PHY_VARS_UE* init_lte_UE(LTE_DL_FRAME_PARMS *frame_parms, uint8_t UE_id, uint8_t abstraction_flag, uint8_t transmission_mode) { int i,j; PHY_VARS_UE* PHY_vars_UE = malloc(sizeof(PHY_VARS_UE)); memset(PHY_vars_UE,0,sizeof(PHY_VARS_UE)); PHY_vars_UE->Mod_id=UE_id; memcpy(&(PHY_vars_UE->lte_frame_parms), frame_parms, sizeof(LTE_DL_FRAME_PARMS)); phy_init_lte_ue(PHY_vars_UE,1,abstraction_flag); for (i=0; i<NUMBER_OF_CONNECTED_eNB_MAX; i++) { for (j=0; j<2; j++) { PHY_vars_UE->dlsch_ue[i][j] = new_ue_dlsch(1,NUMBER_OF_HARQ_PID_MAX,MAX_TURBO_ITERATIONS,frame_parms->N_RB_DL, abstraction_flag); if (!PHY_vars_UE->dlsch_ue[i][j]) { LOG_E(PHY,"Can't get ue dlsch structures\n"); exit(-1); } else LOG_D(PHY,"dlsch_ue[%d][%d] => %p\n",UE_id,i,PHY_vars_UE->dlsch_ue[i][j]); } PHY_vars_UE->ulsch_ue[i] = new_ue_ulsch(NUMBER_OF_HARQ_PID_MAX,frame_parms->N_RB_UL, abstraction_flag); if (!PHY_vars_UE->ulsch_ue[i]) { LOG_E(PHY,"Can't get ue ulsch structures\n"); exit(-1); } PHY_vars_UE->dlsch_ue_SI[i] = new_ue_dlsch(1,1,MAX_TURBO_ITERATIONS,frame_parms->N_RB_DL, abstraction_flag); PHY_vars_UE->dlsch_ue_ra[i] = new_ue_dlsch(1,1,MAX_TURBO_ITERATIONS,frame_parms->N_RB_DL, abstraction_flag); PHY_vars_UE->transmission_mode[i] = transmission_mode; } PHY_vars_UE->lte_frame_parms.pucch_config_common.deltaPUCCH_Shift = 1; PHY_vars_UE->dlsch_ue_MCH[0] = new_ue_dlsch(1,NUMBER_OF_HARQ_PID_MAX,MAX_TURBO_ITERATIONS_MBSFN,frame_parms->N_RB_DL,0); return (PHY_vars_UE); }
PHY_VARS_RN* init_lte_RN(LTE_DL_FRAME_PARMS *frame_parms, uint8_t RN_id, uint8_t eMBMS_active_state) { int i; PHY_VARS_RN* PHY_vars_RN = malloc(sizeof(PHY_VARS_RN)); memset(PHY_vars_RN,0,sizeof(PHY_VARS_RN)); PHY_vars_RN->Mod_id=RN_id; if (eMBMS_active_state == multicast_relay) { for (i=0; i < 10 ; i++){ // num SF in a frame PHY_vars_RN->dlsch_rn_MCH[i] = new_ue_dlsch(1,1,MAX_TURBO_ITERATIONS_MBSFN,frame_parms->N_RB_DL, 0); LOG_D(PHY,"eNB %d : MCH[%d] %p\n",RN_id,i,PHY_vars_RN->dlsch_rn_MCH[i]); } } else { PHY_vars_RN->dlsch_rn_MCH[0] = new_ue_dlsch(1,1,MAX_TURBO_ITERATIONS,frame_parms->N_RB_DL, 0); LOG_D(PHY,"eNB %d : MCH[0] %p\n",RN_id,PHY_vars_RN->dlsch_rn_MCH[0]); } return (PHY_vars_RN); }
int main(int argc, char *argv[]) { int ret,ret2; unsigned int errors,uerrors,errors2,crc_misses,iterations,trials,trials2,block_length,errors3,trials3; double SNR,sigma,rate=.5; unsigned char qbits,mcs; char done0=0; char done1=1; char done2=1; unsigned int coded_bits; unsigned char NB_RB=25; int num_pdcch_symbols = 1; int subframe = 6; randominit(0); logInit(); lte_param_init(1,1,1,0,0,3); PHY_vars_eNB->dlsch_eNB[0][0] = new_eNB_dlsch(1,8,NB_RB,0); PHY_vars_UE->dlsch_ue[0][0] = new_ue_dlsch(1,8,4,NB_RB,0); PHY_vars_eNB->dlsch_eNB[0][1] = new_eNB_dlsch(1,8,NB_RB,0); PHY_vars_UE->dlsch_ue[0][1] = new_ue_dlsch(1,8,4,NB_RB,0); if (argc>1) mcs = atoi(argv[1]); else mcs = 0; printf("NB_RB %d\n",NB_RB); DLSCH_alloc_pdu.rah = 0; DLSCH_alloc_pdu.rballoc = DLSCH_RB_ALLOC; DLSCH_alloc_pdu.TPC = 0; DLSCH_alloc_pdu.dai = 0; DLSCH_alloc_pdu.harq_pid = 0; //DLSCH_alloc_pdu2.tb_swap = 0; DLSCH_alloc_pdu.mcs = mcs; DLSCH_alloc_pdu.ndi = 1; DLSCH_alloc_pdu.rv = 0; if (argc>2) qbits = atoi(argv[2]); else qbits = 4; printf("Quantization bits %d\n",qbits); generate_eNB_dlsch_params_from_dci(subframe, &DLSCH_alloc_pdu, 0x1234, format1, PHY_vars_eNB->dlsch_eNB[0], &PHY_vars_eNB->lte_frame_parms, PHY_vars_eNB->pdsch_config_dedicated, SI_RNTI, 0, P_RNTI, 0); //change this later generate_ue_dlsch_params_from_dci(subframe, &DLSCH_alloc_pdu, C_RNTI, format1, PHY_vars_UE->dlsch_ue[0], &PHY_vars_UE->lte_frame_parms, PHY_vars_UE->pdsch_config_dedicated, SI_RNTI, 0, P_RNTI); coded_bits = get_G(&PHY_vars_eNB->lte_frame_parms, PHY_vars_eNB->dlsch_eNB[0][0]->harq_processes[0]->nb_rb, PHY_vars_eNB->dlsch_eNB[0][0]->harq_processes[0]->rb_alloc, get_Qm(mcs), 1, num_pdcch_symbols, 0, subframe); printf("Coded_bits (G) = %d\n",coded_bits); block_length = dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1]>>3; printf("Block_length = %d bytes (%d bits, rate %f), mcs %d, I_TBS %d, F %d, NB_RB %d\n",block_length, dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1],(double)dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1]/coded_bits, mcs,get_I_TBS(mcs),PHY_vars_eNB->dlsch_eNB[0][0]->harq_processes[0]->F,NB_RB); for (SNR=-5; SNR<15; SNR+=.1) { sigma = pow(10.0,-.05*SNR); printf("\n\nSNR %f dB => sigma %f\n",SNR,sigma); errors=0; crc_misses=0; errors2=0; errors3=0; iterations=0; if (done0 == 0) { ret = test_logmap8(PHY_vars_eNB->dlsch_eNB[0][0], PHY_vars_UE->dlsch_ue[0][0], coded_bits, NB_RB, sigma, // noise standard deviation qbits, block_length, // block length bytes NTRIALS, &errors, &trials, &uerrors, &crc_misses, &iterations, num_pdcch_symbols, subframe); if (ret>=0) printf("%f,%f,%f,%f\n",SNR,(double)errors/trials,(double)crc_misses/trials,(double)iterations/trials); if (((double)errors/trials) < 1e-2) done0=1; } if ((done0==1) && (done1==1) && (done2==1)) { printf("done\n"); break; } } return(0); }
void configure(int argc, char **argv, int trials, short* iqr, short* iqi, int mmcs, int nrx, int num_bss){ mcs = mmcs; /**************************************************************************/ char c; int i, j,u; double snr0=-2.0,snr1,rate; double input_snr_step=.2,snr_int=30; double forgetting_factor=0.0; //in [0,1] 0 means a new channel every time, 1 means keep the same channel uint8_t extended_prefix_flag=0; int eNB_id = 0; int chMod = 0 ; int UE_id = 0; unsigned char l; int **txdata; unsigned char awgn_flag = 0 ; SCM_t channel_model=Rice1; unsigned int coded_bits_per_codeword,nsymb; uint8_t transmission_mode=1,n_tx=1; n_rx = nrx; FILE *input_fdUL=NULL; short input_val_str, input_val_str2; int n_frames=1000; int n_ch_rlz = 1; int abstx = 0; channel_desc_t *UE2eNB; int delay = 0; double maxDoppler = 0.0; uint8_t srs_flag = 0; uint8_t N_RB_DL=50,osf=1; uint8_t beta_ACK=0,beta_RI=0,beta_CQI=2; uint8_t tdd_config=3,frame_type=FDD; uint8_t N0=30; double tx_gain=1.0; double cpu_freq_GHz; int s; int dump_perf=0; int test_perf=0; int dump_table =0; double effective_rate=0.0; char channel_model_input[10]; uint8_t max_turbo_iterations=4; int nb_rb_set = 0; int sf; /***************************************************************************/ logInit(); while ((c = getopt (argc, argv, "hapZbm:n:Y:X:x:s:w:e:q:d:D:O:c:r:i:f:y:c:oA:C:R:g:N:l:S:T:QB:PI:L")) != -1) { switch (c) { case 'a': channel_model = AWGN; chMod = 1; break; case 'b': bundling_flag = 0; break; case 'd': delay = atoi(optarg); break; case 'D': maxDoppler = atoi(optarg); break; case 'm': mcs = atoi(optarg); break; case 'n': n_frames = atoi(optarg); break; case 'Y': n_ch_rlz = atoi(optarg); break; case 'X': abstx= atoi(optarg); break; case 'g': sprintf(channel_model_input,optarg,10); switch((char)*optarg) { case 'A': channel_model=SCM_A; chMod = 2; break; case 'B': channel_model=SCM_B; chMod = 3; break; case 'C': channel_model=SCM_C; chMod = 4; break; case 'D': channel_model=SCM_D; chMod = 5; break; case 'E': channel_model=EPA; chMod = 6; break; case 'F': channel_model=EVA; chMod = 7; break; case 'G': channel_model=ETU; chMod = 8; break; case 'H': channel_model=Rayleigh8; chMod = 9; break; case 'I': channel_model=Rayleigh1; chMod = 10; break; case 'J': channel_model=Rayleigh1_corr; chMod = 11; break; case 'K': channel_model=Rayleigh1_anticorr; chMod = 12; break; case 'L': channel_model=Rice8; chMod = 13; break; case 'M': channel_model=Rice1; chMod = 14; break; case 'N': channel_model=AWGN; chMod = 1; break; default: msg("Unsupported channel model!\n"); exit(-1); break; } break; case 's': snr0 = atof(optarg); break; case 'w': snr_int = atof(optarg); break; case 'e': input_snr_step= atof(optarg); break; case 'x': transmission_mode=atoi(optarg); if ((transmission_mode!=1) && (transmission_mode!=2)) { msg("Unsupported transmission mode %d\n",transmission_mode); exit(-1); } if (transmission_mode>1) { n_tx = 1; } break; case 'y': n_rx = atoi(optarg); break; case 'S': subframe = atoi(optarg); break; case 'T': tdd_config=atoi(optarg); frame_type=TDD; break; case 'p': extended_prefix_flag=1; break; case 'r': nb_rb = atoi(optarg); nb_rb_set = 1; break; case 'f': first_rb = atoi(optarg); break; case 'c': cyclic_shift = atoi(optarg); break; case 'N': N0 = atoi(optarg); break; case 'o': srs_flag = 1; break; case 'i': input_fdUL = fopen(optarg,"r"); printf("Reading in %s (%p)\n",optarg,input_fdUL); if (input_fdUL == (FILE*)NULL) { printf("Unknown file %s\n",optarg); exit(-1); } // input_file=1; break; case 'A': beta_ACK = atoi(optarg); if (beta_ACK>15) { printf("beta_ack must be in (0..15)\n"); exit(-1); } break; case 'C': beta_CQI = atoi(optarg); if ((beta_CQI>15)||(beta_CQI<2)) { printf("beta_cqi must be in (2..15)\n"); exit(-1); } break; case 'R': beta_RI = atoi(optarg); if ((beta_RI>15)||(beta_RI<2)) { printf("beta_ri must be in (0..13)\n"); exit(-1); } break; case 'Q': cqi_flag=1; break; case 'B': N_RB_DL=atoi(optarg); break; case 'P': dump_perf=1; opp_enabled=1; break; case 'O': test_perf=atoi(optarg); //print_perf =1; break; case 'L': llr8_flag=1; break; case 'I': max_turbo_iterations=atoi(optarg); break; case 'Z': dump_table = 1; break; case 'h': default: printf("%s -h(elp) -a(wgn on) -m mcs -n n_frames -s snr0 -t delay_spread -p (extended prefix on) -r nb_rb -f first_rb -c cyclic_shift -o (srs on) -g channel_model [A:M] Use 3GPP 25.814 SCM-A/B/C/D('A','B','C','D') or 36-101 EPA('E'), EVA ('F'),ETU('G') models (ignores delay spread and Ricean factor), Rayghleigh8 ('H'), Rayleigh1('I'), Rayleigh1_corr('J'), Rayleigh1_anticorr ('K'), Rice8('L'), Rice1('M'), -d Channel delay, -D maximum Doppler shift \n", argv[0]); exit(1); break; } } lte_param_init(1,n_rx,1,extended_prefix_flag,N_RB_DL,frame_type,tdd_config,osf, num_bss); int loop = 0; for (loop = 0; loop < num_bss; loop++){ if (nb_rb_set == 0){ nb_rb = PHY_vars_eNB[loop]->lte_frame_parms.N_RB_UL; } // frame_parms = &PHY_vars_eNB[loop]->lte_frame_parms; txdata = PHY_vars_UE[loop]->lte_ue_common_vars.txdata; nsymb = (PHY_vars_eNB[loop]->lte_frame_parms.Ncp == 0) ? 14 : 12; coded_bits_per_codeword = nb_rb * (12 * get_Qm(mcs)) * nsymb; rate = (double)2*dlsch_tbs25[get_I_TBS(mcs)][25-1]/(coded_bits_per_codeword); PHY_vars_UE[loop]->lte_ue_pdcch_vars[0]->crnti = 14; PHY_vars_UE[loop]->lte_frame_parms.soundingrs_ul_config_common.srs_BandwidthConfig = 2; PHY_vars_UE[loop]->lte_frame_parms.soundingrs_ul_config_common.srs_SubframeConfig = 7; PHY_vars_UE[loop]->soundingrs_ul_config_dedicated[eNB_id].srs_Bandwidth = 0; PHY_vars_UE[loop]->soundingrs_ul_config_dedicated[eNB_id].transmissionComb = 0; PHY_vars_UE[loop]->soundingrs_ul_config_dedicated[eNB_id].freqDomainPosition = 0; PHY_vars_eNB[loop]->lte_frame_parms.soundingrs_ul_config_common.srs_BandwidthConfig = 2; PHY_vars_eNB[loop]->lte_frame_parms.soundingrs_ul_config_common.srs_SubframeConfig = 7; PHY_vars_eNB[loop]->soundingrs_ul_config_dedicated[UE_id].srs_ConfigIndex = 1; PHY_vars_eNB[loop]->soundingrs_ul_config_dedicated[UE_id].srs_Bandwidth = 0; PHY_vars_eNB[loop]->soundingrs_ul_config_dedicated[UE_id].transmissionComb = 0; PHY_vars_eNB[loop]->soundingrs_ul_config_dedicated[UE_id].freqDomainPosition = 0; PHY_vars_eNB[loop]->cooperation_flag = cooperation_flag; // PHY_vars_eNB[loop]->eNB_UE_stats[0].SRS_parameters = PHY_vars_UE[loop]->SRS_parameters; PHY_vars_eNB[loop]->pusch_config_dedicated[UE_id].betaOffset_ACK_Index = beta_ACK; PHY_vars_eNB[loop]->pusch_config_dedicated[UE_id].betaOffset_RI_Index = beta_RI; PHY_vars_eNB[loop]->pusch_config_dedicated[UE_id].betaOffset_CQI_Index = beta_CQI; PHY_vars_UE[loop]->pusch_config_dedicated[eNB_id].betaOffset_ACK_Index = beta_ACK; PHY_vars_UE[loop]->pusch_config_dedicated[eNB_id].betaOffset_RI_Index = beta_RI; PHY_vars_UE[loop]->pusch_config_dedicated[eNB_id].betaOffset_CQI_Index = beta_CQI; PHY_vars_UE[loop]->ul_power_control_dedicated[eNB_id].deltaMCS_Enabled = 1; UE2eNB = new_channel_desc_scm(PHY_vars_eNB[loop]->lte_frame_parms.nb_antennas_tx, PHY_vars_UE[loop]->lte_frame_parms.nb_antennas_rx, channel_model, BW, forgetting_factor, delay, 0); // set Doppler UE2eNB->max_Doppler = maxDoppler; // NN: N_RB_UL has to be defined in ulsim PHY_vars_eNB[loop]->ulsch_eNB[0] = new_eNB_ulsch(8,max_turbo_iterations,N_RB_DL,0); PHY_vars_UE[loop]->ulsch_ue[0] = new_ue_ulsch(8,N_RB_DL,0); // Create transport channel structures for 2 transport blocks (MIMO) for (i=0; i<2; i++) { PHY_vars_eNB[loop]->dlsch_eNB[0][i] = new_eNB_dlsch(1,8,N_RB_DL,0); PHY_vars_UE[loop]->dlsch_ue[0][i] = new_ue_dlsch(1,8,MAX_TURBO_ITERATIONS,N_RB_DL,0); if (!PHY_vars_eNB[loop]->dlsch_eNB[0][i]) { printf("Can't get eNB dlsch structures\n"); exit(-1); } if (!PHY_vars_UE[loop]->dlsch_ue[0][i]) { printf("Can't get ue dlsch structures\n"); exit(-1); } PHY_vars_eNB[loop]->dlsch_eNB[0][i]->rnti = 14; PHY_vars_UE[loop]->dlsch_ue[0][i]->rnti = 14; } switch (PHY_vars_eNB[loop]->lte_frame_parms.N_RB_UL) { case 6: break; case 50: if (PHY_vars_eNB[loop]->lte_frame_parms.frame_type == TDD) { ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->type = 0; ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->rballoc = computeRIV(PHY_vars_eNB[loop]->lte_frame_parms.N_RB_UL,first_rb,nb_rb);// 12 RBs from position 8 printf("nb_rb %d/%d, rballoc %d (dci %x)\n",nb_rb,PHY_vars_eNB[loop]->lte_frame_parms.N_RB_UL,((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->rballoc,*(uint32_t *)&UL_alloc_pdu); ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->mcs = mcs; ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->ndi = 1; ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->TPC = 0; ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->cqi_req = cqi_flag&1; ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->cshift = 0; ((DCI0_10MHz_TDD_1_6_t*)&UL_alloc_pdu)->dai = 1; } else { ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->type = 0; ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->rballoc = computeRIV(PHY_vars_eNB[loop]->lte_frame_parms.N_RB_UL,first_rb,nb_rb);// 12 RBs from position 8 printf("nb_rb %d/%d, rballoc %d (dci %x)\n",nb_rb,PHY_vars_eNB[loop]->lte_frame_parms.N_RB_UL,((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->rballoc,*(uint32_t *)&UL_alloc_pdu); ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->mcs = mcs; ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->ndi = 1; ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->TPC = 0; ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->cqi_req = cqi_flag&1; ((DCI0_10MHz_FDD_t*)&UL_alloc_pdu)->cshift = 0; } break; default: break; } PHY_vars_UE[loop]->PHY_measurements.rank[0] = 0; PHY_vars_UE[loop]->transmission_mode[0] = 2; PHY_vars_UE[loop]->pucch_config_dedicated[0].tdd_AckNackFeedbackMode = bundling_flag == 1 ? bundling : multiplexing; PHY_vars_eNB[loop]->transmission_mode[0] = 2; PHY_vars_eNB[loop]->pucch_config_dedicated[0].tdd_AckNackFeedbackMode = bundling_flag == 1 ? bundling : multiplexing; PHY_vars_UE[loop]->lte_frame_parms.pusch_config_common.ul_ReferenceSignalsPUSCH.groupHoppingEnabled = 1; PHY_vars_eNB[loop]->lte_frame_parms.pusch_config_common.ul_ReferenceSignalsPUSCH.groupHoppingEnabled = 1; PHY_vars_UE[loop]->lte_frame_parms.pusch_config_common.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled = 0; PHY_vars_eNB[loop]->lte_frame_parms.pusch_config_common.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled = 0; PHY_vars_UE[loop]->lte_frame_parms.pusch_config_common.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH = 0; PHY_vars_eNB[loop]->lte_frame_parms.pusch_config_common.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH = 0; PHY_vars_UE[loop]->frame_tx=1; for (sf=0; sf<10; sf++) { PHY_vars_eNB[loop]->proc[sf].frame_tx=1; PHY_vars_eNB[loop]->proc[sf].subframe_tx=sf; PHY_vars_eNB[loop]->proc[sf].frame_rx=1; PHY_vars_eNB[loop]->proc[sf].subframe_rx=sf; } msg("Init UL hopping UE\n"); init_ul_hopping(&PHY_vars_UE[loop]->lte_frame_parms); msg("Init UL hopping eNB\n"); init_ul_hopping(&PHY_vars_eNB[loop]->lte_frame_parms); PHY_vars_eNB[loop]->proc[subframe].frame_rx = PHY_vars_UE[loop]->frame_tx; if (ul_subframe2pdcch_alloc_subframe(&PHY_vars_eNB[loop]->lte_frame_parms,subframe) > subframe) // allocation was in previous frame PHY_vars_eNB[loop]->proc[ul_subframe2pdcch_alloc_subframe(&PHY_vars_eNB[loop]->lte_frame_parms,subframe)].frame_tx = (PHY_vars_UE[loop]->frame_tx-1)&1023; PHY_vars_UE[loop]->dlsch_ue[0][0]->harq_ack[ul_subframe2pdcch_alloc_subframe(&PHY_vars_eNB[loop]->lte_frame_parms,subframe)].send_harq_status = 1; PHY_vars_UE[loop]->frame_tx = (PHY_vars_UE[loop]->frame_tx-1)&1023; printf("**********************here=1**************************\n"); generate_ue_ulsch_params_from_dci((void *)&UL_alloc_pdu, 14, ul_subframe2pdcch_alloc_subframe(&PHY_vars_UE[loop]->lte_frame_parms,subframe), format0, PHY_vars_UE[loop], SI_RNTI, 0, P_RNTI, CBA_RNTI, 0, srs_flag); if (PHY_vars_eNB[loop]->ulsch_eNB[0] != NULL) generate_eNB_ulsch_params_from_dci((void *)&UL_alloc_pdu, 14, ul_subframe2pdcch_alloc_subframe(&PHY_vars_eNB[loop]->lte_frame_parms,subframe), format0, 0, PHY_vars_eNB[loop], SI_RNTI, 0, P_RNTI, CBA_RNTI, srs_flag); PHY_vars_UE[loop]->frame_tx = (PHY_vars_UE[loop]->frame_tx+1)&1023; printf("**********************here=2**************************\n"); int round = 0; harq_pid = subframe2harq_pid(&PHY_vars_UE[loop]->lte_frame_parms,PHY_vars_UE[loop]->frame_tx,subframe); // fflush(stdout); PHY_vars_eNB[loop]->ulsch_eNB[0]->harq_processes[harq_pid]->round=round; PHY_vars_UE[loop]->ulsch_ue[0]->harq_processes[harq_pid]->round=round; PHY_vars_eNB[loop]->ulsch_eNB[0]->harq_processes[harq_pid]->rvidx = round>>1; PHY_vars_UE[loop]->ulsch_ue[0]->harq_processes[harq_pid]->rvidx = round>>1; ///////////////////// int aa = 0; int ii=0; for(ii=0; ii< PHY_vars_eNB[loop]->lte_frame_parms.samples_per_tti; ii++){ for (aa=0; aa < n_rx; aa++){ ((short*) &PHY_vars_eNB[loop]->lte_eNB_common_vars.rxdata[0][aa][PHY_vars_eNB[loop]->lte_frame_parms.samples_per_tti*subframe])[2*ii] = iqr[ii]; ((short*) &PHY_vars_eNB[loop]->lte_eNB_common_vars.rxdata[0][aa][PHY_vars_eNB[loop]->lte_frame_parms.samples_per_tti*subframe])[2*ii +1] = iqi[ii]; } } printf("Loaded %d IQ samples\n", PHY_vars_eNB[loop]->lte_frame_parms.samples_per_tti); lte_eNB_I0_measurements(PHY_vars_eNB[loop], 0, 1); PHY_vars_eNB[loop]->ulsch_eNB[0]->cyclicShift = cyclic_shift;// cyclic shift for DMRS remove_7_5_kHz(PHY_vars_eNB[loop],subframe<<1); remove_7_5_kHz(PHY_vars_eNB[loop],1+(subframe<<1)); } }
int main(int argc, char *argv[]) { int ret,ret2; unsigned int errors,uerrors,errors2,crc_misses,iterations,trials,trials2,block_length,errors3,trials3; double SNR,sigma,rate=.5; unsigned char qbits,mcs; char done0=0; char done1=1; char done2=1; unsigned short iind; unsigned int coded_bits; unsigned char NB_RB=25; int num_pdcch_symbols = 3; int subframe = 6; randominit(0); logInit(); lte_param_init(1,1,1,0,0,3); PHY_vars_eNB->dlsch_eNB[0][0] = new_eNB_dlsch(1,8,0); PHY_vars_UE->dlsch_ue[0][0] = new_ue_dlsch(1,8,0); PHY_vars_eNB->dlsch_eNB[0][1] = new_eNB_dlsch(1,8,0); PHY_vars_UE->dlsch_ue[0][1] = new_ue_dlsch(1,8,0); if (argc>1) mcs = atoi(argv[1]); else mcs = 0; printf("NB_RB %d\n",NB_RB); DLSCH_alloc_pdu2.rah = 0; DLSCH_alloc_pdu2.rballoc = DLSCH_RB_ALLOC; DLSCH_alloc_pdu2.TPC = 0; DLSCH_alloc_pdu2.dai = 0; DLSCH_alloc_pdu2.harq_pid = 0; DLSCH_alloc_pdu2.tb_swap = 0; DLSCH_alloc_pdu2.mcs1 = mcs; DLSCH_alloc_pdu2.ndi1 = 1; DLSCH_alloc_pdu2.rv1 = 0; if (argc>2) qbits = atoi(argv[2]); else qbits = 4; printf("Quantization bits %d\n",qbits); generate_eNB_dlsch_params_from_dci(subframe, &DLSCH_alloc_pdu2, 0x1234, format2_2A_M10PRB, PHY_vars_eNB->dlsch_eNB[0], &PHY_vars_eNB->lte_frame_parms, SI_RNTI, 0, P_RNTI, 0); //change this later generate_ue_dlsch_params_from_dci(subframe, &DLSCH_alloc_pdu2, C_RNTI, format2_2A_M10PRB, PHY_vars_UE->dlsch_ue[0], &PHY_vars_UE->lte_frame_parms, SI_RNTI, 0, P_RNTI); coded_bits = get_G(&PHY_vars_eNB->lte_frame_parms,NB_RB,PHY_vars_eNB->dlsch_eNB[0][0]->rb_alloc, get_Qm(mcs),num_pdcch_symbols,subframe); printf("Coded_bits (G) = %d\n",coded_bits); block_length = dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1]>>3; printf("Block_length = %d bytes (%d bits, rate %f), mcs %d, I_TBS %d, NB_RB %d\n",block_length, dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1],(double)dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1]/coded_bits, mcs,get_I_TBS(mcs),NB_RB); // Test Openair0 3GPP encoder /* test_encoder(block_length, f1f2mat[(block_length-5)*2], // f1 (see 36121-820, page 14) f1f2mat[((block_length-5)*2)+1], // f2 (see 36121-820, page 14) 3); */ // exit(0); for (SNR=-6;SNR<16;SNR+=.5) { // printf("\n\nSNR %f dB\n",SNR); sigma = pow(10.0,-.05*SNR); errors=0; crc_misses=0; errors2=0; errors3=0; iterations=0; if (done0 == 0) { ret = test_logmap8(PHY_vars_eNB->dlsch_eNB[0][0], PHY_vars_UE->dlsch_ue[0][0], coded_bits, NB_RB, sigma, // noise standard deviation qbits, block_length, // block length bytes NTRIALS, &errors, &trials, &uerrors, &crc_misses, &iterations, num_pdcch_symbols, subframe); if (ret>=0) // printf("ref: Errors %d (%f), Uerrors %d (%f), CRC Misses %d (%f), Avg iterations %f\n",errors,(double)errors/trials,uerrors,(double)uerrors/trials,crc_misses,(double)crc_misses/trials,(double)iterations/trials); printf("%f,%f,%f,%f\n",SNR,(double)errors/trials,(double)crc_misses/trials,(double)iterations/trials); if (((double)errors/trials) < 1e-2) done0=1; } /* if (done1 == 0) { printf("exmimo\n"); ret = test_logmapexmimo(rate, // code rate sigma, // noise standard deviation qbits, block_length, // block length bytes f1f2mat[iind*2], // f1 (see 36121-820, page 14) f1f2mat[(iind*2)+1], // f2 (see 36121-820, page 14) 3, NTRIALS, &errors3, &trials3); if (ret>=0) printf("exmimo : Errors %d (%f)\n",errors3,(double)errors3/trials3); if (((double)errors3/trials3) < 1e-3) done1=1; } if (done2 == 0) { printf("Viterbi ...\n"); ret2 = test_viterbi(sigma, 8*block_length, NTRIALS, &errors2, &trials2, rate); if (ret2>=0) printf("viterbi : Errors %d (%f)\n",errors2,(double)errors2/trials2); if (((double)errors2/trials2) < 1e-3) done2=1; } */ if ((done0==1) && (done1==1) && (done2==1)) { printf("done\n"); break; } } return(0); }
int main(int argc, char **argv) { char c; int i,aa,s,ind,Kr,Kr_bytes;; double sigma2, sigma2_dB=10,SNR,snr0=-2.0,snr1,SNRmeas; //int **txdataF, **txdata; int **txdata; #ifdef IFFT_FPGA int **txdataF2; #endif //LTE_DL_FRAME_PARMS *frame_parms = (LTE_DL_FRAME_PARMS *)malloc(sizeof(LTE_DL_FRAME_PARMS)); //LTE_UE_COMMON *lte_ue_common_vars = (LTE_UE_COMMON *)malloc(sizeof(LTE_UE_COMMON)); double **s_re,**s_im,**r_re,**r_im; double amps[8] = {0.3868472 , 0.3094778 , 0.1547389 , 0.0773694 , 0.0386847 , 0.0193424 , 0.0096712 , 0.0038685}; double aoa=.03,ricean_factor=1; //0.0000005; int channel_length; struct complex **ch; int eNb_id = 0, eNb_id_i = 1; unsigned char mcs,dual_stream_UE = 0; unsigned short NB_RB=conv_nprb(0,DLSCH_RB_ALLOC); unsigned char Ns,l,m; unsigned char *input_data,*decoded_output; unsigned char *input_buffer; unsigned short input_buffer_length; unsigned int ret; unsigned int coded_bits_per_codeword,nsymb,dci_cnt; unsigned int tx_lev,tx_lev_dB,trials,errs=0,dci_errors=0,dlsch_active=0,num_layers; int re_allocated; FILE *bler_fd; FILE *csv_fd; char bler_fname[20]; char csv_fname[20]; unsigned char pbch_pdu[6]; DCI_ALLOC_t dci_alloc[8],dci_alloc_rx[8]; FILE *rx_frame_file; int result; int n_frames; int cnt=0; int rx_lev_data_sym; int rx_lev_null_sym; int rx_snr_dB; void *data; int ii; int bler; double blerr; int ch_realization; channel_length = (int) 11+2*BW*Td; lte_param_init(1,1,1); num_layers = 1; //int cont=0; // default parameters //for (cont =0;cont<29;cont++){ mcs = 0; n_frames = 1000; snr0 = 2; //if(snr0>0) // snr0 = 0; while ((c = getopt (argc, argv, "hm:n:s:")) != -1) { switch (c) { case 'h': printf("%s -h(elp) -m mcs -n n_frames -s snr0\n",argv[0]); exit(1); case 'm': mcs = atoi(optarg); break; case 'n': n_frames = atoi(optarg); break; case 's': snr0 = atoi(optarg); break; default: printf("%s -h(elp) -m mcs -n n_frames -s snr0\n",argv[0]); exit (-1); break; } } printf("Setting mcs = %d\n",mcs); printf("NPRB = %d\n",NB_RB); printf("n_frames = %d\n",n_frames); /* snr0 = -7 + mcs; if(snr0>0) snr0 = ; */ snr1 = snr0+20; printf("SNR0 %f, SNR1 %f\n",snr0,snr1); /* txdataF = (int **)malloc16(2*sizeof(int*)); txdataF[0] = (int *)malloc16(FRAME_LENGTH_BYTES); txdataF[1] = (int *)malloc16(FRAME_LENGTH_BYTES); txdata = (int **)malloc16(2*sizeof(int*)); txdata[0] = (int *)malloc16(FRAME_LENGTH_BYTES); txdata[1] = (int *)malloc16(FRAME_LENGTH_BYTES); */ #ifdef IFFT_FPGA txdata = (int **)malloc16(2*sizeof(int*)); txdata[0] = (int *)malloc16(FRAME_LENGTH_BYTES); txdata[1] = (int *)malloc16(FRAME_LENGTH_BYTES); bzero(txdata[0],FRAME_LENGTH_BYTES); bzero(txdata[1],FRAME_LENGTH_BYTES); txdataF2 = (int **)malloc16(2*sizeof(int*)); txdataF2[0] = (int *)malloc16(FRAME_LENGTH_BYTES_NO_PREFIX); txdataF2[1] = (int *)malloc16(FRAME_LENGTH_BYTES_NO_PREFIX); bzero(txdataF2[0],FRAME_LENGTH_BYTES_NO_PREFIX); bzero(txdataF2[1],FRAME_LENGTH_BYTES_NO_PREFIX); #else txdata = PHY_vars_eNb->lte_eNB_common_vars.txdata[eNb_id]; #endif s_re = malloc(2*sizeof(double*)); s_im = malloc(2*sizeof(double*)); r_re = malloc(2*sizeof(double*)); r_im = malloc(2*sizeof(double*)); nsymb = (lte_frame_parms->Ncp == 0) ? 14 : 12; coded_bits_per_codeword = NB_RB * (12 * get_Qm(mcs)) * (lte_frame_parms->num_dlsch_symbols); printf("Rate = %f (mod %d)\n",(((double)dlsch_tbs25[get_I_TBS(mcs)][NB_RB-1])*3/4)/coded_bits_per_codeword, get_Qm(mcs)); sprintf(bler_fname,"bler_%d.m",mcs); bler_fd = fopen(bler_fname,"w"); fprintf(bler_fd,"bler = ["); // CSV file sprintf(csv_fname,"data_out%d.m",mcs); csv_fd = fopen(csv_fname,"w"); fprintf(csv_fd,"data_all=["); for (i=0;i<2;i++) { s_re[i] = malloc(FRAME_LENGTH_COMPLEX_SAMPLES*sizeof(double)); s_im[i] = malloc(FRAME_LENGTH_COMPLEX_SAMPLES*sizeof(double)); r_re[i] = malloc(FRAME_LENGTH_COMPLEX_SAMPLES*sizeof(double)); r_im[i] = malloc(FRAME_LENGTH_COMPLEX_SAMPLES*sizeof(double)); } PHY_vars_UE->lte_ue_pdcch_vars[0]->crnti = 0x1234; // Fill in UL_alloc UL_alloc_pdu.type = 0; UL_alloc_pdu.hopping = 0; UL_alloc_pdu.rballoc = UL_RB_ALLOC; UL_alloc_pdu.mcs = 1; UL_alloc_pdu.ndi = 1; UL_alloc_pdu.TPC = 0; UL_alloc_pdu.cqi_req = 1; CCCH_alloc_pdu.type = 0; CCCH_alloc_pdu.vrb_type = 0; CCCH_alloc_pdu.rballoc = CCCH_RB_ALLOC; CCCH_alloc_pdu.ndi = 1; CCCH_alloc_pdu.mcs = 1; CCCH_alloc_pdu.harq_pid = 0; DLSCH_alloc_pdu2.rah = 0; DLSCH_alloc_pdu2.rballoc = DLSCH_RB_ALLOC; DLSCH_alloc_pdu2.TPC = 0; DLSCH_alloc_pdu2.dai = 0; DLSCH_alloc_pdu2.harq_pid = 0; DLSCH_alloc_pdu2.tb_swap = 0; DLSCH_alloc_pdu2.mcs1 = mcs; DLSCH_alloc_pdu2.ndi1 = 1; DLSCH_alloc_pdu2.rv1 = 0; // Forget second codeword DLSCH_alloc_pdu2.tpmi = 5 ; // precoding // Create transport channel structures for SI pdus PHY_vars_eNb->dlsch_eNb_cntl = new_eNb_dlsch(1,1); PHY_vars_UE->dlsch_ue_cntl = new_ue_dlsch(1,1); // Create transport channel structures for 2 transport blocks (MIMO) PHY_vars_eNb->dlsch_eNb = (LTE_eNb_DLSCH_t**) malloc16(2*sizeof(LTE_eNb_DLSCH_t*)); PHY_vars_UE->dlsch_ue = (LTE_UE_DLSCH_t**) malloc16(2*sizeof(LTE_UE_DLSCH_t*)); for (i=0;i<2;i++) { PHY_vars_eNb->dlsch_eNb[i] = new_eNb_dlsch(1,8); PHY_vars_UE->dlsch_ue[i] = new_ue_dlsch(1,8); if (!PHY_vars_eNb->dlsch_eNb[i]) { printf("Can't get eNb dlsch structures\n"); exit(-1); } if (!PHY_vars_UE->dlsch_ue[i]) { printf("Can't get ue dlsch structures\n"); exit(-1); } } if (DLSCH_alloc_pdu2.tpmi == 5) { PHY_vars_eNb->dlsch_eNb[0]->pmi_alloc = (unsigned short)(taus()&0xffff); PHY_vars_UE->dlsch_ue[0]->pmi_alloc = PHY_vars_eNb->dlsch_eNb[0]->pmi_alloc; PHY_vars_eNb->eNB_UE_stats[0].DL_pmi_single[0] = PHY_vars_eNb->dlsch_eNb[0]->pmi_alloc; } generate_eNb_dlsch_params_from_dci(0, &DLSCH_alloc_pdu2, 0x1234, format2_2A_M10PRB, PHY_vars_eNb->dlsch_eNb, lte_frame_parms, SI_RNTI, RA_RNTI, P_RNTI, 0); //change this later /* generate_eNb_dlsch_params_from_dci(0, &CCCH_alloc_pdu, SI_RNTI, format1A, &dlsch_eNb_cntl, lte_frame_parms, SI_RNTI, RA_RNTI, P_RNTI); */ // input_data = (unsigned char*) malloc(block_length/8); // decoded_output = (unsigned char*) malloc(block_length/8); // DCI memcpy(&dci_alloc[0].dci_pdu[0],&DLSCH_alloc_pdu2,sizeof(DCI2_5MHz_2A_M10PRB_TDD_t)); dci_alloc[0].dci_length = sizeof_DCI2_5MHz_2A_M10PRB_TDD_t; dci_alloc[0].L = 3; dci_alloc[0].rnti = 0x1234; /* memcpy(&dci_alloc[0].dci_pdu[0],&CCCH_alloc_pdu,sizeof(DCI1A_5MHz_TDD_1_6_t)); dci_alloc[0].dci_length = sizeof_DCI1A_5MHz_TDD_1_6_t; dci_alloc[0].L = 3; dci_alloc[0].rnti = SI_RNTI; */ memcpy(&dci_alloc[1].dci_pdu[0],&UL_alloc_pdu,sizeof(DCI0_5MHz_TDD0_t)); dci_alloc[1].dci_length = sizeof_DCI0_5MHz_TDD_0_t; dci_alloc[1].L = 3; dci_alloc[1].rnti = 0x1234; // DLSCH if (1) { input_buffer_length = PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->TBS/8; printf("dlsch0: TBS %d\n",PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->TBS); printf("Input buffer size %d bytes\n",input_buffer_length); input_buffer = (unsigned char *)malloc(input_buffer_length+4); for (i=0;i<input_buffer_length;i++) input_buffer[i]= (unsigned char)(taus()&0xff); dlsch_encoding(input_buffer, lte_frame_parms, PHY_vars_eNb->dlsch_eNb[0]); #ifdef OUTPUT_DEBUG for (s=0;s<PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->C;s++) { if (s<PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->Cminus) Kr = PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->Kminus; else Kr = PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->Kplus; Kr_bytes = Kr>>3; for (i=0;i<Kr_bytes;i++) printf("%d : (%x)\n",i,PHY_vars_eNb->dlsch_eNb[0]->harq_processes[0]->c[s][i]); } #endif re_allocated = dlsch_modulation(PHY_vars_eNb->lte_eNB_common_vars.txdataF[eNb_id], 1024, 0, &PHY_vars_eNb->lte_frame_parms, PHY_vars_eNb->dlsch_eNb[0]); printf("RB count %d (%d,%d)\n",re_allocated,re_allocated/lte_frame_parms->num_dlsch_symbols/12,lte_frame_parms->num_dlsch_symbols); if (num_layers>1) re_allocated = dlsch_modulation(PHY_vars_eNb->lte_eNB_common_vars.txdataF[eNb_id], 1024, 0, &PHY_vars_eNb->lte_frame_parms, PHY_vars_eNb->dlsch_eNb[1]); }
void mexFunction( int mlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[] ) { /* Declare */ short *dlsch_llr; unsigned char mcs; unsigned int *ret; unsigned char mod_order; unsigned char num_pdcch_symbols; unsigned char harq_pid; unsigned char subframe; unsigned char Kmimo; unsigned char Mdlharq; unsigned char abstraction_flag; LTE_UE_DLSCH_t* dlsch; LTE_DL_FRAME_PARMS *frame_parms; PHY_VARS_UE *phy_vars_ue; extern int *pi2tab16[188],*pi5tab16[188],*pi4tab16[188],*pi6tab16[188]; unsigned long *ptr_td; //Specific Modification for 64bit int *tmp[1]; /* Allocate input */ dlsch_llr = (short*) mxGetData(prhs[0]); /* Create new dlsch */ Kmimo = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"Kmimo")); Mdlharq = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"Mdlharq")); abstraction_flag = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"abstraction_flag")); mcs = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"mcs")); #ifdef DEBUG_DLSCH_DECODING mexPrintf("Kmimo %d\n",Kmimo); mexPrintf("Mdlharq %d\n",Mdlharq); mexPrintf("abstraction_flag %d\n",abstraction_flag); mexPrintf("mcs %d\n",mcs); #endif /* Create new dlsch */ dlsch = new_ue_dlsch(Kmimo,Mdlharq,8,25,abstraction_flag); // Init CRC tables crcTableInit(); // init_td(); // copy the pointers to memory allocated in dlsch_decoding_init ptr_td = (unsigned int*) mxGetData(mxGetField(prhs[1],0,"ptr_td")); #ifdef DEBUG_DLSCH_DECODING mexPrintf("ptr_td0 %p\n",ptr_td[0]); mexPrintf("ptr_td1 %p\n",ptr_td[1]); mexPrintf("ptr_td2 %p\n",ptr_td[2]); mexPrintf("ptr_td3 %p\n",ptr_td[3]); #endif memcpy(&tmp[0], &ptr_td[0], sizeof(ptr_td[0])); memcpy(&pi2tab16[0], tmp[0], 188*sizeof(pi2tab16[0])); memcpy(&tmp[0], &ptr_td[1], sizeof(ptr_td[1])); memcpy(&pi4tab16[0], tmp[0], 188*sizeof(pi4tab16[0])); memcpy(&tmp[0], &ptr_td[2], sizeof(ptr_td[2])); memcpy(&pi5tab16[0], tmp[0], 188*sizeof(pi5tab16[0])); memcpy(&tmp[0], &ptr_td[3], sizeof(ptr_td[3])); memcpy(&pi6tab16[0], tmp[0], 188*sizeof(pi6tab16[0])); harq_pid = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"harq_pid")); dlsch->current_harq_pid = harq_pid; dlsch->harq_processes[harq_pid]->rvidx = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"rvidx")); dlsch->harq_processes[harq_pid]->Nl = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"Nl")); //dlsch->harq_processes[harq_pid]->Ndi = (unsigned char) mxGetScalar(mxGetField(prhs[2],0,"Ndi")); dlsch->harq_processes[harq_pid]->mcs = mcs; dlsch->harq_processes[harq_pid]->rb_alloc[0] = (unsigned int) mxGetScalar(mxGetField(prhs[1],0,"rb_alloc")); dlsch->harq_processes[harq_pid]->nb_rb = (unsigned short) mxGetScalar(mxGetField(prhs[1],0,"nb_rb")); dlsch->harq_processes[harq_pid]->TBS = dlsch_tbs25[get_I_TBS(mcs)][dlsch->harq_processes[harq_pid]->nb_rb-1]; num_pdcch_symbols = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"num_pdcch_symbols")); subframe = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"subframe")); phy_vars_ue = calloc(1,sizeof(PHY_VARS_UE)); // Create a LTE_DL_FRAME_PARMS structure and assign required params frame_parms = calloc(1,sizeof(LTE_DL_FRAME_PARMS)); frame_parms->N_RB_DL = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"nb_rb")); frame_parms->frame_type = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"frame_type")); frame_parms->mode1_flag = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"mode1_flag")); frame_parms->Ncp = (unsigned char) mxGetScalar(mxGetField(prhs[1],0,"Ncp")); mod_order = get_Qm(dlsch->harq_processes[harq_pid]->mcs); dlsch->harq_processes[harq_pid]->G = get_G(frame_parms,dlsch->harq_processes[harq_pid]->nb_rb,dlsch->harq_processes[harq_pid]->rb_alloc,mod_order,dlsch->harq_processes[harq_pid]->Nl,num_pdcch_symbols,0,subframe); #ifdef DEBUG_DLSCH_DECODING mexPrintf("TBS %d\n",dlsch->harq_processes[harq_pid]->TBS); mexPrintf("nb_rb %d\n",dlsch->harq_processes[harq_pid]->nb_rb); mexPrintf("ncs %d\n",dlsch->harq_processes[harq_pid]->mcs); mexPrintf("num_pdcch_symbols %d\n",num_pdcch_symbols); mexPrintf("subframe %d\n",subframe); mexPrintf("G %d\n",dlsch->harq_processes[harq_pid]->G); #endif if (dlsch->harq_processes[harq_pid]->G != mxGetM(prhs[0])) { free_ue_dlsch(dlsch); free(frame_parms); free(phy_vars_ue); mexErrMsgTxt("Length of the LLR vector is incorrect."); } /* Allocate Output */ plhs[0] = mxCreateNumericMatrix(1, 1, mxUINT32_CLASS, mxREAL); ret = (unsigned int*) mxGetPr(plhs[0]); /* Algo */ *ret = dlsch_decoding(phy_vars_ue, dlsch_llr, frame_parms, dlsch, dlsch->harq_processes[harq_pid], subframe, dlsch->current_harq_pid, 1,0); /* free dlsch */ free_ue_dlsch(dlsch); free(frame_parms); free(phy_vars_ue); // free_td(); }