/* * Licensed to the OpenAirInterface (OAI) Software Alliance under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The OpenAirInterface Software Alliance licenses this file to You under * the OAI Public License, Version 1.1 (the "License"); you may not use this file * except in compliance with the License. * You may obtain a copy of the License at * * http://www.openairinterface.org/?page_id=698 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. *------------------------------------------------------------------------------- * For more information about the OpenAirInterface (OAI) Software Alliance: * contact@openairinterface.org */ #include "executables/nr-softmodem-common.h" #include "PHY/defs_gNB.h" #include "PHY/phy_extern.h" #include "PHY/NR_REFSIG/nr_refsig.h" #include "PHY/INIT/phy_init.h" #include "PHY/CODING/nrPolar_tools/nr_polar_pbch_defs.h" #include "PHY/NR_TRANSPORT/nr_transport.h" /*#include "RadioResourceConfigCommonSIB.h" #include "RadioResourceConfigDedicated.h" #include "TDD-Config.h" #include "MBSFN-SubframeConfigList.h"*/ #include "openair1/PHY/defs_RU.h" #include "LAYER2/NR_MAC_gNB/mac_proto.h" #include "assertions.h" #include <math.h> #include "PHY/NR_TRANSPORT/nr_ulsch.h" #include "PHY/NR_REFSIG/nr_refsig.h" #include "SCHED_NR/fapi_nr_l1.h" #include "openair2/LAYER2/NR_MAC_gNB/mac_proto.h" #include "nfapi_nr_interface.h" /* extern uint32_t from_nrarfcn(int nr_bandP,uint32_t dl_nrarfcn); extern int32_t get_nr_uldl_offset(int nr_bandP);*/ extern openair0_config_t openair0_cfg[MAX_CARDS]; int l1_north_init_gNB() { if (RC.nb_nr_L1_inst > 0 && RC.nb_nr_L1_CC != NULL && RC.gNB != NULL) { AssertFatal(RC.nb_nr_L1_inst>0,"nb_nr_L1_inst=%d\n",RC.nb_nr_L1_inst); AssertFatal(RC.nb_nr_L1_CC!=NULL,"nb_nr_L1_CC is null\n"); AssertFatal(RC.gNB!=NULL,"RC.gNB is null\n"); LOG_I(PHY,"%s() RC.nb_nr_L1_inst:%d\n", __FUNCTION__, RC.nb_nr_L1_inst); for (int i=0; i<RC.nb_nr_L1_inst; i++) { AssertFatal(RC.gNB[i]!=NULL,"RC.gNB[%d] is null\n",i); AssertFatal(RC.nb_nr_L1_CC[i]>0,"RC.nb_nr_L1_CC[%d]=%d\n",i,RC.nb_nr_L1_CC[i]); LOG_I(PHY,"%s() RC.nb_nr_L1_CC[%d]:%d\n", __FUNCTION__, i, RC.nb_nr_L1_CC[i]); for (int j=0; j<RC.nb_nr_L1_CC[i]; j++) { AssertFatal(RC.gNB[i][j]!=NULL,"RC.gNB[%d][%d] is null\n",i,j); if ((RC.gNB[i][j]->if_inst = NR_IF_Module_init(i))<0) return(-1); LOG_I(PHY,"%s() RC.gNB[%d][%d] installing callbacks\n", __FUNCTION__, i, j); RC.gNB[i][j]->if_inst->NR_PHY_config_req = nr_phy_config_request; RC.gNB[i][j]->if_inst->NR_Schedule_response = nr_schedule_response; } } } else { LOG_I(PHY,"%s() Not installing PHY callbacks - RC.nb_nr_L1_inst:%d RC.nb_nr_L1_CC:%p RC.gNB:%p\n", __FUNCTION__, RC.nb_nr_L1_inst, RC.nb_nr_L1_CC, RC.gNB); } return(0); } int phy_init_nr_gNB(PHY_VARS_gNB *gNB, unsigned char is_secondary_gNB, unsigned char abstraction_flag) { // shortcuts NR_DL_FRAME_PARMS *const fp = &gNB->frame_parms; nfapi_nr_config_request_t *cfg = &gNB->gNB_config; NR_gNB_COMMON *const common_vars = &gNB->common_vars; NR_gNB_PUSCH **const pusch_vars = gNB->pusch_vars; /*LTE_eNB_SRS *const srs_vars = gNB->srs_vars; LTE_eNB_PRACH *const prach_vars = &gNB->prach_vars;*/ int i; LOG_I(PHY,"[gNB %d] %s() About to wait for gNB to be configured\n", gNB->Mod_id, __FUNCTION__); gNB->total_dlsch_bitrate = 0; gNB->total_transmitted_bits = 0; gNB->total_system_throughput = 0; gNB->check_for_MUMIMO_transmissions=0; while(gNB->configured == 0) usleep(10000); init_dfts(); /* LOG_I(PHY,"[gNB %"PRIu8"] Initializing DL_FRAME_PARMS : N_RB_DL %"PRIu8", PHICH Resource %d, PHICH Duration %d nb_antennas_tx:%u nb_antennas_rx:%u PRACH[rootSequenceIndex:%u prach_Config_enabled:%u configIndex:%u highSpeed:%u zeroCorrelationZoneConfig:%u freqOffset:%u]\n", gNB->Mod_id, fp->N_RB_DL,fp->phich_config_common.phich_resource, fp->phich_config_common.phich_duration, fp->nb_antennas_tx, fp->nb_antennas_rx, fp->prach_config_common.rootSequenceIndex, fp->prach_config_common.prach_Config_enabled, fp->prach_config_common.prach_ConfigInfo.prach_ConfigIndex, fp->prach_config_common.prach_ConfigInfo.highSpeedFlag, fp->prach_config_common.prach_ConfigInfo.zeroCorrelationZoneConfig, fp->prach_config_common.prach_ConfigInfo.prach_FreqOffset );*/ LOG_D(PHY,"[MSC_NEW][FRAME 00000][PHY_gNB][MOD %02"PRIu8"][]\n", gNB->Mod_id); crcTableInit(); init_dfts(); // PBCH DMRS gold sequences generation nr_init_pbch_dmrs(gNB); //PDCCH DMRS init gNB->nr_gold_pdcch_dmrs = (uint32_t ***)malloc16(fp->slots_per_frame*sizeof(uint32_t **)); uint32_t ***pdcch_dmrs = gNB->nr_gold_pdcch_dmrs; AssertFatal(pdcch_dmrs!=NULL, "NR init: pdcch_dmrs malloc failed\n"); for (int slot=0; slot<fp->slots_per_frame; slot++) { pdcch_dmrs[slot] = (uint32_t **)malloc16(fp->symbols_per_slot*sizeof(uint32_t *)); AssertFatal(pdcch_dmrs[slot]!=NULL, "NR init: pdcch_dmrs for slot %d - malloc failed\n", slot); for (int symb=0; symb<fp->symbols_per_slot; symb++) { pdcch_dmrs[slot][symb] = (uint32_t *)malloc16(NR_MAX_PDCCH_DMRS_INIT_LENGTH_DWORD*sizeof(uint32_t)); AssertFatal(pdcch_dmrs[slot][symb]!=NULL, "NR init: pdcch_dmrs for slot %d symbol %d - malloc failed\n", slot, symb); } } nr_init_pdcch_dmrs(gNB, cfg->sch_config.physical_cell_id.value); nr_init_pbch_interleaver(gNB->nr_pbch_interleaver); //PDSCH DMRS init gNB->nr_gold_pdsch_dmrs = (uint32_t ****)malloc16(fp->slots_per_frame*sizeof(uint32_t ***)); uint32_t ****pdsch_dmrs = gNB->nr_gold_pdsch_dmrs; for (int slot=0; slot<fp->slots_per_frame; slot++) { pdsch_dmrs[slot] = (uint32_t ***)malloc16(fp->symbols_per_slot*sizeof(uint32_t **)); AssertFatal(pdsch_dmrs[slot]!=NULL, "NR init: pdsch_dmrs for slot %d - malloc failed\n", slot); for (int symb=0; symb<fp->symbols_per_slot; symb++) { pdsch_dmrs[slot][symb] = (uint32_t **)malloc16(NR_MAX_NB_CODEWORDS*sizeof(uint32_t *)); AssertFatal(pdsch_dmrs[slot][symb]!=NULL, "NR init: pdsch_dmrs for slot %d symbol %d - malloc failed\n", slot, symb); for (int q=0; q<NR_MAX_NB_CODEWORDS; q++) { pdsch_dmrs[slot][symb][q] = (uint32_t *)malloc16(NR_MAX_PDSCH_DMRS_INIT_LENGTH_DWORD*sizeof(uint32_t)); AssertFatal(pdsch_dmrs[slot][symb][q]!=NULL, "NR init: pdsch_dmrs for slot %d symbol %d codeword %d - malloc failed\n", slot, symb, q); } } } //------------- config PUSCH DMRS parameters(to be updated from RRC)--------------// gNB->dmrs_UplinkConfig.pusch_dmrs_type = pusch_dmrs_type1; gNB->dmrs_UplinkConfig.pusch_dmrs_AdditionalPosition = pusch_dmrs_pos0; gNB->dmrs_UplinkConfig.pusch_maxLength = pusch_len1; //--------------------------------------------------------------------------------// nr_init_pdsch_dmrs(gNB, cfg->sch_config.physical_cell_id.value); // default values until overwritten by RRCConnectionReconfiguration for (i=0;i<MAX_NR_OF_UL_ALLOCATIONS;i++){ gNB->pusch_config.pusch_TimeDomainResourceAllocation[i] = (PUSCH_TimeDomainResourceAllocation_t *)malloc16(sizeof(PUSCH_TimeDomainResourceAllocation_t)); gNB->pusch_config.pusch_TimeDomainResourceAllocation[i]->mappingType = typeB; } /// Transport init necessary for NR synchro init_nr_transport(gNB); gNB->first_run_I0_measurements = 1; ///This flag used to be static. With multiple gNBs this does no longer work, hence we put it in the structure. However it has to be initialized with 1, which is performed here. common_vars->rxdata = (int32_t **)malloc16(15*sizeof(int32_t*)); common_vars->txdataF = (int32_t **)malloc16(15*sizeof(int32_t*)); common_vars->rxdataF = (int32_t **)malloc16(15*sizeof(int32_t*)); for (i=0;i<15;i++){ common_vars->txdataF[i] = (int32_t*)malloc16_clear(fp->samples_per_frame_wCP*sizeof(int32_t)); // [hna] samples_per_frame without CP common_vars->rxdataF[i] = (int32_t*)malloc16_clear(fp->samples_per_frame_wCP*sizeof(int32_t)); common_vars->rxdata[i] = (int32_t*)malloc16_clear(fp->samples_per_frame*sizeof(int32_t)); LOG_D(PHY,"[INIT] common_vars->txdataF[%d] = %p (%lu bytes)\n", i,common_vars->txdataF[i], fp->samples_per_frame_wCP*sizeof(int32_t)); } // Channel estimates for SRS /* for (UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) { srs_vars[UE_id].srs_ch_estimates = (int32_t **)malloc16( 64*sizeof(int32_t *) ); srs_vars[UE_id].srs_ch_estimates_time = (int32_t **)malloc16( 64*sizeof(int32_t *) ); for (i=0; i<64; i++) { srs_vars[UE_id].srs_ch_estimates[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*fp->ofdm_symbol_size ); srs_vars[UE_id].srs_ch_estimates_time[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*fp->ofdm_symbol_size*2 ); } } //UE_id */ /*generate_ul_ref_sigs_rx(); init_ulsch_power_LUT();*/ /* // SRS for (UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) { srs_vars[UE_id].srs = (int32_t *)malloc16_clear(2*fp->ofdm_symbol_size*sizeof(int32_t)); } // PRACH prach_vars->prachF = (int16_t *)malloc16_clear( 1024*2*sizeof(int16_t) ); // assume maximum of 64 RX antennas for PRACH receiver prach_vars->prach_ifft[0] = (int32_t **)malloc16_clear(64*sizeof(int32_t *)); for (i=0; i<64; i++) prach_vars->prach_ifft[0][i] = (int32_t *)malloc16_clear(1024*2*sizeof(int32_t)); prach_vars->rxsigF[0] = (int16_t **)malloc16_clear(64*sizeof(int16_t *)); */ for (int UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) { //FIXME pusch_vars[UE_id] = (NR_gNB_PUSCH *)malloc16_clear( sizeof(NR_gNB_PUSCH) ); pusch_vars[UE_id]->rxdataF_ext = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->rxdataF_ext2 = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_estimates = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_estimates_ext = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_estimates_time = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->rxdataF_comp = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_mag0 = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_magb0 = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_mag = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->ul_ch_magb = (int32_t **)malloc16( fp->nb_antennas_rx*sizeof(int32_t *) ); pusch_vars[UE_id]->rho = (int32_t **)malloc16_clear( fp->nb_antennas_rx*sizeof(int32_t*) ); for (i=0; i<fp->nb_antennas_rx; i++) { // RK 2 times because of output format of FFT! // FIXME We should get rid of this pusch_vars[UE_id]->rxdataF_ext[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12*fp->symbols_per_slot ); pusch_vars[UE_id]->rxdataF_ext2[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12*fp->symbols_per_slot ); pusch_vars[UE_id]->ul_ch_estimates[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12*fp->symbols_per_slot ); pusch_vars[UE_id]->ul_ch_estimates_ext[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12*fp->symbols_per_slot ); pusch_vars[UE_id]->ul_ch_estimates_time[i] = (int32_t *)malloc16_clear( 2*sizeof(int32_t)*fp->ofdm_symbol_size ); pusch_vars[UE_id]->rxdataF_comp[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12*fp->symbols_per_slot ); pusch_vars[UE_id]->ul_ch_mag0[i] = (int32_t *)malloc16_clear( fp->symbols_per_slot*sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12 ); pusch_vars[UE_id]->ul_ch_magb0[i] = (int32_t *)malloc16_clear( fp->symbols_per_slot*sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12 ); pusch_vars[UE_id]->ul_ch_mag[i] = (int32_t *)malloc16_clear( fp->symbols_per_slot*sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12 ); pusch_vars[UE_id]->ul_ch_magb[i] = (int32_t *)malloc16_clear( fp->symbols_per_slot*sizeof(int32_t)*cfg->rf_config.ul_carrier_bandwidth.value*12 ); pusch_vars[UE_id]->rho[i] = (int32_t *)malloc16_clear( sizeof(int32_t)*(fp->N_RB_UL*12*7*2) ); } pusch_vars[UE_id]->llr = (int16_t *)malloc16_clear( (8*((3*8*6144)+12))*sizeof(int16_t) ); // [hna] 6144 is LTE and (8*((3*8*6144)+12)) is not clear } //UE_id /* for (UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) gNB->UE_stats_ptr[UE_id] = &gNB->UE_stats[UE_id]; */ gNB->pdsch_config_dedicated->p_a = dB0; //defaul value until overwritten by RRCConnectionReconfiguration return (0); } /* void phy_config_request(PHY_Config_t *phy_config) { uint8_t Mod_id = phy_config->Mod_id; int CC_id = phy_config->CC_id; nfapi_nr_config_request_t *cfg = phy_config->cfg; NR_DL_FRAME_PARMS *fp; PHICH_RESOURCE_t phich_resource_table[4]={oneSixth,half,one,two}; int eutra_band = cfg->nfapi_config.rf_bands.rf_band[0]; int dl_Bandwidth = cfg->rf_config.dl_carrier_bandwidth.value; int ul_Bandwidth = cfg->rf_config.ul_carrier_bandwidth.value; int Nid_cell = cfg->sch_config.physical_cell_id.value; int Ncp = cfg->subframe_config.dl_cyclic_prefix_type.value; int p_eNB = cfg->rf_config.tx_antenna_ports.value; uint32_t dl_CarrierFreq = cfg->nfapi_config.earfcn.value; LOG_I(PHY,"Configuring MIB for instance %d, CCid %d : (band %d,N_RB_DL %d, N_RB_UL %d, Nid_cell %d,gNB_tx_antenna_ports %d,Ncp %d,DL freq %u)\n", Mod_id, CC_id, eutra_band, dl_Bandwidth, ul_Bandwidth, Nid_cell, p_eNB,Ncp,dl_CarrierFreq ); AssertFatal(RC.gNB != NULL, "PHY instance pointer doesn't exist\n"); AssertFatal(RC.gNB[Mod_id] != NULL, "PHY instance %d doesn't exist\n",Mod_id); AssertFatal(RC.gNB[Mod_id][CC_id] != NULL, "PHY instance %d, CCid %d doesn't exist\n",Mod_id,CC_id); if (RC.gNB[Mod_id][CC_id]->configured == 1) { LOG_E(PHY,"Already eNB already configured, do nothing\n"); return; } RC.gNB[Mod_id][CC_id]->mac_enabled = 1; fp = &RC.gNB[Mod_id][CC_id]->frame_parms; fp->threequarter_fs = 0; nr_init_frame_parms(fp,1); RC.gNB[Mod_id][CC_id]->configured = 1; LOG_I(PHY,"gNB %d/%d configured\n",Mod_id,CC_id); }*/ void phy_free_nr_gNB(PHY_VARS_gNB *gNB) { //NR_DL_FRAME_PARMS* const fp = &gNB->frame_parms; //nfapi_nr_config_request_t *cfg = &gNB->gNB_config; NR_gNB_COMMON *const common_vars = &gNB->common_vars; NR_gNB_PUSCH **const pusch_vars = gNB->pusch_vars; /*LTE_eNB_SRS *const srs_vars = gNB->srs_vars; LTE_eNB_PRACH *const prach_vars = &gNB->prach_vars;*/ uint32_t ***pdcch_dmrs = gNB->nr_gold_pdcch_dmrs; for (int i = 0; i < 15; i++) { free_and_zero(common_vars->txdataF[i]); /* rxdataF[i] is not allocated -> don't free */ } free_and_zero(common_vars->txdataF); free_and_zero(common_vars->rxdataF); // PDCCH DMRS sequences free_and_zero(pdcch_dmrs); /* // Channel estimates for SRS for (UE_id = 0; UE_id < NUMBER_OF_UE_MAX; UE_id++) { for (i=0; i<64; i++) { free_and_zero(srs_vars[UE_id].srs_ch_estimates[i]); free_and_zero(srs_vars[UE_id].srs_ch_estimates_time[i]); } free_and_zero(srs_vars[UE_id].srs_ch_estimates); free_and_zero(srs_vars[UE_id].srs_ch_estimates_time); } //UE_id //free_ul_ref_sigs(); for (UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) free_and_zero(srs_vars[UE_id].srs); free_and_zero(prach_vars->prachF); for (i = 0; i < 64; i++) free_and_zero(prach_vars->prach_ifft[0][i]); free_and_zero(prach_vars->prach_ifft[0]); free_and_zero(prach_vars->rxsigF[0]); */ for (int UE_id=0; UE_id<NUMBER_OF_UE_MAX; UE_id++) { for (int i = 0; i < 2; i++) { free_and_zero(pusch_vars[UE_id]->rxdataF_ext[i]); free_and_zero(pusch_vars[UE_id]->rxdataF_ext2[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_estimates[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_estimates_ext[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_estimates_time[i]); free_and_zero(pusch_vars[UE_id]->rxdataF_comp[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_mag0[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_magb0[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_mag[i]); free_and_zero(pusch_vars[UE_id]->ul_ch_magb[i]); free_and_zero(pusch_vars[UE_id]->rho[i]); } free_and_zero(pusch_vars[UE_id]->rxdataF_ext); free_and_zero(pusch_vars[UE_id]->rxdataF_ext2); free_and_zero(pusch_vars[UE_id]->ul_ch_estimates); free_and_zero(pusch_vars[UE_id]->ul_ch_estimates_ext); free_and_zero(pusch_vars[UE_id]->ul_ch_estimates_time); free_and_zero(pusch_vars[UE_id]->rxdataF_comp); free_and_zero(pusch_vars[UE_id]->ul_ch_mag0); free_and_zero(pusch_vars[UE_id]->ul_ch_magb0); free_and_zero(pusch_vars[UE_id]->ul_ch_mag); free_and_zero(pusch_vars[UE_id]->ul_ch_magb); free_and_zero(pusch_vars[UE_id]->rho); free_and_zero(pusch_vars[UE_id]->llr); free_and_zero(pusch_vars[UE_id]); } //UE_id /* for (UE_id = 0; UE_id < NUMBER_OF_UE_MAX; UE_id++) gNB->UE_stats_ptr[UE_id] = NULL; */ } /* void install_schedule_handlers(IF_Module_t *if_inst) { if_inst->PHY_config_req = phy_config_request; if_inst->schedule_response = schedule_response; }*/ /// this function is a temporary addition for NR configuration void nr_phy_config_request_sim(PHY_VARS_gNB *gNB, int N_RB_DL, int N_RB_UL, int mu, int Nid_cell, uint64_t position_in_burst) { NR_DL_FRAME_PARMS *fp = &gNB->frame_parms; nfapi_nr_config_request_t *gNB_config = &gNB->gNB_config; //overwrite for new NR parameters gNB_config->nfapi_config.rf_bands.rf_band[0] = 78; gNB_config->nfapi_config.nrarfcn.value = 620000; gNB_config->subframe_config.numerology_index_mu.value = mu; gNB_config->subframe_config.duplex_mode.value = TDD; gNB_config->rf_config.dl_carrier_bandwidth.value = N_RB_DL; gNB_config->rf_config.ul_carrier_bandwidth.value = N_RB_UL; gNB_config->sch_config.half_frame_index.value = 0; gNB_config->sch_config.ssb_subcarrier_offset.value = 0; gNB_config->sch_config.n_ssb_crb.value = (N_RB_DL-20); gNB_config->sch_config.ssb_subcarrier_offset.value = 0; gNB_config->sch_config.physical_cell_id.value = Nid_cell; gNB_config->sch_config.ssb_scg_position_in_burst.value = position_in_burst; gNB_config->subframe_config.dl_cyclic_prefix_type.value = (fp->Ncp == NORMAL) ? NFAPI_CP_NORMAL : NFAPI_CP_EXTENDED; gNB->mac_enabled = 1; fp->dl_CarrierFreq = 3500000000;//from_nrarfcn(gNB_config->nfapi_config.rf_bands.rf_band[0],gNB_config->nfapi_config.nrarfcn.value); fp->ul_CarrierFreq = 3500000000;//fp->dl_CarrierFreq - (get_uldl_offset(gNB_config->nfapi_config.rf_bands.rf_band[0])*100000); fp->threequarter_fs= 0; nr_init_frame_parms(gNB_config, fp); gNB->configured = 1; LOG_I(PHY,"gNB configured\n"); } void nr_phy_config_request(NR_PHY_Config_t *phy_config) { uint8_t Mod_id = phy_config->Mod_id; int CC_id = phy_config->CC_id; NR_DL_FRAME_PARMS *fp = &RC.gNB[Mod_id][CC_id]->frame_parms; nfapi_nr_config_request_t *gNB_config = &RC.gNB[Mod_id][CC_id]->gNB_config; gNB_config->nfapi_config.rf_bands.rf_band[0] = phy_config->cfg->nfapi_config.rf_bands.rf_band[0]; //22 gNB_config->nfapi_config.nrarfcn.value = phy_config->cfg->nfapi_config.nrarfcn.value; //6600 gNB_config->subframe_config.numerology_index_mu.value = phy_config->cfg->subframe_config.numerology_index_mu.value;//1 gNB_config->rf_config.dl_carrier_bandwidth.value = phy_config->cfg->rf_config.dl_carrier_bandwidth.value;//106; gNB_config->rf_config.ul_carrier_bandwidth.value = phy_config->cfg->rf_config.ul_carrier_bandwidth.value;//106; gNB_config->sch_config.half_frame_index.value = 0; gNB_config->sch_config.ssb_subcarrier_offset.value = phy_config->cfg->sch_config.ssb_subcarrier_offset.value;//0; gNB_config->sch_config.n_ssb_crb.value = (phy_config->cfg->rf_config.dl_carrier_bandwidth.value-20); gNB_config->sch_config.physical_cell_id.value = phy_config->cfg->sch_config.physical_cell_id.value; gNB_config->sch_config.ssb_scg_position_in_burst.value= phy_config->cfg->sch_config.ssb_scg_position_in_burst.value; gNB_config->sch_config.ssb_periodicity.value = phy_config->cfg->sch_config.ssb_periodicity.value; if (phy_config->cfg->subframe_config.duplex_mode.value == 0) { gNB_config->subframe_config.duplex_mode.value = FDD; } else { gNB_config->subframe_config.duplex_mode.value = TDD; } RC.gNB[Mod_id][CC_id]->mac_enabled = 1; fp->dl_CarrierFreq = from_nrarfcn(gNB_config->nfapi_config.rf_bands.rf_band[0],gNB_config->nfapi_config.nrarfcn.value); get_band(fp->dl_CarrierFreq, &gNB_config->nfapi_config.rf_bands.rf_band[0], &uplink_frequency_offset[CC_id][0], &fp->frame_type); fp->ul_CarrierFreq = fp->dl_CarrierFreq + uplink_frequency_offset[CC_id][0]; fp->threequarter_fs = openair0_cfg[0].threequarter_fs; LOG_I(PHY,"Configuring MIB for instance %d, CCid %d : (band %d,N_RB_DL %d, N_RB_UL %d, Nid_cell %d,DL freq %u, UL freq %u)\n", Mod_id, CC_id, gNB_config->nfapi_config.rf_bands.rf_band[0], gNB_config->rf_config.dl_carrier_bandwidth.value, gNB_config->rf_config.ul_carrier_bandwidth.value, gNB_config->sch_config.physical_cell_id.value, fp->dl_CarrierFreq, fp->ul_CarrierFreq); nr_init_frame_parms(gNB_config, fp); if (RC.gNB[Mod_id][CC_id]->configured == 1) { LOG_E(PHY,"Already gNB already configured, do nothing\n"); return; } RC.gNB[Mod_id][CC_id]->configured = 1; LOG_I(PHY,"gNB %d/%d configured\n",Mod_id,CC_id); } void init_nr_transport(PHY_VARS_gNB *gNB) { int i; int j; NR_DL_FRAME_PARMS *fp = &gNB->frame_parms; nfapi_nr_config_request_t *cfg = &gNB->gNB_config; LOG_I(PHY, "Initialise nr transport\n"); for (i=0; i<NUMBER_OF_NR_DLSCH_MAX; i++) { LOG_I(PHY,"Allocating Transport Channel Buffers for DLSCH %d/%d\n",i,NUMBER_OF_NR_DLSCH_MAX); for (j=0; j<2; j++) { gNB->dlsch[i][j] = new_gNB_dlsch(1,16,NSOFT,0,fp,cfg); if (!gNB->dlsch[i][j]) { LOG_E(PHY,"Can't get gNB dlsch structures for UE %d \n", i); exit(-1); }/* else { gNB->dlsch[i][j]->rnti=0; LOG_D(PHY,"dlsch[%d][%d] => %p rnti:%d\n",i,j,gNB->dlsch[i][j], gNB->dlsch[i][j]->rnti); }*/ } } for (i=0; i<NUMBER_OF_NR_ULSCH_MAX; i++) { LOG_I(PHY,"Allocating Transport Channel Buffer for ULSCH, UE %d\n",i); for (j=0; j<2; j++) { // ULSCH for data gNB->ulsch[i][j] = new_gNB_ulsch(MAX_LDPC_ITERATIONS, fp->N_RB_UL, 0); if (!gNB->ulsch[i][j]) { LOG_E(PHY,"Can't get gNB ulsch structures\n"); exit(-1); } /* LOG_I(PHY,"Initializing nFAPI for ULSCH, UE %d\n",i); // [hna] added here for RT implementation uint8_t harq_pid = 0; nfapi_nr_ul_config_ulsch_pdu *rel15_ul = &gNB->ulsch[i+1][j]->harq_processes[harq_pid]->ulsch_pdu; // --------- setting rel15_ul parameters ---------- rel15_ul->rnti = 0x1234; rel15_ul->ulsch_pdu_rel15.start_rb = 0; rel15_ul->ulsch_pdu_rel15.number_rbs = 50; rel15_ul->ulsch_pdu_rel15.start_symbol = 0; rel15_ul->ulsch_pdu_rel15.number_symbols = 14; rel15_ul->ulsch_pdu_rel15.length_dmrs = gNB->dmrs_UplinkConfig.pusch_maxLength; rel15_ul->ulsch_pdu_rel15.Qm = 2; rel15_ul->ulsch_pdu_rel15.R = 679; rel15_ul->ulsch_pdu_rel15.mcs = 9; rel15_ul->ulsch_pdu_rel15.rv = 0; rel15_ul->ulsch_pdu_rel15.n_layers = 1; /////////////////////////////////////////////////// */ } } gNB->dlsch_SI = new_gNB_dlsch(1,8,NSOFT, 0, fp, cfg); LOG_D(PHY,"gNB %d.%d : SI %p\n",gNB->Mod_id,gNB->CC_id,gNB->dlsch_SI); gNB->dlsch_ra = new_gNB_dlsch(1,8,NSOFT, 0, fp, cfg); LOG_D(PHY,"gNB %d.%d : RA %p\n",gNB->Mod_id,gNB->CC_id,gNB->dlsch_ra); gNB->rx_total_gain_dB=130; for(i=0; i<NUMBER_OF_NR_UE_MAX; i++) gNB->mu_mimo_mode[i].dl_pow_off = 2; gNB->check_for_total_transmissions = 0; gNB->check_for_MUMIMO_transmissions = 0; gNB->FULL_MUMIMO_transmissions = 0; gNB->check_for_SUMIMO_transmissions = 0; //fp->pucch_config_common.deltaPUCCH_Shift = 1; }