobi aka mr monaco: ETH
} else { // should not get here
AssertFatal(1==0, "Unknown eNB->node_function %d",eNB->node_function);
} }
} else { // grab transport channel information from network interface } else { // grab transport channel information from network interface
} }
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_COMMON, 0 );
} }
...@@ -2784,7 +2636,7 @@ void phy_procedures_eNB_uespec_RX(PHY_VARS_eNB *eNB,eNB_rxtx_proc_t *proc,const ...@@ -2784,7 +2636,7 @@ void phy_procedures_eNB_uespec_RX(PHY_VARS_eNB *eNB,eNB_rxtx_proc_t *proc,const
const int subframe = proc->subframe_rx; const int subframe = proc->subframe_rx;
const int frame = proc->frame_rx; const int frame = proc->frame_rx;
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX,1); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_UESPEC, 1 );
start_meas(&eNB->phy_proc_rx); start_meas(&eNB->phy_proc_rx);
#ifdef DEBUG_PHY_PROC #ifdef DEBUG_PHY_PROC
LOG_D(PHY,"[eNB %d] Frame %d: Doing phy_procedures_eNB_RX(%d)\n",eNB->Mod_id,frame, subframe); LOG_D(PHY,"[eNB %d] Frame %d: Doing phy_procedures_eNB_RX(%d)\n",eNB->Mod_id,frame, subframe);
...@@ -3346,7 +3198,8 @@ void phy_procedures_eNB_uespec_RX(PHY_VARS_eNB *eNB,eNB_rxtx_proc_t *proc,const ...@@ -3346,7 +3198,8 @@ void phy_procedures_eNB_uespec_RX(PHY_VARS_eNB *eNB,eNB_rxtx_proc_t *proc,const
phy_procedures_emos_eNB_RX(subframe,eNB); phy_procedures_emos_eNB_RX(subframe,eNB);
#endif #endif
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX,0); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_UESPEC, 0 );
stop_meas(&eNB->phy_proc_rx); stop_meas(&eNB->phy_proc_rx);
} }
......
targets/RT/USER/lte-enb.c
View file @ af489a78
...@@ -435,14 +435,16 @@ static void* eNB_thread_rxtx( void* param ) { ...@@ -435,14 +435,16 @@ static void* eNB_thread_rxtx( void* param ) {
if (oai_exit) break; if (oai_exit) break;
// Common procedures
phy_procedures_eNB_common_RX(PHY_vars_eNB_g[0][proc->CC_id], 0);
// UE-specific RX processing for subframe n // UE-specific RX processing for subframe n
if ((PHY_vars_eNB_g[0][proc->CC_id]->node_function == eNodeB_3GPP) || if ((PHY_vars_eNB_g[0][proc->CC_id]->node_function == eNodeB_3GPP) ||
(PHY_vars_eNB_g[0][proc->CC_id]->node_function == eNodeB_3GPP_BBU) || (PHY_vars_eNB_g[0][proc->CC_id]->node_function == eNodeB_3GPP_BBU) ||
(PHY_vars_eNB_g[0][proc->CC_id]->node_function == NGFI_RCC_IF4)) { (PHY_vars_eNB_g[0][proc->CC_id]->node_function == NGFI_RCC_IF4)) {
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_UESPEC, 1 );
// this is the ue-specific processing for the subframe and can be multi-threaded later // this is the ue-specific processing for the subframe and can be multi-threaded later
phy_procedures_eNB_uespec_RX(PHY_vars_eNB_g[0][proc->CC_id], proc, 0, no_relay ); phy_procedures_eNB_uespec_RX(PHY_vars_eNB_g[0][proc->CC_id], proc, 0, no_relay );
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_UESPEC, 0 );
} }
// TX processing for subframe n+4 // TX processing for subframe n+4
...@@ -629,23 +631,122 @@ static void wait_system_ready (char *message, volatile int *start_flag) { ...@@ -629,23 +631,122 @@ static void wait_system_ready (char *message, volatile int *start_flag) {
} }
#endif #endif
/*!
* \brief The Asynchronous RX FH thread of RAU/RCC/eNB.
* This handles the RX FH for an asynchronous RRU/UE
* \param param is a \ref eNB_proc_t structure which contains the info what to process.
* \returns a pointer to an int. The storage is not on the heap and must not be freed.
*/
static void* eNB_thread_asynch_rx( void* param ) {
eNB_proc_t *proc = (eNB_proc_t*)param;
PHY_VARS_eNB *eNB = PHY_vars_eNB_g[0][proc->CC_id];
LTE_DL_FRAME_PARMS *fp = &eNB->frame_parms;
openair0_timestamp timestamp_rx;
int frame_rx,subframe_rx;
int first_rx = 1;
uint16_t packet_type;
uint32_t symbol_number=0;
uint32_t symbol_mask, symbol_mask_full;
int prach_rx;
if (eNB->node_function == eNodeB_3GPP_BBU) { // acquisition from IF
/// **** recv_IF5 of rxdata from RRH **** ///
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF5, 1 );
recv_IF5(eNB, &timestamp_rx, subframe_rx++, IF5_RRH_GW_UL);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF5, 0 );
if (first_rx == 1) {
first_rx = 0;
subframe_rx = (timestamp_rx/fp->samples_per_tti)%10;
}
else {
// check timestamp
if ((timestamp_rx - proc->timestamp_rx) < (2*fp->samples_per_tti))
printf("RX overflow ...\n");
}
} // eNodeB_3GPP_BBU
else if (eNB->node_function == NGFI_RCC_IF4) {
/// **** recv_IF4 of rxdataF from RRU **** ///
/// **** recv_IF4 of rxsigF from RRU **** ///
// get frame/subframe information from IF4 interface
// timed loop (200 us)
symbol_number = 0;
symbol_mask = 0;
symbol_mask_full = (1<<fp->symbols_per_tti)-1;
prach_rx = 0;
do { // Blocking, we need a timeout on this !!!!!!!!!!!!!!!!!!!!!!!
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF4, 1 );
recv_IF4(eNB, &frame_rx, &subframe_rx, &packet_type, &symbol_number);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF4, 0 );
if (packet_type == IF4_PULFFT) {
symbol_mask = symbol_mask | (1<<symbol_number);
} else if (packet_type == IF4_PRACH) {
// wake up thread for PRACH RX
prach_rx = 1;
}
} while( (symbol_mask != symbol_mask_full) && (prach_rx == 0));
if (proc->first_rx == 0) {
if (subframe_rx < proc->subframe_rx+2){
LOG_E(PHY,"RX overflow (proc->subframe_rx %d, subframe_rx %d)\n",proc->subframe_rx,subframe_rx);
}
} else {
proc->first_rx = 0;
}
} // node_timing == synch_to_externs, node_function = NGFI_IF4
else { // should not get here
AssertFatal(1==0, "Unknown eNB->node_function %d",eNB->node_function);
}
}
/*! /*!
* \brief The RX common thread of eNB. * \brief The Fronthaul thread of RRU/RAU/RCC/eNB
* In the case of RRU/eNB, handles interface with external RF
* In the case of RAU/RCC, handles fronthaul interface with RRU/RAU
* \param param is a \ref eNB_proc_t structure which contains the info what to process. * \param param is a \ref eNB_proc_t structure which contains the info what to process.
* \returns a pointer to an int. The storage is not on the heap and must not be freed. * \returns a pointer to an int. The storage is not on the heap and must not be freed.
*/ */
static void* eNB_thread_rx_common( void* param ) { static void* eNB_thread_FH( void* param ) {
static int eNB_thread_rx_status; static int eNB_thread_FH_status;
eNB_proc_t *proc = (eNB_proc_t*)param; eNB_proc_t *proc = (eNB_proc_t*)param;
PHY_VARS_eNB *eNB = PHY_vars_eNB_g[0][proc->CC_id]; PHY_VARS_eNB *eNB = PHY_vars_eNB_g[0][proc->CC_id];
LTE_DL_FRAME_PARMS *fp = &eNB->frame_parms; LTE_DL_FRAME_PARMS *fp = &eNB->frame_parms;
void *rxp[fp->nb_antennas_rx];
unsigned int rxs;
FILE *rx_time_file = NULL; FILE *rx_time_file = NULL;
char rx_time_name[101]; char rx_time_name[101];
struct timespec wait; struct timespec wait;
int i;
int prach_rx;
uint16_t packet_type;
uint32_t symbol_number=0;
uint32_t symbol_mask, symbol_mask_full;
int subframe = proc->subframe_rx;
int frame = proc->frame_rx;
if (subframe==9) {
subframe=0;
frame++;
frame&=1023;
} else {
subframe++;
}
wait.tv_sec=0; wait.tv_sec=0;
wait.tv_nsec=5000000L; wait.tv_nsec=5000000L;
...@@ -655,7 +756,7 @@ static void* eNB_thread_rx_common( void* param ) { ...@@ -655,7 +756,7 @@ static void* eNB_thread_rx_common( void* param ) {
rx_time_file = fopen(rx_time_name,"w"); rx_time_file = fopen(rx_time_name,"w");
} }
// set default return value // set default return value
eNB_thread_rx_status = 0; eNB_thread_FH_status = 0;
MSC_START_USE(); MSC_START_USE();
...@@ -678,7 +779,7 @@ static void* eNB_thread_rx_common( void* param ) { ...@@ -678,7 +779,7 @@ static void* eNB_thread_rx_common( void* param ) {
if (sched_setattr(0, &attr, flags) < 0 ) { if (sched_setattr(0, &attr, flags) < 0 ) {
perror("[SCHED] eNB RX sched_setattr failed\n"); perror("[SCHED] eNB RX sched_setattr failed\n");
return &eNB_thread_rx_status; return &eNB_thread_FH_status;
} }
LOG_I( HW, "[SCHED] eNB RX deadline thread (TID %ld) started on CPU %d\n", gettid(), sched_getcpu() ); LOG_I( HW, "[SCHED] eNB RX deadline thread (TID %ld) started on CPU %d\n", gettid(), sched_getcpu() );
...@@ -796,32 +897,205 @@ static void* eNB_thread_rx_common( void* param ) { ...@@ -796,32 +897,205 @@ static void* eNB_thread_rx_common( void* param ) {
// This is a forever while loop, it loops over subframes which are scheduled by incoming samples from HW devices // This is a forever while loop, it loops over subframes which are scheduled by incoming samples from HW devices
while (!oai_exit) { while (!oai_exit) {
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_RX, 0 );
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_COMMON, 0 );
start_meas( &softmodem_stats_rx_sf );
if (oai_exit) break; if (oai_exit) break;
if ((((fp->frame_type == TDD )&&(subframe_select(fp,proc->subframe_rx)==SF_UL)) ||
(fp->frame_type == FDD))) { if ((eNB->node_timing == synch_to_other) &&
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_COMMON, 1 ); ((eNB->node_function == NGFI_RRU_IF4) ||
// this spawns the prach inside and updates the frame and subframe counters (eNB->node_function == NGFI_RRU_IF5) ||
phy_procedures_eNB_common_RX(eNB, 0); (eNB->node_function == eNodeB_3GPP))) { // This case is for synchronization to another thread
//wait for event
// how long should we wait here, for MOBIPASS this could be long
// if (pthread_mutex_timedlock(&proc->mutex_FH,&wait) != 0) {
if (pthread_mutex_lock(&proc->mutex_FH) != 0) {
LOG_E( PHY, "[SCHED][eNB] error locking mutex for FH\n");
exit_fun( "error locking mutex" );
break;
}
while (proc->instance_cnt_FH < 0) {
// most of the time the thread is waiting here
// proc->instance_cnt_prach is -1
pthread_cond_wait( &proc->cond_FH,&proc->mutex_FH ); // this unlocks mutex_rxtx while waiting and then locks it again
}
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_RX_COMMON, 0 ); proc->instance_cnt_FH++;
} }
// Remaining cases are all for synchronization on FH interface
else if ((eNB->node_timing == synch_to_ext_device) &&
((eNB->node_function == NGFI_RRU_IF4) ||
(eNB->node_function == NGFI_RRU_IF5) ||
(eNB->node_function == eNodeB_3GPP))) { // acquisition from RF
for (i=0; i<fp->nb_antennas_rx; i++)
rxp[i] = (void*)&eNB->common_vars.rxdata[0][i][subframe*fp->samples_per_tti];
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_TRX_READ, 1 );
rxs = eNB->rfdevice.trx_read_func(&eNB->rfdevice,
&proc->timestamp_rx,
rxp,
fp->samples_per_tti,
fp->nb_antennas_rx);
proc->frame_rx = (proc->timestamp_rx / (fp->samples_per_tti*10))&1023;
proc->subframe_rx = (proc->timestamp_rx / fp->samples_per_tti)%10;
if (proc->first_rx == 0) {
if (proc->subframe_rx != subframe){
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->subframe_rx %d, subframe %d)\n",proc->subframe_rx,subframe);
exit_fun("Exiting");
}
if (proc->frame_rx != frame) {
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->frame_rx %d frame %d)\n",proc->frame_rx,frame);
exit_fun("Exiting");
}
} else {
proc->first_rx = 0;
}
// printf("timestamp_rx %lu, frame %d(%d), subframe %d(%d)\n",proc->timestamp_rx,proc->frame_rx,frame,proc->subframe_rx,subframe);
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_TRX_TS, proc->timestamp_rx&0xffffffff );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_SUBFRAME_NUMBER_RX_ENB, proc->subframe_rx );
if (rxs != fp->samples_per_tti)
exit_fun( "problem receiving samples" );
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_TRX_READ, 0 );
} // node_timing==synch_to_ext_device && node_function == RRU || eNodeB
else if ((eNB->node_timing == synch_to_ext_device) &&
(eNB->node_function == eNodeB_3GPP_BBU)) { // acquisition from IF
/// **** recv_IF5 of rxdata from RRH **** ///
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF5, 1 );
recv_IF5(eNB, &proc->timestamp_rx, proc->subframe_rx, IF5_RRH_GW_UL);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF5, 0 );
proc->frame_rx = (proc->timestamp_rx / (fp->samples_per_tti*10))&1023;
proc->subframe_rx = (proc->timestamp_rx / fp->samples_per_tti)%10;
if (proc->first_rx == 0) {
if (proc->subframe_rx != subframe){
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->subframe_rx %d, subframe %d)\n",proc->subframe_rx,subframe);
//exit_fun("Exiting");
}
if (proc->frame_rx != frame) {
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->frame_rx %d frame %d)\n",proc->frame_rx,frame);
//exit_fun("Exiting");
}
} else {
proc->first_rx = 0;
}
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_TRX_TS, proc->timestamp_rx&0xffffffff );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_SUBFRAME_NUMBER_RX_ENB, proc->subframe_rx );
} // eNodeB_3GPP_BBU && node_timing == synch_to_ext_device
else if ((eNB->node_timing == synch_to_ext_device) &&
(eNB->node_function == NGFI_RCC_IF4)) {
/// **** recv_IF4 of rxdataF from RRU **** ///
/// **** recv_IF4 of rxsigF from RRU **** ///
// get frame/subframe information from IF4 interface
// timed loop (200 us)
symbol_number = 0;
symbol_mask = 0;
symbol_mask_full = (1<<fp->symbols_per_tti)-1;
prach_rx = 0;
do { // Blocking, we need a timeout on this !!!!!!!!!!!!!!!!!!!!!!!
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF4, 1 );
recv_IF4(eNB, &proc->frame_rx, &proc->subframe_rx, &packet_type, &symbol_number);
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_RECV_IF4, 0 );
if (packet_type == IF4_PULFFT) {
symbol_mask = symbol_mask | (1<<symbol_number);
} else if (packet_type == IF4_PRACH) {
// wake up thread for PRACH RX
prach_rx = 1;
}
} while( (symbol_mask != symbol_mask_full) && (prach_rx == 0));
if (proc->first_rx == 0) {
if (proc->subframe_rx != subframe){
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->subframe_rx %d, subframe %d)\n",proc->subframe_rx,subframe);
//exit_fun("Exiting");
}
if (proc->frame_rx != frame) {
LOG_E(PHY,"Received Timestamp doesn't correspond to the time we think it is (proc->frame_rx %d frame %d)\n",proc->frame_rx,frame);
//exit_fun("Exiting");
}
} else {
proc->first_rx = 0;
}
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_TRX_TS, proc->timestamp_rx&0xffffffff );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_FRAME_NUMBER_RX_ENB, proc->frame_rx );
VCD_SIGNAL_DUMPER_DUMP_VARIABLE_BY_NAME( VCD_SIGNAL_DUMPER_VARIABLES_SUBFRAME_NUMBER_RX_ENB, proc->subframe_rx );
} // node_timing == synch_to_externs, node_function = NGFI_IF4
else { // should not get here
AssertFatal(1==0, "Unknown eNB->node_function %d",eNB->node_function);
}
// At this point, all information for subframe has been received on FH interface
// If this proc is to provide synchronization, do so
for (i=0;i<proc->num_slaves;i++) {
eNB_proc_t *slave_proc = proc->slave_proc[i];
// wake up slave FH thread
// lock the FH mutex and make sure the thread is ready
if (pthread_mutex_timedlock(&slave_proc->mutex_FH,&wait) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_mutex_lock for eNB CCid %d slave CCid %d (IC %d)\n",proc->CC_id,slave_proc->CC_id);
exit_fun( "error locking mutex_rxtx" );
break;
}
int cnt_slave = ++slave_proc->instance_cnt_FH;
slave_proc->frame_rx = proc->frame_rx;
slave_proc->subframe_rx = proc->subframe_rx;
slave_proc->timestamp_rx = proc->timestamp_rx;
pthread_mutex_unlock( &slave_proc->mutex_FH );
if (cnt_slave == 0) {
// the thread was presumably waiting where it should and can now be woken up
if (pthread_cond_signal(&slave_proc->cond_FH) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_cond_signal for eNB CCid %d, slave CCid %d\n",proc->CC_id,slave_proc->CC_id);
exit_fun( "ERROR pthread_cond_signal" );
break;
}
} else {
LOG_W( PHY,"[eNB] Frame %d, FH CC_id %d thread busy!! (cnt_rxtx %i)\n",slave_proc->frame_rx,slave_proc->CC_id, cnt_slave);
exit_fun( "TX thread busy" );
break;
}
}
// wake up RXn_TXnp4 thread for the subframe
// choose even or odd thread for RXn-TXnp4 processing // choose even or odd thread for RXn-TXnp4 processing
eNB_rxtx_proc_t *proc_rxtx = &proc->proc_rxtx[proc->subframe_rx&1]; eNB_rxtx_proc_t *proc_rxtx = &proc->proc_rxtx[proc->subframe_rx&1];
// wake up TX for subframe n+4 // wake up TX for subframe n+4
// lock the TX mutex and make sure the thread is ready // lock the TX mutex and make sure the thread is ready
if (pthread_mutex_timedlock(&proc_rxtx->mutex_rxtx,&wait) != 0) { if (pthread_mutex_timedlock(&proc_rxtx->mutex_rxtx,&wait) != 0) {
LOG_E( PHY, "[eNB] ERROR pthread_mutex_lock for eNB TX thread %d (IC %d)\n", proc_rxtx->instance_cnt_rxtx ); LOG_E( PHY, "[eNB] ERROR pthread_mutex_lock for eNB RXTX thread %d (IC %d)\n", proc_rxtx->subframe_rx&1,proc_rxtx->instance_cnt_rxtx );
exit_fun( "error locking mutex_rxtx" ); exit_fun( "error locking mutex_rxtx" );
break; break;
} }
int cnt_rxtx = ++proc_rxtx->instance_cnt_rxtx; int cnt_rxtx = ++proc_rxtx->instance_cnt_rxtx;
// We have just received and processed the common part of a subframe, say n. // We have just received and processed the common part of a subframe, say n.
// TS_rx is the last received timestamp (start of 1st slot), TS_tx is the desired // TS_rx is the last received timestamp (start of 1st slot), TS_tx is the desired
// transmitted timestamp of the next TX slot (first). // transmitted timestamp of the next TX slot (first).
...@@ -865,12 +1139,20 @@ static void* eNB_thread_rx_common( void* param ) { ...@@ -865,12 +1139,20 @@ static void* eNB_thread_rx_common( void* param ) {
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_RXTX0+(proc->subframe_rx&1), 0 ); VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME( VCD_SIGNAL_DUMPER_FUNCTIONS_eNB_PROC_RXTX0+(proc->subframe_rx&1), 0 );
} }
if (eNB->node_timing == synch_to_ext_device) {
printf( "Exiting eNB thread rx_common\n"); proc->instance_cnt_FH--;
if (pthread_mutex_unlock(&proc->mutex_FH) != 0) {
LOG_E( PHY, "[SCHED][eNB] error unlocking mutex for FH\n");
exit_fun( "error unlocking mutex" );
}
}
printf( "Exiting FH thread \n");
eNB_thread_rx_status = 0; eNB_thread_FH_status = 0;
return &eNB_thread_rx_status; return &eNB_thread_FH_status;
} }
...@@ -1070,9 +1352,9 @@ void init_eNB_proc(void) { ...@@ -1070,9 +1352,9 @@ void init_eNB_proc(void) {
pthread_attr_setschedparam (&proc_rxtx[1].attr_rxtx, &proc_rxtx[1].sched_param_rxtx); pthread_attr_setschedparam (&proc_rxtx[1].attr_rxtx, &proc_rxtx[1].sched_param_rxtx);
pthread_attr_setschedpolicy (&proc_rxtx[1].attr_rxtx, SCHED_FIFO); pthread_attr_setschedpolicy (&proc_rxtx[1].attr_rxtx, SCHED_FIFO);
proc->sched_param_rx.sched_priority = sched_get_priority_max(SCHED_FIFO); //OPENAIR_THREAD_PRIORITY; proc->sched_param_FH.sched_priority = sched_get_priority_max(SCHED_FIFO); //OPENAIR_THREAD_PRIORITY;
pthread_attr_setschedparam (&proc->attr_rx, &proc->sched_param_rx); pthread_attr_setschedparam (&proc->attr_FH, &proc->sched_param_FH);
pthread_attr_setschedpolicy (&proc->attr_rx, SCHED_FIFO); pthread_attr_setschedpolicy (&proc->attr_FH, SCHED_FIFO);
proc->sched_param_prach.sched_priority = sched_get_priority_max(SCHED_FIFO)-1; //OPENAIR_THREAD_PRIORITY; proc->sched_param_prach.sched_priority = sched_get_priority_max(SCHED_FIFO)-1; //OPENAIR_THREAD_PRIORITY;
pthread_attr_setschedparam (&proc->attr_prach, &proc->sched_param_prach); pthread_attr_setschedparam (&proc->attr_prach, &proc->sched_param_prach);
...@@ -1083,6 +1365,7 @@ void init_eNB_proc(void) { ...@@ -1083,6 +1365,7 @@ void init_eNB_proc(void) {
proc_rxtx[0].instance_cnt_rxtx = -1; proc_rxtx[0].instance_cnt_rxtx = -1;
proc_rxtx[1].instance_cnt_rxtx = -1; proc_rxtx[1].instance_cnt_rxtx = -1;
proc->instance_cnt_prach = -1; proc->instance_cnt_prach = -1;
proc->instance_cnt_FH = -1;
proc->CC_id = CC_id; proc->CC_id = CC_id;
proc->first_rx=4; proc->first_rx=4;
...@@ -1093,24 +1376,30 @@ void init_eNB_proc(void) { ...@@ -1093,24 +1376,30 @@ void init_eNB_proc(void) {
pthread_cond_init( &proc_rxtx[0].cond_rxtx, NULL); pthread_cond_init( &proc_rxtx[0].cond_rxtx, NULL);
pthread_cond_init( &proc_rxtx[1].cond_rxtx, NULL); pthread_cond_init( &proc_rxtx[1].cond_rxtx, NULL);
pthread_cond_init( &proc->cond_prach, NULL); pthread_cond_init( &proc->cond_prach, NULL);
pthread_cond_init( &proc->cond_FH, NULL);
#ifndef DEADLINE_SCHEDULER #ifndef DEADLINE_SCHEDULER
pthread_create( &proc_rxtx[0].pthread_rxtx, &proc_rxtx[0].attr_rxtx, eNB_thread_rxtx, &proc_rxtx[0] ); pthread_create( &proc_rxtx[0].pthread_rxtx, &proc_rxtx[0].attr_rxtx, eNB_thread_rxtx, &proc_rxtx[0] );
pthread_create( &proc_rxtx[1].pthread_rxtx, &proc_rxtx[1].attr_rxtx, eNB_thread_rxtx, &proc_rxtx[1] ); pthread_create( &proc_rxtx[1].pthread_rxtx, &proc_rxtx[1].attr_rxtx, eNB_thread_rxtx, &proc_rxtx[1] );
pthread_create( &proc->pthread_rx, &proc->attr_rx, eNB_thread_rx_common, &eNB->proc ); pthread_create( &proc->pthread_FH, &proc->attr_FH, eNB_thread_FH, &eNB->proc );
pthread_create( &proc->pthread_prach, &proc->attr_prach, eNB_thread_prach, &eNB->proc ); pthread_create( &proc->pthread_prach, &proc->attr_prach, eNB_thread_prach, &eNB->proc );
if (eNB->node_timing == synch_to_other)
pthread_create( &proc->pthread_asynch_rx, &proc->attr_asynch_rx, eNB_thread_asynch_rx, &eNB->proc );
#else #else
pthread_create( &proc_rxtx[0].pthread_rxtx, NULL, eNB_thread_rxtx, &eNB->proc_rxtx[0] ); pthread_create( &proc_rxtx[0].pthread_rxtx, NULL, eNB_thread_rxtx, &eNB->proc_rxtx[0] );
pthread_create( &proc_rxtx[1].pthread_rxtx, NULL, eNB_thread_rxtx, &eNB->proc_rxtx[1] ); pthread_create( &proc_rxtx[1].pthread_rxtx, NULL, eNB_thread_rxtx, &eNB->proc_rxtx[1] );
pthread_create( &proc->pthread_rx, NULL, eNB_thread_rx_common, &eNB->proc ); pthread_create( &proc->pthread_FH, NULL, eNB_thread_FH, &eNB->proc );
pthread_create( &proc->pthread_prach, NULL, eNB_thread_prach, &eNB->proc ); pthread_create( &proc->pthread_prach, NULL, eNB_thread_prach, &eNB->proc );
if (eNB->node_timing == synch_to_other)
pthread_create( &proc->pthread_asynch_rx, NULL, eNB_thread_asynch_rx, &eNB->proc );
#endif #endif
char name[16]; char name[16];
snprintf( name, sizeof(name), "RXTX0 %d", i ); snprintf( name, sizeof(name), "RXTX0 %d", i );
pthread_setname_np( proc_rxtx[0].pthread_rxtx, name ); pthread_setname_np( proc_rxtx[0].pthread_rxtx, name );
snprintf( name, sizeof(name), "RXTX1 %d", i ); snprintf( name, sizeof(name), "RXTX1 %d", i );
pthread_setname_np( proc_rxtx[1].pthread_rxtx, name ); pthread_setname_np( proc_rxtx[1].pthread_rxtx, name );
snprintf( name, sizeof(name), "RX %d", i ); snprintf( name, sizeof(name), "FH %d", i );
pthread_setname_np( proc->pthread_rx, name ); pthread_setname_np( proc->pthread_FH, name );
} }
/* setup PHY proc TX sync mechanism */ /* setup PHY proc TX sync mechanism */
...@@ -1142,63 +1431,27 @@ void kill_eNB_proc(void) { ...@@ -1142,63 +1431,27 @@ void kill_eNB_proc(void) {
proc_rxtx[0].instance_cnt_rxtx = 0; // FIXME data race! proc_rxtx[0].instance_cnt_rxtx = 0; // FIXME data race!
proc_rxtx[1].instance_cnt_rxtx = 0; // FIXME data race! proc_rxtx[1].instance_cnt_rxtx = 0; // FIXME data race!
proc->instance_cnt_prach = 0; proc->instance_cnt_prach = 0;
proc->instance_cnt_FH = 0;
pthread_cond_signal( &proc_rxtx[0].cond_rxtx ); pthread_cond_signal( &proc_rxtx[0].cond_rxtx );
pthread_cond_signal( &proc_rxtx[1].cond_rxtx ); pthread_cond_signal( &proc_rxtx[1].cond_rxtx );
pthread_cond_signal( &proc->cond_prach ); pthread_cond_signal( &proc->cond_prach );
pthread_cond_signal( &proc->cond_FH );
pthread_cond_broadcast(&sync_phy_proc.cond_phy_proc_tx); pthread_cond_broadcast(&sync_phy_proc.cond_phy_proc_tx);
pthread_join( proc->pthread_rx, (void**)&status ); pthread_join( proc->pthread_FH, (void**)&status );
pthread_mutex_destroy( &proc->mutex_FH );
pthread_cond_destroy( &proc->cond_FH );
pthread_join( proc->pthread_prach, (void**)&status );
pthread_mutex_destroy( &proc->mutex_prach );
pthread_cond_destroy( &proc->cond_prach );
int result,i; int i;
for (i=0;i<2;i++) { for (i=0;i<2;i++) {
pthread_join( proc_rxtx[i].pthread_rxtx, (void**)&status ); pthread_join( proc_rxtx[i].pthread_rxtx, (void**)&status );
#ifdef DEBUG_THREADS
if (result != 0) {
printf( "Error joining thread.\n" );
} else {
if (status) {
printf( "status %d\n", *status );
} else {
printf( "The thread was killed. No status available.\n" );
}
}
#else
UNUSED(result);
#endif
pthread_mutex_destroy( &proc_rxtx[i].mutex_rxtx ); pthread_mutex_destroy( &proc_rxtx[i].mutex_rxtx );
pthread_cond_destroy( &proc_rxtx[i].cond_rxtx ); pthread_cond_destroy( &proc_rxtx[i].cond_rxtx );
} }
#ifdef DEBUG_THREADS
printf( "Killing RX CC_id %d thread\n", CC_id);
#endif
#ifdef DEBUG_THREADS
printf( "Joining eNB RX CC_id %d thread ...\n", CC_id);
#endif
result = pthread_join( proc->pthread_rx, (void**)&status );
#ifdef DEBUG_THREADS
if (result != 0) {
printf( "Error joining thread.\n" );
} else {
if (status) {
printf( "status %d\n", *status );
} else {
printf( "The thread was killed. No status available.\n" );
}
}
#else
UNUSED(result);
#endif
pthread_mutex_destroy( &proc->mutex_prach );
pthread_cond_destroy( &proc->cond_prach );
} }
} }
......
targets/SIMU/USER/oaisim_functions.c
View file @ af489a78
...@@ -1166,17 +1166,6 @@ void init_ocm(void) ...@@ -1166,17 +1166,6 @@ void init_ocm(void)
LOG_D(OCM,"Initializing channel (%s, %d) from eNB %d to UE %d\n", oai_emulation.environment_system_config.fading.small_scale.selected_option, LOG_D(OCM,"Initializing channel (%s, %d) from eNB %d to UE %d\n", oai_emulation.environment_system_config.fading.small_scale.selected_option,
map_str_to_int(small_scale_names,oai_emulation.environment_system_config.fading.small_scale.selected_option), eNB_id, UE_id); map_str_to_int(small_scale_names,oai_emulation.environment_system_config.fading.small_scale.selected_option), eNB_id, UE_id);
/* if (oai_emulation.info.transmission_mode == 5)
eNB2UE[eNB_id][UE_id] = new_channel_desc_scm(PHY_vars_eNB_g[eNB_id]->frame_parms.nb_antennas_tx,
PHY_vars_UE_g[UE_id]->frame_parms.nb_antennas_rx,
(UE_id == 0)? Rice1_corr : Rice1_anticorr,
oai_emulation.environment_system_config.system_bandwidth_MB,
forgetting_factor,
0,
0);
else
*/
eNB2UE[eNB_id][UE_id][CC_id] = eNB2UE[eNB_id][UE_id][CC_id] =
new_channel_desc_scm(PHY_vars_eNB_g[eNB_id][CC_id]->frame_parms.nb_antennas_tx, new_channel_desc_scm(PHY_vars_eNB_g[eNB_id][CC_id]->frame_parms.nb_antennas_tx,
......
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