Commit 5e991ecc authored by Raymond Knopp's avatar Raymond Knopp

fixed compilatiaon issues after merge with develop and enhancement-rfsim....

fixed compilatiaon issues after merge with develop and enhancement-rfsim. Intitial testing with emulator.
parent 45dc7ed6
......@@ -1145,7 +1145,7 @@ set(PHY_SRC
${OPENAIR1_DIR}/PHY/LTE_TRANSPORT/uci_tools.c
${OPENAIR1_DIR}/PHY/LTE_ESTIMATION/freq_equalization.c
${OPENAIR1_DIR}/PHY/LTE_ESTIMATION/lte_adjust_sync_eNB.c
${OPENAIR1_DIR}/PHY/LTE_ESTIMATION/lte_ul_channel_estimation.c
# ${OPENAIR1_DIR}/PHY/LTE_ESTIMATION/lte_ul_channel_estimation.c
${OPENAIR1_DIR}/PHY/LTE_ESTIMATION/lte_eNB_measurements.c
${OPENAIR1_DIR}/PHY/INIT/lte_init.c
)
......@@ -1154,6 +1154,8 @@ set(PHY_SRC_RU
# actual source
${OPENAIR1_DIR}/PHY/LTE_TRANSPORT/if4_tools.c
${OPENAIR1_DIR}/PHY/LTE_TRANSPORT/if5_tools.c
${OPENAIR1_DIR}/PHY/LTE_UE_TRANSPORT/drs_modulation.c
${OPENAIR1_DIR}/PHY/LTE_ESTIMATION/lte_ul_channel_estimation.c
${OPENAIR1_DIR}/PHY/MODULATION/slot_fep_ul.c
${OPENAIR1_DIR}/PHY/MODULATION/ul_7_5_kHz.c
${OPENAIR1_DIR}/PHY/MODULATION/beamforming.c
......
......@@ -720,7 +720,6 @@ void generate_phich_top(PHY_VARS_eNB *eNB,
uint32_t pusch_frame;
int subframe = proc->subframe_tx;
phich_config_t *phich;
int absSF = subframe+(proc->frame_tx*10);
// compute Ngroup_PHICH (see formula at beginning of Section 6.9 in 36-211
......@@ -732,20 +731,16 @@ void generate_phich_top(PHY_VARS_eNB *eNB,
if (frame_parms->Ncp == 1)
NSF_PHICH = 2;
for (i=0; i<MAX_NUM_PHICH; i++) {
phich = &eNB->phich_vars.config[i];
if (phich->active == 0 || phich->absSF != absSF) continue;
if (eNB->phich_vars[subframe&1].num_hi > 0) {
pusch_frame = phich_frame2_pusch_frame(frame_parms,proc->frame_tx,subframe);
pusch_subframe = phich_subframe2_pusch_subframe(frame_parms,subframe);
harq_pid = subframe2harq_pid(frame_parms,pusch_frame,pusch_subframe);
phich->active = 0;
}
for (i=0; i<eNB->phich_vars[subframe&1].num_hi; i++) {
phich = &eNB->phich_vars[subframe&1].config[i];
ngroup_PHICH = (phich->first_rb +
phich->n_DMRS)%Ngroup_PHICH;
......@@ -778,6 +773,8 @@ void generate_phich_top(PHY_VARS_eNB *eNB,
phich->hi,
subframe,
txdataF);
}
}// for (i=0; i<eNB->phich_vars[subframe&1].num_hi; i++) {
eNB->phich_vars[subframe&1].num_hi=0;
}
......@@ -267,6 +267,23 @@ typedef enum {
//EMULATE_RF =6
} RU_if_south_t;
typedef enum {
RU_IDLE = 0,
RU_CONFIG = 1,
RU_READY = 2,
RU_RUN = 3,
RU_ERROR = 4,
RU_SYNC = 5
} rru_state_t;
/// Some commamds to RRU. Not sure we should do it like this !
typedef enum {
EMPTY = 0,
STOP_RU = 1,
RU_FRAME_RESYNCH = 2,
WAIT_RESYNCH = 3
} rru_cmd_t;
typedef struct RU_t_s{
/// index of this ru
uint32_t idx;
......@@ -286,6 +303,12 @@ typedef struct RU_t_s{
int rx_offset;
/// flag to indicate the RU is a slave to another source
int is_slave;
/// flag to indicate that the RU should generate the DMRS sequence in slot 2 (subframe 1) for OTA synchronization and calibration
int generate_dmrs_sync;
/// flag to indicate if the RU has a control channel
int has_ctrl_prt;
/// counter to delay start of processing of RU until HW settles
int wait_cnt;
/// Total gain of receive chain
uint32_t rx_total_gain_dB;
/// number of bands that this device can support
......@@ -393,11 +416,18 @@ typedef struct RU_t_s{
uint8_t seqno;
/// initial timestamp used as an offset make first real timestamp 0
openair0_timestamp ts_offset;
/// Current state of the RU
rru_state_t state;
/// Command to do
rru_cmd_t cmd;
/// value to be passed using command
uint16_t cmdval;
/// process scheduling variables
RU_proc_t proc;
/// stats thread pthread descriptor
pthread_t ru_stats_thread;
/// OTA synchronization signal
int16_t *dmrssync;
} RU_t;
......@@ -407,7 +437,12 @@ typedef enum {
RAU_tick=0,
RRU_capabilities=1,
RRU_config=2,
RRU_MSG_max_num=3
RRU_config_ok=3,
RRU_start=4,
RRU_stop=5,
RRU_sync_ok=6,
RRU_frame_resynch=7,
RRU_MSG_max_num=8
} rru_config_msg_type_t;
typedef struct RRU_CONFIG_msg_s {
......@@ -823,7 +858,11 @@ typedef struct eNB_proc_t_s {
/// mutex for RU access to eNB processing (PRACH BR)
pthread_mutex_t mutex_RU_PRACH_br;
/// mask for RUs serving eNB (PDSCH/PUSCH)
int RU_mask;
int RU_mask[10];
/// time measurements for RU arrivals
struct timespec t[10];
/// Timing statistics (RU_arrivals)
time_stats_t ru_arrival_time;
/// mask for RUs serving eNB (PRACH)
int RU_mask_prach;
#if (RRC_VERSION >= MAKE_VERSION(14, 0, 0))
......@@ -1139,524 +1178,6 @@ typedef struct PHY_VARS_eNB_s {
int32_t pusch_stats_BO[NUMBER_OF_UE_MAX][10240];
} PHY_VARS_eNB;
<<<<<<< HEAD:openair1/PHY/defs.h
#define debug_msg if (((mac_xface->frame%100) == 0) || (mac_xface->frame < 50)) msg
/// Top-level PHY Data Structure for UE
typedef struct {
/// \brief Module ID indicator for this instance
uint8_t Mod_id;
/// \brief Component carrier ID for this PHY instance
uint8_t CC_id;
/// \brief Mapping of CC_id antennas to cards
openair0_rf_map rf_map;
//uint8_t local_flag;
/// \brief Indicator of current run mode of UE (normal_txrx, rx_calib_ue, no_L2_connect, debug_prach)
runmode_t mode;
/// \brief Indicator that UE should perform band scanning
int UE_scan;
/// \brief Indicator that UE should perform coarse scanning around carrier
int UE_scan_carrier;
/// \brief Indicator that UE is synchronized to an eNB
int is_synchronized;
/// Data structure for UE process scheduling
UE_proc_t proc;
/// Flag to indicate the UE shouldn't do timing correction at all
int no_timing_correction;
/// \brief Total gain of the TX chain (16-bit baseband I/Q to antenna)
uint32_t tx_total_gain_dB;
/// \brief Total gain of the RX chain (antenna to baseband I/Q) This is a function of rx_gain_mode (and the corresponding gain) and the rx_gain of the card.
uint32_t rx_total_gain_dB;
/// \brief Total gains with maximum RF gain stage (ExpressMIMO2/Lime)
uint32_t rx_gain_max[4];
/// \brief Total gains with medium RF gain stage (ExpressMIMO2/Lime)
uint32_t rx_gain_med[4];
/// \brief Total gains with bypassed RF gain stage (ExpressMIMO2/Lime)
uint32_t rx_gain_byp[4];
/// \brief Current transmit power
int16_t tx_power_dBm[10];
/// \brief Total number of REs in current transmission
int tx_total_RE[10];
/// \brief Maximum transmit power
int8_t tx_power_max_dBm;
/// \brief Number of eNB seen by UE
uint8_t n_connected_eNB;
/// \brief indicator that Handover procedure has been initiated
uint8_t ho_initiated;
/// \brief indicator that Handover procedure has been triggered
uint8_t ho_triggered;
/// \brief Measurement variables.
PHY_MEASUREMENTS measurements;
LTE_DL_FRAME_PARMS frame_parms;
/// \brief Frame parame before ho used to recover if ho fails.
LTE_DL_FRAME_PARMS frame_parms_before_ho;
LTE_UE_COMMON common_vars;
// point to the current rxTx thread index
uint8_t current_thread_id[10];
LTE_UE_PDSCH *pdsch_vars[RX_NB_TH_MAX][NUMBER_OF_CONNECTED_eNB_MAX+1]; // two RxTx Threads
LTE_UE_PDSCH_FLP *pdsch_vars_flp[NUMBER_OF_CONNECTED_eNB_MAX+1];
LTE_UE_PDSCH *pdsch_vars_SI[NUMBER_OF_CONNECTED_eNB_MAX+1];
LTE_UE_PDSCH *pdsch_vars_ra[NUMBER_OF_CONNECTED_eNB_MAX+1];
LTE_UE_PDSCH *pdsch_vars_p[NUMBER_OF_CONNECTED_eNB_MAX+1];
LTE_UE_PDSCH *pdsch_vars_MCH[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_PBCH *pbch_vars[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_PDCCH *pdcch_vars[RX_NB_TH_MAX][NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_PRACH *prach_vars[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_DLSCH_t *dlsch[RX_NB_TH_MAX][NUMBER_OF_CONNECTED_eNB_MAX][2]; // two RxTx Threads
LTE_UE_ULSCH_t *ulsch[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_DLSCH_t *dlsch_SI[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_DLSCH_t *dlsch_ra[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_DLSCH_t *dlsch_p[NUMBER_OF_CONNECTED_eNB_MAX];
LTE_UE_DLSCH_t *dlsch_MCH[NUMBER_OF_CONNECTED_eNB_MAX];
// This is for SIC in the UE, to store the reencoded data
LTE_eNB_DLSCH_t *dlsch_eNB[NUMBER_OF_CONNECTED_eNB_MAX];
//Paging parameters
uint32_t IMSImod1024;
uint32_t PF;
uint32_t PO;
// For abstraction-purposes only
uint8_t sr[10];
uint8_t pucch_sel[10];
uint8_t pucch_payload[22];
UE_MODE_t UE_mode[NUMBER_OF_CONNECTED_eNB_MAX];
/// cell-specific reference symbols
uint32_t lte_gold_table[7][20][2][14];
/// UE-specific reference symbols (p=5), TM 7
uint32_t lte_gold_uespec_port5_table[20][38];
/// ue-specific reference symbols
uint32_t lte_gold_uespec_table[2][20][2][21];
/// mbsfn reference symbols
uint32_t lte_gold_mbsfn_table[10][3][42];
uint32_t X_u[64][839];
uint32_t high_speed_flag;
uint32_t perfect_ce;
int16_t ch_est_alpha;
int generate_ul_signal[NUMBER_OF_CONNECTED_eNB_MAX];
UE_SCAN_INFO_t scan_info[NB_BANDS_MAX];
char ulsch_no_allocation_counter[NUMBER_OF_CONNECTED_eNB_MAX];
unsigned char ulsch_Msg3_active[NUMBER_OF_CONNECTED_eNB_MAX];
uint32_t ulsch_Msg3_frame[NUMBER_OF_CONNECTED_eNB_MAX];
unsigned char ulsch_Msg3_subframe[NUMBER_OF_CONNECTED_eNB_MAX];
PRACH_RESOURCES_t *prach_resources[NUMBER_OF_CONNECTED_eNB_MAX];
int turbo_iterations, turbo_cntl_iterations;
/// \brief ?.
/// - first index: eNB [0..NUMBER_OF_CONNECTED_eNB_MAX[ (hard coded)
uint32_t total_TBS[NUMBER_OF_CONNECTED_eNB_MAX];
/// \brief ?.
/// - first index: eNB [0..NUMBER_OF_CONNECTED_eNB_MAX[ (hard coded)
uint32_t total_TBS_last[NUMBER_OF_CONNECTED_eNB_MAX];
/// \brief ?.
/// - first index: eNB [0..NUMBER_OF_CONNECTED_eNB_MAX[ (hard coded)
uint32_t bitrate[NUMBER_OF_CONNECTED_eNB_MAX];
/// \brief ?.
/// - first index: eNB [0..NUMBER_OF_CONNECTED_eNB_MAX[ (hard coded)
uint32_t total_received_bits[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_errors[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_errors_last[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_received[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_received_last[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_fer[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_SI_received[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_SI_errors[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_ra_received[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_ra_errors[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_p_received[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_p_errors[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mch_received_sf[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mch_received[NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mcch_received[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mtch_received[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mcch_errors[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mtch_errors[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mcch_trials[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int dlsch_mtch_trials[MAX_MBSFN_AREA][NUMBER_OF_CONNECTED_eNB_MAX];
int current_dlsch_cqi[NUMBER_OF_CONNECTED_eNB_MAX];
unsigned char first_run_timing_advance[NUMBER_OF_CONNECTED_eNB_MAX];
uint8_t generate_prach;
uint8_t prach_cnt;
uint8_t prach_PreambleIndex;
// uint8_t prach_timer;
uint8_t decode_SIB;
uint8_t decode_MIB;
int rx_offset; /// Timing offset
int rx_offset_diff; /// Timing adjustment for ofdm symbol0 on HW USRP
int time_sync_cell;
int timing_advance; ///timing advance signalled from eNB
int hw_timing_advance;
int N_TA_offset; ///timing offset used in TDD
/// Flag to tell if UE is secondary user (cognitive mode)
unsigned char is_secondary_ue;
/// Flag to tell if secondary eNB has channel estimates to create NULL-beams from.
unsigned char has_valid_precoder;
/// hold the precoder for NULL beam to the primary eNB
int **ul_precoder_S_UE;
/// holds the maximum channel/precoder coefficient
char log2_maxp;
/// if ==0 enables phy only test mode
int mac_enabled;
/// Flag to initialize averaging of PHY measurements
int init_averaging;
/// \brief sinr for all subcarriers of the current link (used only for abstraction).
/// - first index: ? [0..12*N_RB_DL[
double *sinr_dB;
/// \brief sinr for all subcarriers of first symbol for the CQI Calculation.
/// - first index: ? [0..12*N_RB_DL[
double *sinr_CQI_dB;
/// sinr_effective used for CQI calulcation
double sinr_eff;
/// N0 (used for abstraction)
double N0;
/// PDSCH Varaibles
PDSCH_CONFIG_DEDICATED pdsch_config_dedicated[NUMBER_OF_CONNECTED_eNB_MAX];
/// PUSCH Varaibles
PUSCH_CONFIG_DEDICATED pusch_config_dedicated[NUMBER_OF_CONNECTED_eNB_MAX];
/// PUSCH contention-based access vars
PUSCH_CA_CONFIG_DEDICATED pusch_ca_config_dedicated[NUMBER_OF_eNB_MAX]; // lola
/// PUCCH variables
PUCCH_CONFIG_DEDICATED pucch_config_dedicated[NUMBER_OF_CONNECTED_eNB_MAX];
uint8_t ncs_cell[20][7];
/// UL-POWER-Control
UL_POWER_CONTROL_DEDICATED ul_power_control_dedicated[NUMBER_OF_CONNECTED_eNB_MAX];
/// TPC
TPC_PDCCH_CONFIG tpc_pdcch_config_pucch[NUMBER_OF_CONNECTED_eNB_MAX];
TPC_PDCCH_CONFIG tpc_pdcch_config_pusch[NUMBER_OF_CONNECTED_eNB_MAX];
/// CQI reporting
CQI_REPORT_CONFIG cqi_report_config[NUMBER_OF_CONNECTED_eNB_MAX];
/// SRS Variables
SOUNDINGRS_UL_CONFIG_DEDICATED soundingrs_ul_config_dedicated[NUMBER_OF_CONNECTED_eNB_MAX];
/// Scheduling Request Config
SCHEDULING_REQUEST_CONFIG scheduling_request_config[NUMBER_OF_CONNECTED_eNB_MAX];
/// Transmission mode per eNB
uint8_t transmission_mode[NUMBER_OF_CONNECTED_eNB_MAX];
time_stats_t phy_proc[RX_NB_TH];
time_stats_t phy_proc_tx;
time_stats_t phy_proc_rx[RX_NB_TH];
uint32_t use_ia_receiver;
time_stats_t ofdm_mod_stats;
time_stats_t ulsch_encoding_stats;
time_stats_t ulsch_modulation_stats;
time_stats_t ulsch_segmentation_stats;
time_stats_t ulsch_rate_matching_stats;
time_stats_t ulsch_turbo_encoding_stats;
time_stats_t ulsch_interleaving_stats;
time_stats_t ulsch_multiplexing_stats;
time_stats_t generic_stat;
time_stats_t generic_stat_bis[RX_NB_TH][LTE_SLOTS_PER_SUBFRAME];
time_stats_t ue_front_end_stat[RX_NB_TH];
time_stats_t ue_front_end_per_slot_stat[RX_NB_TH][LTE_SLOTS_PER_SUBFRAME];
time_stats_t pdcch_procedures_stat[RX_NB_TH];
time_stats_t pdsch_procedures_stat[RX_NB_TH];
time_stats_t pdsch_procedures_per_slot_stat[RX_NB_TH][LTE_SLOTS_PER_SUBFRAME];
time_stats_t dlsch_procedures_stat[RX_NB_TH];
time_stats_t ofdm_demod_stats;
time_stats_t dlsch_rx_pdcch_stats;
time_stats_t rx_dft_stats;
time_stats_t dlsch_channel_estimation_stats;
time_stats_t dlsch_freq_offset_estimation_stats;
time_stats_t dlsch_decoding_stats[2];
time_stats_t dlsch_demodulation_stats;
time_stats_t dlsch_rate_unmatching_stats;
time_stats_t dlsch_turbo_decoding_stats;
time_stats_t dlsch_deinterleaving_stats;
time_stats_t dlsch_llr_stats;
time_stats_t dlsch_llr_stats_parallelization[RX_NB_TH][LTE_SLOTS_PER_SUBFRAME];
time_stats_t dlsch_unscrambling_stats;
time_stats_t dlsch_rate_matching_stats;
time_stats_t dlsch_turbo_encoding_stats;
time_stats_t dlsch_interleaving_stats;
time_stats_t dlsch_tc_init_stats;
time_stats_t dlsch_tc_alpha_stats;
time_stats_t dlsch_tc_beta_stats;
time_stats_t dlsch_tc_gamma_stats;
time_stats_t dlsch_tc_ext_stats;
time_stats_t dlsch_tc_intl1_stats;
time_stats_t dlsch_tc_intl2_stats;
time_stats_t tx_prach;
/// RF and Interface devices per CC
openair0_device rfdevice;
} PHY_VARS_UE;
/* this structure is used to pass both UE phy vars and
* proc to the function UE_thread_rxn_txnp4
*/
struct rx_tx_thread_data {
PHY_VARS_UE *UE;
UE_rxtx_proc_t *proc;
};
void exit_fun(const char* s);
#include "UTIL/LOG/log_extern.h"
extern pthread_cond_t sync_cond;
extern pthread_mutex_t sync_mutex;
extern int sync_var;
#define MODE_DECODE_NONE 0
#define MODE_DECODE_SSE 1
#define MODE_DECODE_C 2
#define MODE_DECODE_AVX2 3
#define DECODE_INITTD8_SSE_FPTRIDX 0
#define DECODE_INITTD16_SSE_FPTRIDX 1
#define DECODE_INITTD_AVX2_FPTRIDX 2
#define DECODE_TD8_SSE_FPTRIDX 3
#define DECODE_TD16_SSE_FPTRIDX 4
#define DECODE_TD_C_FPTRIDX 5
#define DECODE_TD16_AVX2_FPTRIDX 6
#define DECODE_FREETD8_FPTRIDX 7
#define DECODE_FREETD16_FPTRIDX 8
#define DECODE_FREETD_AVX2_FPTRIDX 9
#define ENCODE_SSE_FPTRIDX 10
#define ENCODE_C_FPTRIDX 11
#define ENCODE_INIT_SSE_FPTRIDX 12
#define DECODE_NUM_FPTR 13
typedef uint8_t(*decoder_if_t)(int16_t *y,
int16_t *y2,
uint8_t *decoded_bytes,
uint8_t *decoded_bytes2,
uint16_t n,
uint16_t f1,
uint16_t f2,
uint8_t max_iterations,
uint8_t crc_type,
uint8_t F,
time_stats_t *init_stats,
time_stats_t *alpha_stats,
time_stats_t *beta_stats,
time_stats_t *gamma_stats,
time_stats_t *ext_stats,
time_stats_t *intl1_stats,
time_stats_t *intl2_stats);
typedef uint8_t(*encoder_if_t)(uint8_t *input,
uint16_t input_length_bytes,
uint8_t *output,
uint8_t F,
uint16_t interleaver_f1,
uint16_t interleaver_f2);
#define MAX_RRU_CONFIG_SIZE 1024
typedef enum {
RAU_tick=0,
RRU_capabilities=1,
RRU_config=2,
RRU_MSG_max_num=3,
RRU_config_ok=4,
RRU_start=5,
RRU_stop=6,
RRU_sync_ok=7,
RRU_frame_resynch=8
} rru_config_msg_type_t;
typedef struct RRU_CONFIG_msg_s {
rru_config_msg_type_t type;
ssize_t len;
uint8_t msg[MAX_RRU_CONFIG_SIZE];
} RRU_CONFIG_msg_t;
typedef enum {
OAI_IF5_only =0,
OAI_IF4p5_only =1,
OAI_IF5_and_IF4p5 =2,
MBP_IF5 =3,
MAX_FH_FMTs =4
} FH_fmt_options_t;
#define MAX_BANDS_PER_RRU 4
typedef struct RRU_capabilities_s {
/// Fronthaul format
FH_fmt_options_t FH_fmt;
/// number of EUTRA bands (<=4) supported by RRU
uint8_t num_bands;
/// EUTRA band list supported by RRU
uint8_t band_list[MAX_BANDS_PER_RRU];
/// Number of concurrent bands (component carriers)
uint8_t num_concurrent_bands;
/// Maximum TX EPRE of each band
int8_t max_pdschReferenceSignalPower[MAX_BANDS_PER_RRU];
/// Maximum RX gain of each band
uint8_t max_rxgain[MAX_BANDS_PER_RRU];
/// Number of RX ports of each band
uint8_t nb_rx[MAX_BANDS_PER_RRU];
/// Number of TX ports of each band
uint8_t nb_tx[MAX_BANDS_PER_RRU];
/// max DL bandwidth (1,6,15,25,50,75,100)
uint8_t N_RB_DL[MAX_BANDS_PER_RRU];
/// max UL bandwidth (1,6,15,25,50,75,100)
uint8_t N_RB_UL[MAX_BANDS_PER_RRU];
} RRU_capabilities_t;
typedef struct RRU_config_s {
/// Fronthaul format
RU_if_south_t FH_fmt;
/// number of EUTRA bands (<=4) configured in RRU
uint8_t num_bands;
/// EUTRA band list configured in RRU
uint8_t band_list[MAX_BANDS_PER_RRU];
/// TDD configuration (0-6)
uint8_t tdd_config[MAX_BANDS_PER_RRU];
/// TDD special subframe configuration (0-10)
uint8_t tdd_config_S[MAX_BANDS_PER_RRU];
/// TX frequency
uint32_t tx_freq[MAX_BANDS_PER_RRU];
/// RX frequency
uint32_t rx_freq[MAX_BANDS_PER_RRU];
/// TX attenation w.r.t. max
uint8_t att_tx[MAX_BANDS_PER_RRU];
/// RX attenuation w.r.t. max
uint8_t att_rx[MAX_BANDS_PER_RRU];
/// DL bandwidth
uint8_t N_RB_DL[MAX_BANDS_PER_RRU];
/// UL bandwidth
uint8_t N_RB_UL[MAX_BANDS_PER_RRU];
/// 3/4 sampling rate
uint8_t threequarter_fs[MAX_BANDS_PER_RRU];
/// prach_FreqOffset for IF4p5
int prach_FreqOffset[MAX_BANDS_PER_RRU];
/// prach_ConfigIndex for IF4p5
int prach_ConfigIndex[MAX_BANDS_PER_RRU];
int emtc_prach_CElevel_enable[MAX_BANDS_PER_RRU][4];
/// emtc_prach_FreqOffset for IF4p5 per CE Level
int emtc_prach_FreqOffset[MAX_BANDS_PER_RRU][4];
/// emtc_prach_ConfigIndex for IF4p5 per CE Level
int emtc_prach_ConfigIndex[MAX_BANDS_PER_RRU][4];
#endif
} RRU_config_t;
static inline void wait_sync(char *thread_name) {
printf( "waiting for sync (%s)\n",thread_name);
pthread_mutex_lock( &sync_mutex );
while (sync_var<0)
pthread_cond_wait( &sync_cond, &sync_mutex );
pthread_mutex_unlock(&sync_mutex);
printf( "got sync (%s)\n", thread_name);
}
static inline int wait_on_condition(pthread_mutex_t *mutex,pthread_cond_t *cond,int *instance_cnt,char *name) {
if (pthread_mutex_lock(mutex) != 0) {
LOG_E( PHY, "[SCHED][eNB] error locking mutex for %s\n",name);
exit_fun("nothing to add");
return(-1);
}
while (*instance_cnt < 0) {
// most of the time the thread is waiting here
// proc->instance_cnt_rxtx is -1
LOG_I(PHY,"Waiting (instance_cnt %d thread : %s)\n",*instance_cnt,name);
AssertFatal(0==pthread_cond_wait(cond,mutex),""); // this unlocks mutex_rxtx while waiting and then locks it again
LOG_I(PHY,"Waking up (instance_cnt %d thread: %s)\n",*instance_cnt,name);
}
if (pthread_mutex_unlock(mutex) != 0) {
LOG_E(PHY,"[SCHED][eNB] error unlocking mutex for %s\n",name);
exit_fun("nothing to add");
return(-1);
}
return(0);
}
static inline int wait_on_busy_condition(pthread_mutex_t *mutex,pthread_cond_t *cond,int *instance_cnt,char *name) {
if (pthread_mutex_lock(mutex) != 0) {
LOG_E( PHY, "[SCHED][eNB] error locking mutex for %s\n",name);
exit_fun("nothing to add");
return(-1);
}
while (*instance_cnt == 0) {
// most of the time the thread will skip this
// waits only if proc->instance_cnt_rxtx is 0
pthread_cond_wait(cond,mutex); // this unlocks mutex_rxtx while waiting and then locks it again
}
if (pthread_mutex_unlock(mutex) != 0) {
LOG_E(PHY,"[SCHED][eNB] error unlocking mutex for %s\n",name);
exit_fun("nothing to add");
return(-1);
}
return(0);
}
static inline int release_thread(pthread_mutex_t *mutex,int *instance_cnt,char *name) {
if (pthread_mutex_lock(mutex) != 0) {
LOG_E( PHY, "[SCHED][eNB] error locking mutex for %s\n",name);
exit_fun("nothing to add");
return(-1);
}
*instance_cnt=*instance_cnt-1;
if (pthread_mutex_unlock(mutex) != 0) {
LOG_E( PHY, "[SCHED][eNB] error unlocking mutex for %s\n",name);
exit_fun("nothing to add");
return(-1);
}
return(0);
}
#include "PHY/INIT/defs.h"
#include "PHY/LTE_REFSIG/defs.h"
#include "PHY/MODULATION/defs.h"
#include "PHY/LTE_TRANSPORT/proto.h"
#include "PHY/LTE_ESTIMATION/defs.h"
#include "SIMULATION/ETH_TRANSPORT/defs.h"
#endif // __PHY_DEFS__H__
=======
#endif /* __PHY_DEFS_ENB__H__ */
>>>>>>> enhancement-rfsim:openair1/PHY/defs_eNB.h
......@@ -96,8 +96,7 @@ void handle_nfapi_hi_dci0_dci_pdu(PHY_VARS_eNB *eNB,int frame,int subframe,eNB_r
void handle_nfapi_hi_dci0_hi_pdu(PHY_VARS_eNB *eNB,int frame,int subframe,eNB_rxtx_proc_t *proc,
nfapi_hi_dci0_request_pdu_t *hi_dci0_config_pdu)
{
LTE_eNB_PHICH *phich = &eNB->phich_vars;
int i;
LTE_eNB_PHICH *phich = &eNB->phich_vars[subframe&1];
// copy dci configuration in to eNB structure
LOG_D(PHY,"Received HI PDU with value %d (rbstart %d,cshift %d)\n",
......@@ -105,15 +104,9 @@ void handle_nfapi_hi_dci0_hi_pdu(PHY_VARS_eNB *eNB,int frame,int subframe,eNB_rx
hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.resource_block_start,
hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.cyclic_shift_2_for_drms);
// DJP - TODO FIXME - transmission power ignored
for (i=0;i<32;i++) if (phich->config[i].active==0) break;
AssertFatal(i<32,"no free PHICH allocation\n");
phich->config[i].active = 0;
phich->config[i].absSF = (frame*10)+subframe;
phich->config[i].hi = hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.hi_value;
phich->config[i].first_rb = hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.resource_block_start;
phich->config[i].n_DMRS = hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.cyclic_shift_2_for_drms;
phich->config[phich->num_hi].hi = hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.hi_value;
phich->config[phich->num_hi].first_rb = hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.resource_block_start;
phich->config[phich->num_hi].n_DMRS = hi_dci0_config_pdu->hi_pdu.hi_pdu_rel8.cyclic_shift_2_for_drms;
}
void handle_nfapi_bch_pdu(PHY_VARS_eNB *eNB,eNB_rxtx_proc_t *proc,
......
......@@ -62,7 +62,7 @@ sim_t sim;
void init_ru_devices(void);
void init_RU(const char*);
void init_RU(const char*,clock_source_t clock_source,clock_source_t time_source,int send_dmrssync);
void *rfsim_top(void *n_frames);
void wait_RUs(void)
......@@ -107,7 +107,7 @@ void RCConfig_sim(void) {
printf("returned with %d rus\n",RC.nb_RU);
init_RU(NULL);
init_RU(NULL,internal,internal,0);
printf("Waiting for RUs to get set up\n");
wait_RUs();
......
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