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alex037yang
OpenXG-RAN
Commits
bb78f964
Commit
bb78f964
authored
Jun 01, 2018
by
Hongzhi Wang
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UE missing file nr_init
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openair1/PHY/INIT/nr_init_ue.c
openair1/PHY/INIT/nr_init_ue.c
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openair1/PHY/INIT/nr_init_ue.c
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bb78f964
/*
* 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 "phy_init.h"
#include "SCHED_UE/sched_UE.h"
#include "PHY/phy_extern_nr_ue.h"
#include "SIMULATION/TOOLS/sim.h"
#include "RadioResourceConfigCommonSIB.h"
#include "RadioResourceConfigDedicated.h"
#include "TDD-Config.h"
#include "MBSFN-SubframeConfigList.h"
#include "UTIL/LOG/vcd_signal_dumper.h"
#include "assertions.h"
#include <math.h>
#include "PHY/NR_UE_TRANSPORT/nr_transport_ue.h"
#include "PHY/NR_UE_TRANSPORT/nr_transport_proto_ue.h"
#include "PHY/LTE_REFSIG/lte_refsig.h"
//uint8_t dmrs1_tab_ue[8] = {0,2,3,4,6,8,9,10};
/*void phy_config_sib1_ue(uint8_t Mod_id,int CC_id,
uint8_t eNB_id,
TDD_Config_t *tdd_Config,
uint8_t SIwindowsize,
uint16_t SIperiod)
{
NR_DL_FRAME_PARMS *fp = &PHY_vars_UE_g[Mod_id][CC_id]->frame_parms;
if (tdd_Config) {
fp->tdd_config = tdd_Config->subframeAssignment;
fp->tdd_config_S = tdd_Config->specialSubframePatterns;
}
fp->SIwindowsize = SIwindowsize;
fp->SIPeriod = SIperiod;
}
void phy_config_sib2_ue(uint8_t Mod_id,int CC_id,
uint8_t eNB_id,
RadioResourceConfigCommonSIB_t *radioResourceConfigCommon,
ARFCN_ValueEUTRA_t *ul_CarrierFreq,
long *ul_Bandwidth,
AdditionalSpectrumEmission_t *additionalSpectrumEmission,
struct MBSFN_SubframeConfigList *mbsfn_SubframeConfigList)
{
PHY_VARS_UE *ue = PHY_vars_UE_g[Mod_id][CC_id];
NR_DL_FRAME_PARMS *fp = &ue->frame_parms;
int i;
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_UE_CONFIG_SIB2, VCD_FUNCTION_IN);
LOG_I(PHY,"[UE%d] Applying radioResourceConfigCommon from eNB%d\n",Mod_id,eNB_id);
fp->prach_config_common.rootSequenceIndex =radioResourceConfigCommon->prach_Config.rootSequenceIndex;
fp->prach_config_common.prach_Config_enabled=1;
fp->prach_config_common.prach_ConfigInfo.prach_ConfigIndex =radioResourceConfigCommon->prach_Config.prach_ConfigInfo.prach_ConfigIndex;
fp->prach_config_common.prach_ConfigInfo.highSpeedFlag =radioResourceConfigCommon->prach_Config.prach_ConfigInfo.highSpeedFlag;
fp->prach_config_common.prach_ConfigInfo.zeroCorrelationZoneConfig =radioResourceConfigCommon->prach_Config.prach_ConfigInfo.zeroCorrelationZoneConfig;
fp->prach_config_common.prach_ConfigInfo.prach_FreqOffset =radioResourceConfigCommon->prach_Config.prach_ConfigInfo.prach_FreqOffset;
compute_prach_seq(fp->prach_config_common.rootSequenceIndex,
fp->prach_config_common.prach_ConfigInfo.prach_ConfigIndex,
fp->prach_config_common.prach_ConfigInfo.zeroCorrelationZoneConfig,
fp->prach_config_common.prach_ConfigInfo.highSpeedFlag,
fp->frame_type,ue->X_u);
fp->pucch_config_common.deltaPUCCH_Shift = 1+radioResourceConfigCommon->pucch_ConfigCommon.deltaPUCCH_Shift;
fp->pucch_config_common.nRB_CQI = radioResourceConfigCommon->pucch_ConfigCommon.nRB_CQI;
fp->pucch_config_common.nCS_AN = radioResourceConfigCommon->pucch_ConfigCommon.nCS_AN;
fp->pucch_config_common.n1PUCCH_AN = radioResourceConfigCommon->pucch_ConfigCommon.n1PUCCH_AN;
fp->pdsch_config_common.referenceSignalPower = radioResourceConfigCommon->pdsch_ConfigCommon.referenceSignalPower;
fp->pdsch_config_common.p_b = radioResourceConfigCommon->pdsch_ConfigCommon.p_b;
fp->pusch_config_common.n_SB = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.n_SB;
fp->pusch_config_common.hoppingMode = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.hoppingMode;
fp->pusch_config_common.pusch_HoppingOffset = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.pusch_HoppingOffset;
fp->pusch_config_common.enable64QAM = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.enable64QAM;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.groupHoppingEnabled = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupHoppingEnabled;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.cyclicShift = dmrs1_tab_ue[radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.cyclicShift];
init_ul_hopping(fp);
fp->soundingrs_ul_config_common.enabled_flag = 0;
if (radioResourceConfigCommon->soundingRS_UL_ConfigCommon.present==SoundingRS_UL_ConfigCommon_PR_setup) {
fp->soundingrs_ul_config_common.enabled_flag = 1;
fp->soundingrs_ul_config_common.srs_BandwidthConfig = radioResourceConfigCommon->soundingRS_UL_ConfigCommon.choice.setup.srs_BandwidthConfig;
fp->soundingrs_ul_config_common.srs_SubframeConfig = radioResourceConfigCommon->soundingRS_UL_ConfigCommon.choice.setup.srs_SubframeConfig;
fp->soundingrs_ul_config_common.ackNackSRS_SimultaneousTransmission = radioResourceConfigCommon->soundingRS_UL_ConfigCommon.choice.setup.ackNackSRS_SimultaneousTransmission;
if (radioResourceConfigCommon->soundingRS_UL_ConfigCommon.choice.setup.srs_MaxUpPts)
fp->soundingrs_ul_config_common.srs_MaxUpPts = 1;
else
fp->soundingrs_ul_config_common.srs_MaxUpPts = 0;
}
fp->ul_power_control_config_common.p0_NominalPUSCH = radioResourceConfigCommon->uplinkPowerControlCommon.p0_NominalPUSCH;
fp->ul_power_control_config_common.alpha = radioResourceConfigCommon->uplinkPowerControlCommon.alpha;
fp->ul_power_control_config_common.p0_NominalPUCCH = radioResourceConfigCommon->uplinkPowerControlCommon.p0_NominalPUCCH;
fp->ul_power_control_config_common.deltaPreambleMsg3 = radioResourceConfigCommon->uplinkPowerControlCommon.deltaPreambleMsg3;
fp->ul_power_control_config_common.deltaF_PUCCH_Format1 = radioResourceConfigCommon->uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format1;
fp->ul_power_control_config_common.deltaF_PUCCH_Format1b = radioResourceConfigCommon->uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format1b;
fp->ul_power_control_config_common.deltaF_PUCCH_Format2 = radioResourceConfigCommon->uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2;
fp->ul_power_control_config_common.deltaF_PUCCH_Format2a = radioResourceConfigCommon->uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2a;
fp->ul_power_control_config_common.deltaF_PUCCH_Format2b = radioResourceConfigCommon->uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2b;
fp->maxHARQ_Msg3Tx = radioResourceConfigCommon->rach_ConfigCommon.maxHARQ_Msg3Tx;
// Now configure some of the Physical Channels
// PUCCH
init_ncs_cell(fp,ue->ncs_cell);
init_ul_hopping(fp);
// PCH
init_ue_paging_info(ue,radioResourceConfigCommon->pcch_Config.defaultPagingCycle,radioResourceConfigCommon->pcch_Config.nB);
// MBSFN
if (mbsfn_SubframeConfigList != NULL) {
fp->num_MBSFN_config = mbsfn_SubframeConfigList->list.count;
for (i=0; i<mbsfn_SubframeConfigList->list.count; i++) {
fp->MBSFN_config[i].radioframeAllocationPeriod = mbsfn_SubframeConfigList->list.array[i]->radioframeAllocationPeriod;
fp->MBSFN_config[i].radioframeAllocationOffset = mbsfn_SubframeConfigList->list.array[i]->radioframeAllocationOffset;
if (mbsfn_SubframeConfigList->list.array[i]->subframeAllocation.present == MBSFN_SubframeConfig__subframeAllocation_PR_oneFrame) {
fp->MBSFN_config[i].fourFrames_flag = 0;
fp->MBSFN_config[i].mbsfn_SubframeConfig = mbsfn_SubframeConfigList->list.array[i]->subframeAllocation.choice.oneFrame.buf[0]; // 6-bit subframe configuration
LOG_I(PHY, "[CONFIG] MBSFN_SubframeConfig[%d] pattern is %d\n", i,
fp->MBSFN_config[i].mbsfn_SubframeConfig);
} else if (mbsfn_SubframeConfigList->list.array[i]->subframeAllocation.present == MBSFN_SubframeConfig__subframeAllocation_PR_fourFrames) { // 24-bit subframe configuration
fp->MBSFN_config[i].fourFrames_flag = 1;
fp->MBSFN_config[i].mbsfn_SubframeConfig =
mbsfn_SubframeConfigList->list.array[i]->subframeAllocation.choice.oneFrame.buf[0]|
(mbsfn_SubframeConfigList->list.array[i]->subframeAllocation.choice.oneFrame.buf[1]<<8)|
(mbsfn_SubframeConfigList->list.array[i]->subframeAllocation.choice.oneFrame.buf[2]<<16);
LOG_I(PHY, "[CONFIG] MBSFN_SubframeConfig[%d] pattern is %d\n", i,
fp->MBSFN_config[i].mbsfn_SubframeConfig);
}
}
}
VCD_SIGNAL_DUMPER_DUMP_FUNCTION_BY_NAME(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_UE_CONFIG_SIB2, VCD_FUNCTION_OUT);
}
void phy_config_sib13_ue(uint8_t Mod_id,int CC_id,uint8_t eNB_id,int mbsfn_Area_idx,
long mbsfn_AreaId_r9)
{
NR_DL_FRAME_PARMS *fp = &PHY_vars_UE_g[Mod_id][CC_id]->frame_parms;
LOG_I(PHY,"[UE%d] Applying MBSFN_Area_id %ld for index %d\n",Mod_id,mbsfn_AreaId_r9,mbsfn_Area_idx);
if (mbsfn_Area_idx == 0) {
fp->Nid_cell_mbsfn = (uint16_t)mbsfn_AreaId_r9;
LOG_N(PHY,"Fix me: only called when mbsfn_Area_idx == 0)\n");
}
lte_gold_mbsfn(fp,PHY_vars_UE_g[Mod_id][CC_id]->lte_gold_mbsfn_table,fp->Nid_cell_mbsfn);
}*/
/*
* Configures UE MAC and PHY with radioResourceCommon received in mobilityControlInfo IE during Handover
*/
/*void phy_config_afterHO_ue(uint8_t Mod_id,uint8_t CC_id,uint8_t eNB_id, MobilityControlInfo_t *mobilityControlInfo, uint8_t ho_failed)
{
if(mobilityControlInfo!=NULL) {
RadioResourceConfigCommon_t *radioResourceConfigCommon = &mobilityControlInfo->radioResourceConfigCommon;
LOG_I(PHY,"radioResourceConfigCommon %p\n", radioResourceConfigCommon);
memcpy((void *)&PHY_vars_UE_g[Mod_id][CC_id]->frame_parms_before_ho,
(void *)&PHY_vars_UE_g[Mod_id][CC_id]->frame_parms,
sizeof(NR_DL_FRAME_PARMS));
PHY_vars_UE_g[Mod_id][CC_id]->ho_triggered = 1;
//PHY_vars_UE_g[UE_id]->UE_mode[0] = PRACH;
NR_DL_FRAME_PARMS *fp = &PHY_vars_UE_g[Mod_id][CC_id]->frame_parms;
// int N_ZC;
// uint8_t prach_fmt;
// int u;
LOG_I(PHY,"[UE%d] Handover triggered: Applying radioResourceConfigCommon from eNB %d\n",
Mod_id,eNB_id);
fp->prach_config_common.rootSequenceIndex =radioResourceConfigCommon->prach_Config.rootSequenceIndex;
fp->prach_config_common.prach_Config_enabled=1;
fp->prach_config_common.prach_ConfigInfo.prach_ConfigIndex =radioResourceConfigCommon->prach_Config.prach_ConfigInfo->prach_ConfigIndex;
fp->prach_config_common.prach_ConfigInfo.highSpeedFlag =radioResourceConfigCommon->prach_Config.prach_ConfigInfo->highSpeedFlag;
fp->prach_config_common.prach_ConfigInfo.zeroCorrelationZoneConfig =radioResourceConfigCommon->prach_Config.prach_ConfigInfo->zeroCorrelationZoneConfig;
fp->prach_config_common.prach_ConfigInfo.prach_FreqOffset =radioResourceConfigCommon->prach_Config.prach_ConfigInfo->prach_FreqOffset;
// prach_fmt = get_prach_fmt(radioResourceConfigCommon->prach_Config.prach_ConfigInfo->prach_ConfigIndex,fp->frame_type);
// N_ZC = (prach_fmt <4)?839:139;
// u = (prach_fmt < 4) ? prach_root_sequence_map0_3[fp->prach_config_common.rootSequenceIndex] :
// prach_root_sequence_map4[fp->prach_config_common.rootSequenceIndex];
//compute_prach_seq(u,N_ZC, PHY_vars_UE_g[Mod_id]->X_u);
compute_prach_seq(PHY_vars_UE_g[Mod_id][CC_id]->frame_parms.prach_config_common.rootSequenceIndex,
PHY_vars_UE_g[Mod_id][CC_id]->frame_parms.prach_config_common.prach_ConfigInfo.prach_ConfigIndex,
PHY_vars_UE_g[Mod_id][CC_id]->frame_parms.prach_config_common.prach_ConfigInfo.zeroCorrelationZoneConfig,
PHY_vars_UE_g[Mod_id][CC_id]->frame_parms.prach_config_common.prach_ConfigInfo.highSpeedFlag,
fp->frame_type,
PHY_vars_UE_g[Mod_id][CC_id]->X_u);
fp->pucch_config_common.deltaPUCCH_Shift = 1+radioResourceConfigCommon->pucch_ConfigCommon->deltaPUCCH_Shift;
fp->pucch_config_common.nRB_CQI = radioResourceConfigCommon->pucch_ConfigCommon->nRB_CQI;
fp->pucch_config_common.nCS_AN = radioResourceConfigCommon->pucch_ConfigCommon->nCS_AN;
fp->pucch_config_common.n1PUCCH_AN = radioResourceConfigCommon->pucch_ConfigCommon->n1PUCCH_AN;
fp->pdsch_config_common.referenceSignalPower = radioResourceConfigCommon->pdsch_ConfigCommon->referenceSignalPower;
fp->pdsch_config_common.p_b = radioResourceConfigCommon->pdsch_ConfigCommon->p_b;
fp->pusch_config_common.n_SB = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.n_SB;
fp->pusch_config_common.hoppingMode = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.hoppingMode;
fp->pusch_config_common.pusch_HoppingOffset = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.pusch_HoppingOffset;
fp->pusch_config_common.enable64QAM = radioResourceConfigCommon->pusch_ConfigCommon.pusch_ConfigBasic.enable64QAM;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.groupHoppingEnabled = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupHoppingEnabled;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled;
fp->pusch_config_common.ul_ReferenceSignalsPUSCH.cyclicShift = radioResourceConfigCommon->pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.cyclicShift;
init_ul_hopping(fp);
fp->soundingrs_ul_config_common.enabled_flag = 0;
if (radioResourceConfigCommon->soundingRS_UL_ConfigCommon->present==SoundingRS_UL_ConfigCommon_PR_setup) {
fp->soundingrs_ul_config_common.enabled_flag = 1;
fp->soundingrs_ul_config_common.srs_BandwidthConfig = radioResourceConfigCommon->soundingRS_UL_ConfigCommon->choice.setup.srs_BandwidthConfig;
fp->soundingrs_ul_config_common.srs_SubframeConfig = radioResourceConfigCommon->soundingRS_UL_ConfigCommon->choice.setup.srs_SubframeConfig;
fp->soundingrs_ul_config_common.ackNackSRS_SimultaneousTransmission = radioResourceConfigCommon->soundingRS_UL_ConfigCommon->choice.setup.ackNackSRS_SimultaneousTransmission;
if (radioResourceConfigCommon->soundingRS_UL_ConfigCommon->choice.setup.srs_MaxUpPts)
fp->soundingrs_ul_config_common.srs_MaxUpPts = 1;
else
fp->soundingrs_ul_config_common.srs_MaxUpPts = 0;
}
fp->ul_power_control_config_common.p0_NominalPUSCH = radioResourceConfigCommon->uplinkPowerControlCommon->p0_NominalPUSCH;
fp->ul_power_control_config_common.alpha = radioResourceConfigCommon->uplinkPowerControlCommon->alpha;
fp->ul_power_control_config_common.p0_NominalPUCCH = radioResourceConfigCommon->uplinkPowerControlCommon->p0_NominalPUCCH;
fp->ul_power_control_config_common.deltaPreambleMsg3 = radioResourceConfigCommon->uplinkPowerControlCommon->deltaPreambleMsg3;
fp->ul_power_control_config_common.deltaF_PUCCH_Format1 = radioResourceConfigCommon->uplinkPowerControlCommon->deltaFList_PUCCH.deltaF_PUCCH_Format1;
fp->ul_power_control_config_common.deltaF_PUCCH_Format1b = radioResourceConfigCommon->uplinkPowerControlCommon->deltaFList_PUCCH.deltaF_PUCCH_Format1b;
fp->ul_power_control_config_common.deltaF_PUCCH_Format2 = radioResourceConfigCommon->uplinkPowerControlCommon->deltaFList_PUCCH.deltaF_PUCCH_Format2;
fp->ul_power_control_config_common.deltaF_PUCCH_Format2a = radioResourceConfigCommon->uplinkPowerControlCommon->deltaFList_PUCCH.deltaF_PUCCH_Format2a;
fp->ul_power_control_config_common.deltaF_PUCCH_Format2b = radioResourceConfigCommon->uplinkPowerControlCommon->deltaFList_PUCCH.deltaF_PUCCH_Format2b;
fp->maxHARQ_Msg3Tx = radioResourceConfigCommon->rach_ConfigCommon->maxHARQ_Msg3Tx;
// Now configure some of the Physical Channels
if (radioResourceConfigCommon->antennaInfoCommon)
fp->nb_antennas_tx = (1<<radioResourceConfigCommon->antennaInfoCommon->antennaPortsCount);
else
fp->nb_antennas_tx = 1;
//PHICH
if (radioResourceConfigCommon->antennaInfoCommon) {
fp->phich_config_common.phich_resource = radioResourceConfigCommon->phich_Config->phich_Resource;
fp->phich_config_common.phich_duration = radioResourceConfigCommon->phich_Config->phich_Duration;
}
//Target CellId
fp->Nid_cell = mobilityControlInfo->targetPhysCellId;
fp->nushift = fp->Nid_cell%6;
// PUCCH
init_ncs_cell(fp,PHY_vars_UE_g[Mod_id][CC_id]->ncs_cell);
init_ul_hopping(fp);
// RNTI
PHY_vars_UE_g[Mod_id][CC_id]->pdcch_vars[0][eNB_id]->crnti = mobilityControlInfo->newUE_Identity.buf[0]|(mobilityControlInfo->newUE_Identity.buf[1]<<8);
PHY_vars_UE_g[Mod_id][CC_id]->pdcch_vars[1][eNB_id]->crnti = mobilityControlInfo->newUE_Identity.buf[0]|(mobilityControlInfo->newUE_Identity.buf[1]<<8);
LOG_I(PHY,"SET C-RNTI %x %x\n",PHY_vars_UE_g[Mod_id][CC_id]->pdcch_vars[0][eNB_id]->crnti,
PHY_vars_UE_g[Mod_id][CC_id]->pdcch_vars[1][eNB_id]->crnti);
}
if(ho_failed) {
LOG_D(PHY,"[UE%d] Handover failed, triggering RACH procedure\n",Mod_id);
memcpy((void *)&PHY_vars_UE_g[Mod_id][CC_id]->frame_parms,(void *)&PHY_vars_UE_g[Mod_id][CC_id]->frame_parms_before_ho, sizeof(NR_DL_FRAME_PARMS));
PHY_vars_UE_g[Mod_id][CC_id]->UE_mode[eNB_id] = PRACH;
}
}
void phy_config_meas_ue(uint8_t Mod_id,uint8_t CC_id,uint8_t eNB_index,uint8_t n_adj_cells,unsigned int *adj_cell_id)
{
PHY_NR_MEASUREMENTS *phy_meas = &PHY_vars_UE_g[Mod_id][CC_id]->measurements;
int i;
LOG_I(PHY,"Configuring inter-cell measurements for %d cells, ids: \n",n_adj_cells);
for (i=0; i<n_adj_cells; i++) {
LOG_I(PHY,"%d\n",adj_cell_id[i]);
lte_gold(&PHY_vars_UE_g[Mod_id][CC_id]->frame_parms,PHY_vars_UE_g[Mod_id][CC_id]->lte_gold_table[i+1],adj_cell_id[i]);
}
phy_meas->n_adj_cells = n_adj_cells;
memcpy((void*)phy_meas->adj_cell_id,(void *)adj_cell_id,n_adj_cells*sizeof(unsigned int));
}
#if defined(Rel10) || defined(Rel14)
void phy_config_dedicated_scell_ue(uint8_t Mod_id,
uint8_t eNB_index,
SCellToAddMod_r10_t *sCellToAddMod_r10,
int CC_id)
{
}
#endif
void phy_config_harq_ue(uint8_t Mod_id,int CC_id,uint8_t eNB_id,
uint16_t max_harq_tx )
{
PHY_VARS_UE *phy_vars_ue = PHY_vars_UE_g[Mod_id][CC_id];
phy_vars_ue->ulsch[eNB_id]->Mlimit = max_harq_tx;
}
extern uint16_t beta_cqi[16];
void phy_config_dedicated_ue(uint8_t Mod_id,int CC_id,uint8_t eNB_id,
struct PhysicalConfigDedicated *physicalConfigDedicated )
{
static uint8_t first_dedicated_configuration = 0;
PHY_VARS_UE *phy_vars_ue = PHY_vars_UE_g[Mod_id][CC_id];
phy_vars_ue->total_TBS[eNB_id]=0;
phy_vars_ue->total_TBS_last[eNB_id]=0;
phy_vars_ue->bitrate[eNB_id]=0;
phy_vars_ue->total_received_bits[eNB_id]=0;
phy_vars_ue->dlsch_errors[eNB_id]=0;
phy_vars_ue->dlsch_errors_last[eNB_id]=0;
phy_vars_ue->dlsch_received[eNB_id]=0;
phy_vars_ue->dlsch_received_last[eNB_id]=0;
phy_vars_ue->dlsch_fer[eNB_id]=0;
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.ri_ConfigIndex = -1;
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.cqi_PMI_ConfigIndex = -1;
if (physicalConfigDedicated) {
LOG_D(PHY,"[UE %d] Received physicalConfigDedicated from eNB %d\n",Mod_id, eNB_id);
LOG_D(PHY,"------------------------------------------------------------------------\n");
if (physicalConfigDedicated->pdsch_ConfigDedicated) {
phy_vars_ue->pdsch_config_dedicated[eNB_id].p_a=physicalConfigDedicated->pdsch_ConfigDedicated->p_a;
LOG_D(PHY,"pdsch_config_dedicated.p_a %d\n",phy_vars_ue->pdsch_config_dedicated[eNB_id].p_a);
LOG_D(PHY,"\n");
}
if (physicalConfigDedicated->pucch_ConfigDedicated) {
if (physicalConfigDedicated->pucch_ConfigDedicated->ackNackRepetition.present==PUCCH_ConfigDedicated__ackNackRepetition_PR_release)
phy_vars_ue->pucch_config_dedicated[eNB_id].ackNackRepetition=0;
else {
phy_vars_ue->pucch_config_dedicated[eNB_id].ackNackRepetition=1;
}
if (physicalConfigDedicated->pucch_ConfigDedicated->tdd_AckNackFeedbackMode)
phy_vars_ue->pucch_config_dedicated[eNB_id].tdd_AckNackFeedbackMode = *physicalConfigDedicated->pucch_ConfigDedicated->tdd_AckNackFeedbackMode;
else
phy_vars_ue->pucch_config_dedicated[eNB_id].tdd_AckNackFeedbackMode = bundling;
if ( phy_vars_ue->pucch_config_dedicated[eNB_id].tdd_AckNackFeedbackMode == multiplexing)
LOG_D(PHY,"pucch_config_dedicated.tdd_AckNackFeedbackMode = multiplexing\n");
else
LOG_D(PHY,"pucch_config_dedicated.tdd_AckNackFeedbackMode = bundling\n");
}
if (physicalConfigDedicated->pusch_ConfigDedicated) {
phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_ACK_Index = physicalConfigDedicated->pusch_ConfigDedicated->betaOffset_ACK_Index;
phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_RI_Index = physicalConfigDedicated->pusch_ConfigDedicated->betaOffset_RI_Index;
phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_CQI_Index = physicalConfigDedicated->pusch_ConfigDedicated->betaOffset_CQI_Index;
LOG_D(PHY,"pusch_config_dedicated.betaOffset_ACK_Index %d\n",phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_ACK_Index);
LOG_D(PHY,"pusch_config_dedicated.betaOffset_RI_Index %d\n",phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_RI_Index);
LOG_D(PHY,"pusch_config_dedicated.betaOffset_CQI_Index %d => %d)\n",phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_CQI_Index,beta_cqi[phy_vars_ue->pusch_config_dedicated[eNB_id].betaOffset_CQI_Index]);
LOG_D(PHY,"\n");
}
if (physicalConfigDedicated->uplinkPowerControlDedicated) {
phy_vars_ue->ul_power_control_dedicated[eNB_id].p0_UE_PUSCH = physicalConfigDedicated->uplinkPowerControlDedicated->p0_UE_PUSCH;
phy_vars_ue->ul_power_control_dedicated[eNB_id].deltaMCS_Enabled= physicalConfigDedicated->uplinkPowerControlDedicated->deltaMCS_Enabled;
phy_vars_ue->ul_power_control_dedicated[eNB_id].accumulationEnabled= physicalConfigDedicated->uplinkPowerControlDedicated->accumulationEnabled;
phy_vars_ue->ul_power_control_dedicated[eNB_id].p0_UE_PUCCH= physicalConfigDedicated->uplinkPowerControlDedicated->p0_UE_PUCCH;
phy_vars_ue->ul_power_control_dedicated[eNB_id].pSRS_Offset= physicalConfigDedicated->uplinkPowerControlDedicated->pSRS_Offset;
phy_vars_ue->ul_power_control_dedicated[eNB_id].filterCoefficient= *physicalConfigDedicated->uplinkPowerControlDedicated->filterCoefficient;
LOG_D(PHY,"ul_power_control_dedicated.p0_UE_PUSCH %d\n",phy_vars_ue->ul_power_control_dedicated[eNB_id].p0_UE_PUSCH);
LOG_D(PHY,"ul_power_control_dedicated.deltaMCS_Enabled %d\n",phy_vars_ue->ul_power_control_dedicated[eNB_id].deltaMCS_Enabled);
LOG_D(PHY,"ul_power_control_dedicated.accumulationEnabled %d\n",phy_vars_ue->ul_power_control_dedicated[eNB_id].accumulationEnabled);
LOG_D(PHY,"ul_power_control_dedicated.p0_UE_PUCCH %d\n",phy_vars_ue->ul_power_control_dedicated[eNB_id].p0_UE_PUCCH);
LOG_D(PHY,"ul_power_control_dedicated.pSRS_Offset %d\n",phy_vars_ue->ul_power_control_dedicated[eNB_id].pSRS_Offset);
LOG_D(PHY,"ul_power_control_dedicated.filterCoefficient %d\n",phy_vars_ue->ul_power_control_dedicated[eNB_id].filterCoefficient);
LOG_D(PHY,"\n");
}
if (physicalConfigDedicated->antennaInfo) {
phy_vars_ue->transmission_mode[eNB_id] = 1+(physicalConfigDedicated->antennaInfo->choice.explicitValue.transmissionMode);
LOG_I(PHY,"Transmission Mode %d\n",phy_vars_ue->transmission_mode[eNB_id]);
switch(physicalConfigDedicated->antennaInfo->choice.explicitValue.transmissionMode) {
case AntennaInfoDedicated__transmissionMode_tm1:
phy_vars_ue->transmission_mode[eNB_id] = 1;
break;
case AntennaInfoDedicated__transmissionMode_tm2:
phy_vars_ue->transmission_mode[eNB_id] = 2;
break;
case AntennaInfoDedicated__transmissionMode_tm3:
phy_vars_ue->transmission_mode[eNB_id] = 3;
break;
case AntennaInfoDedicated__transmissionMode_tm4:
phy_vars_ue->transmission_mode[eNB_id] = 4;
break;
case AntennaInfoDedicated__transmissionMode_tm5:
phy_vars_ue->transmission_mode[eNB_id] = 5;
break;
case AntennaInfoDedicated__transmissionMode_tm6:
phy_vars_ue->transmission_mode[eNB_id] = 6;
break;
case AntennaInfoDedicated__transmissionMode_tm7:
lte_gold_ue_spec_port5(phy_vars_ue->lte_gold_uespec_port5_table, phy_vars_ue->frame_parms.Nid_cell, phy_vars_ue->pdcch_vars[0][eNB_id]->crnti);
phy_vars_ue->transmission_mode[eNB_id] = 7;
break;
default:
LOG_E(PHY,"Unknown transmission mode!\n");
break;
}
} else {
LOG_D(PHY,"[UE %d] Received NULL physicalConfigDedicated->antennaInfo from eNB %d\n",Mod_id, eNB_id);
}
if (physicalConfigDedicated->schedulingRequestConfig) {
if (physicalConfigDedicated->schedulingRequestConfig->present == SchedulingRequestConfig_PR_setup) {
phy_vars_ue->scheduling_request_config[eNB_id].sr_PUCCH_ResourceIndex = physicalConfigDedicated->schedulingRequestConfig->choice.setup.sr_PUCCH_ResourceIndex;
phy_vars_ue->scheduling_request_config[eNB_id].sr_ConfigIndex=physicalConfigDedicated->schedulingRequestConfig->choice.setup.sr_ConfigIndex;
phy_vars_ue->scheduling_request_config[eNB_id].dsr_TransMax=physicalConfigDedicated->schedulingRequestConfig->choice.setup.dsr_TransMax;
LOG_D(PHY,"scheduling_request_config.sr_PUCCH_ResourceIndex %d\n",phy_vars_ue->scheduling_request_config[eNB_id].sr_PUCCH_ResourceIndex);
LOG_D(PHY,"scheduling_request_config.sr_ConfigIndex %d\n",phy_vars_ue->scheduling_request_config[eNB_id].sr_ConfigIndex);
LOG_D(PHY,"scheduling_request_config.dsr_TransMax %d\n",phy_vars_ue->scheduling_request_config[eNB_id].dsr_TransMax);
}
LOG_D(PHY,"------------------------------------------------------------\n");
}
if (physicalConfigDedicated->soundingRS_UL_ConfigDedicated) {
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].srsConfigDedicatedSetup = 0;
if (physicalConfigDedicated->soundingRS_UL_ConfigDedicated->present == SoundingRS_UL_ConfigDedicated_PR_setup) {
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].srsConfigDedicatedSetup = 1;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].duration = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.duration;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].cyclicShift = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.cyclicShift;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].freqDomainPosition = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.freqDomainPosition;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].srs_Bandwidth = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.srs_Bandwidth;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].srs_ConfigIndex = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.srs_ConfigIndex;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].srs_HoppingBandwidth = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.srs_HoppingBandwidth;
phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].transmissionComb = physicalConfigDedicated->soundingRS_UL_ConfigDedicated->choice.setup.transmissionComb;
LOG_D(PHY,"soundingrs_ul_config_dedicated.srs_ConfigIndex %d\n",phy_vars_ue->soundingrs_ul_config_dedicated[eNB_id].srs_ConfigIndex);
}
LOG_D(PHY,"------------------------------------------------------------\n");
}
if (physicalConfigDedicated->cqi_ReportConfig) {
if (physicalConfigDedicated->cqi_ReportConfig->cqi_ReportModeAperiodic) {
// configure PUSCH CQI reporting
phy_vars_ue->cqi_report_config[eNB_id].cqi_ReportModeAperiodic = *physicalConfigDedicated->cqi_ReportConfig->cqi_ReportModeAperiodic;
if ((phy_vars_ue->cqi_report_config[eNB_id].cqi_ReportModeAperiodic != rm12) &&
(phy_vars_ue->cqi_report_config[eNB_id].cqi_ReportModeAperiodic != rm30) &&
(phy_vars_ue->cqi_report_config[eNB_id].cqi_ReportModeAperiodic != rm31))
LOG_E(PHY,"Unsupported Aperiodic CQI Feedback Mode : %d\n",phy_vars_ue->cqi_report_config[eNB_id].cqi_ReportModeAperiodic);
}
if (physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic) {
if (physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic->present == CQI_ReportPeriodic_PR_setup) {
// configure PUCCH CQI reporting
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.cqi_PUCCH_ResourceIndex = physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic->choice.setup.cqi_PUCCH_ResourceIndex;
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.cqi_PMI_ConfigIndex = physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic->choice.setup.cqi_pmi_ConfigIndex;
if (physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic->choice.setup.ri_ConfigIndex)
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.ri_ConfigIndex = *physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic->choice.setup.ri_ConfigIndex;
}
else if (physicalConfigDedicated->cqi_ReportConfig->cqi_ReportPeriodic->present == CQI_ReportPeriodic_PR_release) {
// handle release
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.ri_ConfigIndex = -1;
phy_vars_ue->cqi_report_config[eNB_id].CQI_ReportPeriodic.cqi_PMI_ConfigIndex = -1;
}
}
}
#ifdef CBA
if (physicalConfigDedicated->pusch_CBAConfigDedicated_vlola) {
phy_vars_ue->pusch_ca_config_dedicated[eNB_id].betaOffset_CA_Index = (uint16_t) *physicalConfigDedicated->pusch_CBAConfigDedicated_vlola->betaOffset_CBA_Index;
phy_vars_ue->pusch_ca_config_dedicated[eNB_id].cShift = (uint16_t) *physicalConfigDedicated->pusch_CBAConfigDedicated_vlola->cShift_CBA;
LOG_D(PHY,"[UE %d ] physicalConfigDedicated pusch CBA config dedicated: beta offset %d cshift %d \n",Mod_id,
phy_vars_ue->pusch_ca_config_dedicated[eNB_id].betaOffset_CA_Index,
phy_vars_ue->pusch_ca_config_dedicated[eNB_id].cShift);
}
#endif
} else {
LOG_D(PHY,"[PHY][UE %d] Received NULL radioResourceConfigDedicated from eNB %d\n",Mod_id,eNB_id);
return;
}
// fill cqi parameters for periodic CQI reporting
get_cqipmiri_params(phy_vars_ue,eNB_id);
// disable MIB SIB decoding once we are on connected mode
first_dedicated_configuration ++;
if(first_dedicated_configuration > 1)
{
LOG_I(PHY,"Disable SIB MIB decoding \n");
phy_vars_ue->decode_SIB = 0;
phy_vars_ue->decode_MIB = 0;
}
//phy_vars_ue->pdcch_vars[1][eNB_id]->crnti = phy_vars_ue->pdcch_vars[0][eNB_id]->crnti;
if(phy_vars_ue->pdcch_vars[0][eNB_id]->crnti == 0x1234)
phy_vars_ue->pdcch_vars[0][eNB_id]->crnti = phy_vars_ue->pdcch_vars[1][eNB_id]->crnti;
else
phy_vars_ue->pdcch_vars[1][eNB_id]->crnti = phy_vars_ue->pdcch_vars[0][eNB_id]->crnti;
LOG_I(PHY,"C-RNTI %x %x \n", phy_vars_ue->pdcch_vars[0][eNB_id]->crnti,
phy_vars_ue->pdcch_vars[1][eNB_id]->crnti);
}*/
/*! \brief Helper function to allocate memory for DLSCH data structures.
* \param[out] pdsch Pointer to the LTE_UE_PDSCH structure to initialize.
* \param[in] frame_parms LTE_DL_FRAME_PARMS structure.
* \note This function is optimistic in that it expects malloc() to succeed.
*/
void
phy_init_nr_ue__PDSCH
(
NR_UE_PDSCH
*
const
pdsch
,
const
NR_DL_FRAME_PARMS
*
const
fp
)
{
AssertFatal
(
pdsch
,
"pdsch==0"
);
pdsch
->
pmi_ext
=
(
uint8_t
*
)
malloc16_clear
(
fp
->
N_RB_DL
);
pdsch
->
llr
[
0
]
=
(
int16_t
*
)
malloc16_clear
(
(
8
*
((
3
*
8
*
6144
)
+
12
))
*
sizeof
(
int16_t
)
);
pdsch
->
llr128
=
(
int16_t
**
)
malloc16_clear
(
sizeof
(
int16_t
*
)
);
// FIXME! no further allocation for (int16_t*)pdsch->llr128 !!! expect SIGSEGV
// FK, 11-3-2015: this is only as a temporary pointer, no memory is stored there
pdsch
->
rxdataF_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pdsch
->
rxdataF_uespec_pilots
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pdsch
->
rxdataF_comp0
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pdsch
->
rho
=
(
int32_t
**
)
malloc16_clear
(
fp
->
nb_antennas_rx
*
sizeof
(
int32_t
*
)
);
pdsch
->
dl_ch_estimates_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pdsch
->
dl_bf_ch_estimates
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pdsch
->
dl_bf_ch_estimates_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
//pdsch->dl_ch_rho_ext = (int32_t**)malloc16_clear( 8*sizeof(int32_t*) );
//pdsch->dl_ch_rho2_ext = (int32_t**)malloc16_clear( 8*sizeof(int32_t*) );
pdsch
->
dl_ch_mag0
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pdsch
->
dl_ch_magb0
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
// the allocated memory size is fixed:
AssertFatal
(
fp
->
nb_antennas_rx
<=
2
,
"nb_antennas_rx > 2"
);
for
(
int
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
{
pdsch
->
rho
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
(
fp
->
N_RB_DL
*
12
*
7
*
2
)
);
for
(
int
j
=
0
;
j
<
4
;
j
++
)
{
//fp->nb_antennas_tx; j++)
const
int
idx
=
(
j
<<
1
)
+
i
;
const
size_t
num
=
7
*
2
*
fp
->
N_RB_DL
*
12
;
pdsch
->
rxdataF_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
pdsch
->
rxdataF_uespec_pilots
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
fp
->
N_RB_DL
*
12
);
pdsch
->
rxdataF_comp0
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
pdsch
->
dl_ch_estimates_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
pdsch
->
dl_bf_ch_estimates
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
fp
->
ofdm_symbol_size
*
7
*
2
);
pdsch
->
dl_bf_ch_estimates_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
//pdsch->dl_ch_rho_ext[idx] = (int32_t*)malloc16_clear( sizeof(int32_t) * num );
//pdsch->dl_ch_rho2_ext[idx] = (int32_t*)malloc16_clear( sizeof(int32_t) * num );
pdsch
->
dl_ch_mag0
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
pdsch
->
dl_ch_magb0
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
}
}
}
int
init_nr_ue_signal
(
PHY_VARS_NR_UE
*
ue
,
int
nb_connected_eNB
,
uint8_t
abstraction_flag
)
{
// create shortcuts
NR_DL_FRAME_PARMS
*
const
fp
=
&
ue
->
frame_parms
;
NR_UE_COMMON
*
const
common_vars
=
&
ue
->
common_vars
;
NR_UE_PDSCH
**
const
pdsch_vars_SI
=
ue
->
pdsch_vars_SI
;
NR_UE_PDSCH
**
const
pdsch_vars_ra
=
ue
->
pdsch_vars_ra
;
NR_UE_PDSCH
**
const
pdsch_vars_p
=
ue
->
pdsch_vars_p
;
NR_UE_PDSCH
**
const
pdsch_vars_mch
=
ue
->
pdsch_vars_MCH
;
NR_UE_PDSCH
*
(
*
pdsch_vars_th
)[][
NUMBER_OF_CONNECTED_eNB_MAX
+
1
]
=
&
ue
->
pdsch_vars
;
NR_UE_PDCCH
*
(
*
pdcch_vars_th
)[][
NUMBER_OF_CONNECTED_eNB_MAX
]
=
&
ue
->
pdcch_vars
;
NR_UE_PBCH
**
const
pbch_vars
=
ue
->
pbch_vars
;
NR_UE_PRACH
**
const
prach_vars
=
ue
->
prach_vars
;
int
i
,
j
,
k
,
l
;
int
eNB_id
;
int
th_id
;
abstraction_flag
=
0
;
fp
->
nb_antennas_tx
=
1
;
fp
->
nb_antennas_rx
=
1
;
printf
(
"Initializing UE vars (abstraction %"
PRIu8
") for eNB TXant %"
PRIu8
", UE RXant %"
PRIu8
"
\n
"
,
abstraction_flag
,
fp
->
nb_antennas_tx
,
fp
->
nb_antennas_rx
);
//LOG_D(PHY,"[MSC_NEW][FRAME 00000][PHY_UE][MOD %02u][]\n", ue->Mod_id+NB_eNB_INST);
// many memory allocation sizes are hard coded
AssertFatal
(
fp
->
nb_antennas_rx
<=
2
,
"hard coded allocation for ue_common_vars->dl_ch_estimates[eNB_id]"
);
AssertFatal
(
ue
->
n_connected_eNB
<=
NUMBER_OF_CONNECTED_eNB_MAX
,
"n_connected_eNB is too large"
);
// init phy_vars_ue
for
(
i
=
0
;
i
<
4
;
i
++
)
{
ue
->
rx_gain_max
[
i
]
=
135
;
ue
->
rx_gain_med
[
i
]
=
128
;
ue
->
rx_gain_byp
[
i
]
=
120
;
}
ue
->
n_connected_eNB
=
nb_connected_eNB
;
for
(
eNB_id
=
0
;
eNB_id
<
ue
->
n_connected_eNB
;
eNB_id
++
)
{
ue
->
total_TBS
[
eNB_id
]
=
0
;
ue
->
total_TBS_last
[
eNB_id
]
=
0
;
ue
->
bitrate
[
eNB_id
]
=
0
;
ue
->
total_received_bits
[
eNB_id
]
=
0
;
}
for
(
i
=
0
;
i
<
10
;
i
++
)
ue
->
tx_power_dBm
[
i
]
=-
127
;
if
(
abstraction_flag
==
0
)
{
// init TX buffers
common_vars
->
txdata
=
(
int32_t
**
)
malloc16
(
fp
->
nb_antennas_tx
*
sizeof
(
int32_t
*
)
);
common_vars
->
txdataF
=
(
int32_t
**
)
malloc16
(
fp
->
nb_antennas_tx
*
sizeof
(
int32_t
*
)
);
for
(
i
=
0
;
i
<
fp
->
nb_antennas_tx
;
i
++
)
{
common_vars
->
txdata
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
fp
->
samples_per_subframe
*
10
*
sizeof
(
int32_t
)
);
common_vars
->
txdataF
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
fp
->
ofdm_symbol_size
*
fp
->
symbols_per_tti
*
10
*
sizeof
(
int32_t
)
);
}
// init RX buffers
common_vars
->
rxdata
=
(
int32_t
**
)
malloc16
(
fp
->
nb_antennas_rx
*
sizeof
(
int32_t
*
)
);
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
common_vars
->
common_vars_rx_data_per_thread
[
th_id
].
rxdataF
=
(
int32_t
**
)
malloc16
(
fp
->
nb_antennas_rx
*
sizeof
(
int32_t
*
)
);
}
for
(
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
{
common_vars
->
rxdata
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
(
fp
->
samples_per_subframe
*
10
+
2048
)
*
sizeof
(
int32_t
)
);
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
common_vars
->
common_vars_rx_data_per_thread
[
th_id
].
rxdataF
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
(
fp
->
ofdm_symbol_size
*
14
)
);
}
}
}
// Channel estimates
for
(
eNB_id
=
0
;
eNB_id
<
7
;
eNB_id
++
)
{
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
common_vars
->
common_vars_rx_data_per_thread
[
th_id
].
dl_ch_estimates
[
eNB_id
]
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
));
common_vars
->
common_vars_rx_data_per_thread
[
th_id
].
dl_ch_estimates_time
[
eNB_id
]
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
));
}
for
(
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
for
(
j
=
0
;
j
<
4
;
j
++
)
{
int
idx
=
(
j
<<
1
)
+
i
;
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
common_vars
->
common_vars_rx_data_per_thread
[
th_id
].
dl_ch_estimates
[
eNB_id
][
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
fp
->
symbols_per_tti
*
(
fp
->
ofdm_symbol_size
+
LTE_CE_FILTER_LENGTH
)
);
common_vars
->
common_vars_rx_data_per_thread
[
th_id
].
dl_ch_estimates_time
[
eNB_id
][
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
fp
->
ofdm_symbol_size
*
2
);
}
}
}
// DLSCH
for
(
eNB_id
=
0
;
eNB_id
<
ue
->
n_connected_eNB
;
eNB_id
++
)
{
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
));
}
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
=
(
NR_UE_PDCCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDCCH
));
}
pdsch_vars_SI
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
));
pdsch_vars_ra
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
));
pdsch_vars_p
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
));
pdsch_vars_mch
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
));
prach_vars
[
eNB_id
]
=
(
NR_UE_PRACH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PRACH
));
pbch_vars
[
eNB_id
]
=
(
NR_UE_PBCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PBCH
));
if
(
abstraction_flag
==
0
)
{
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
phy_init_nr_ue__PDSCH
(
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
],
fp
);
}
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
llr_shifts
=
(
uint8_t
*
)
malloc16_clear
(
7
*
2
*
fp
->
N_RB_DL
*
12
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
llr_shifts_p
=
(
*
pdsch_vars_th
)[
0
][
eNB_id
]
->
llr_shifts
;
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
llr
[
1
]
=
(
int16_t
*
)
malloc16_clear
(
(
8
*
((
3
*
8
*
8448
)
+
12
))
*
sizeof
(
int16_t
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
llr128_2ndstream
=
(
int16_t
**
)
malloc16_clear
(
sizeof
(
int16_t
*
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
rho
=
(
int32_t
**
)
malloc16_clear
(
fp
->
nb_antennas_rx
*
sizeof
(
int32_t
*
)
);
}
for
(
int
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
){
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
rho
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
7
*
2
*
sizeof
(
int32_t
)
*
(
fp
->
N_RB_DL
*
12
)
);
}
}
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_rho2_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
}
for
(
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
for
(
j
=
0
;
j
<
4
;
j
++
)
{
const
int
idx
=
(
j
<<
1
)
+
i
;
const
size_t
num
=
7
*
2
*
fp
->
N_RB_DL
*
12
+
4
;
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_rho2_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
}
}
//const size_t num = 7*2*fp->N_RB_DL*12+4;
for
(
k
=
0
;
k
<
8
;
k
++
)
{
//harq_pid
for
(
l
=
0
;
l
<
8
;
l
++
)
{
//round
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
rxdataF_comp1
[
k
][
l
]
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_rho_ext
[
k
][
l
]
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_mag1
[
k
][
l
]
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_magb1
[
k
][
l
]
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
}
for
(
int
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
for
(
int
j
=
0
;
j
<
4
;
j
++
)
{
//frame_parms->nb_antennas_tx; j++)
const
int
idx
=
(
j
<<
1
)
+
i
;
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_rho_ext
[
k
][
l
][
idx
]
=
(
int32_t
*
)
malloc16_clear
(
7
*
2
*
sizeof
(
int32_t
)
*
(
fp
->
N_RB_DL
*
12
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
rxdataF_comp1
[
k
][
l
][
idx
]
=
(
int32_t
*
)
malloc16_clear
(
7
*
2
*
sizeof
(
int32_t
)
*
(
fp
->
N_RB_DL
*
12
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_mag1
[
k
][
l
][
idx
]
=
(
int32_t
*
)
malloc16_clear
(
7
*
2
*
sizeof
(
int32_t
)
*
(
fp
->
N_RB_DL
*
12
)
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_magb1
[
k
][
l
][
idx
]
=
(
int32_t
*
)
malloc16_clear
(
7
*
2
*
sizeof
(
int32_t
)
*
(
fp
->
N_RB_DL
*
12
)
);
}
}
}
}
phy_init_nr_ue__PDSCH
(
pdsch_vars_SI
[
eNB_id
],
fp
);
phy_init_nr_ue__PDSCH
(
pdsch_vars_ra
[
eNB_id
],
fp
);
phy_init_nr_ue__PDSCH
(
pdsch_vars_p
[
eNB_id
],
fp
);
phy_init_nr_ue__PDSCH
(
pdsch_vars_mch
[
eNB_id
],
fp
);
// 100 PRBs * 12 REs/PRB * 4 PDCCH SYMBOLS * 2 LLRs/RE
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
llr
=
(
uint16_t
*
)
malloc16_clear
(
2
*
4
*
100
*
12
*
sizeof
(
uint16_t
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
llr16
=
(
uint16_t
*
)
malloc16_clear
(
2
*
4
*
100
*
12
*
sizeof
(
uint16_t
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
wbar
=
(
uint16_t
*
)
malloc16_clear
(
2
*
4
*
100
*
12
*
sizeof
(
uint16_t
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
e_rx
=
(
int8_t
*
)
malloc16_clear
(
4
*
2
*
100
*
12
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
rxdataF_comp
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_rho_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
rho
=
(
int32_t
**
)
malloc16
(
fp
->
nb_antennas_rx
*
sizeof
(
int32_t
*
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
rxdataF_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_estimates_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
}
for
(
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
{
//ue_pdcch_vars[eNB_id]->rho[i] = (int32_t*)malloc16_clear( sizeof(int32_t)*(fp->N_RB_DL*12*7*2) );
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
rho
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
(
100
*
12
*
4
)
);
}
for
(
j
=
0
;
j
<
4
;
j
++
)
{
//fp->nb_antennas_tx; j++)
int
idx
=
(
j
<<
1
)
+
i
;
// size_t num = 7*2*fp->N_RB_DL*12;
size_t
num
=
4
*
100
*
12
;
// 4 symbols, 100 PRBs, 12 REs per PRB
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
rxdataF_comp
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_rho_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
rxdataF_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
(
*
pdcch_vars_th
)[
th_id
][
eNB_id
]
->
dl_ch_estimates_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
num
);
}
}
}
// PBCH
pbch_vars
[
eNB_id
]
->
rxdataF_ext
=
(
int32_t
**
)
malloc16
(
fp
->
nb_antennas_rx
*
sizeof
(
int32_t
*
)
);
pbch_vars
[
eNB_id
]
->
rxdataF_comp
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pbch_vars
[
eNB_id
]
->
dl_ch_estimates_ext
=
(
int32_t
**
)
malloc16_clear
(
8
*
sizeof
(
int32_t
*
)
);
pbch_vars
[
eNB_id
]
->
llr
=
(
int8_t
*
)
malloc16_clear
(
1920
);
prach_vars
[
eNB_id
]
->
prachF
=
(
int16_t
*
)
malloc16_clear
(
sizeof
(
int
)
*
(
7
*
2
*
sizeof
(
int
)
*
(
fp
->
ofdm_symbol_size
*
12
))
);
prach_vars
[
eNB_id
]
->
prach
=
(
int16_t
*
)
malloc16_clear
(
sizeof
(
int
)
*
(
7
*
2
*
sizeof
(
int
)
*
(
fp
->
ofdm_symbol_size
*
12
))
);
for
(
i
=
0
;
i
<
fp
->
nb_antennas_rx
;
i
++
)
{
pbch_vars
[
eNB_id
]
->
rxdataF_ext
[
i
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
6
*
12
*
4
);
for
(
j
=
0
;
j
<
4
;
j
++
)
{
//fp->nb_antennas_tx;j++) {
int
idx
=
(
j
<<
1
)
+
i
;
pbch_vars
[
eNB_id
]
->
rxdataF_comp
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
6
*
12
*
4
);
pbch_vars
[
eNB_id
]
->
dl_ch_estimates_ext
[
idx
]
=
(
int32_t
*
)
malloc16_clear
(
sizeof
(
int32_t
)
*
6
*
12
*
4
);
}
}
}
pbch_vars
[
eNB_id
]
->
decoded_output
=
(
uint8_t
*
)
malloc16_clear
(
64
);
}
// initialization for the last instance of pdsch_vars (used for MU-MIMO)
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
)
);
}
pdsch_vars_SI
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
)
);
pdsch_vars_ra
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
)
);
pdsch_vars_p
[
eNB_id
]
=
(
NR_UE_PDSCH
*
)
malloc16_clear
(
sizeof
(
NR_UE_PDSCH
)
);
if
(
abstraction_flag
==
0
)
{
for
(
th_id
=
0
;
th_id
<
RX_NB_TH_MAX
;
th_id
++
)
{
phy_init_lte_ue__PDSCH
(
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
],
fp
);
(
*
pdsch_vars_th
)[
th_id
][
eNB_id
]
->
llr
[
1
]
=
(
int16_t
*
)
malloc16_clear
(
(
8
*
((
3
*
8
*
8448
)
+
12
))
*
sizeof
(
int16_t
)
);
}
}
else
{
//abstraction == 1
ue
->
sinr_dB
=
(
double
*
)
malloc16_clear
(
fp
->
N_RB_DL
*
12
*
sizeof
(
double
)
);
}
ue
->
sinr_CQI_dB
=
(
double
*
)
malloc16_clear
(
fp
->
N_RB_DL
*
12
*
sizeof
(
double
)
);
ue
->
init_averaging
=
1
;
// default value until overwritten by RRCConnectionReconfiguration
if
(
fp
->
nb_antenna_ports_eNB
==
2
)
ue
->
pdsch_config_dedicated
->
p_a
=
dBm3
;
else
ue
->
pdsch_config_dedicated
->
p_a
=
dB0
;
// set channel estimation to do linear interpolation in time
ue
->
high_speed_flag
=
1
;
ue
->
ch_est_alpha
=
24576
;
// enable MIB/SIB decoding by default
ue
->
decode_MIB
=
1
;
ue
->
decode_SIB
=
1
;
init_prach_tables
(
839
);
return
0
;
}
/*
void nr_lte_ue_transport(PHY_VARS_UE *ue,int abstraction_flag) {
int i,j,k;
for (i=0; i<NUMBER_OF_CONNECTED_eNB_MAX; i++) {
for (j=0; j<2; j++) {
for (k=0; k<2; k++) {
AssertFatal((ue->dlsch[k][i][j] = new_ue_dlsch(1,NUMBER_OF_HARQ_PID_MAX,NSOFT,MAX_TURBO_ITERATIONS,ue->frame_parms.N_RB_DL, abstraction_flag))!=NULL,"Can't get ue dlsch structures\n");
LOG_D(PHY,"dlsch[%d][%d][%d] => %p\n",k,i,j,ue->dlsch[i][j]);
}
}
AssertFatal((ue->ulsch[i] = new_ue_ulsch(ue->frame_parms.N_RB_UL, abstraction_flag))!=NULL,"Can't get ue ulsch structures\n");
ue->dlsch_SI[i] = new_ue_dlsch(1,1,NSOFT,MAX_TURBO_ITERATIONS,ue->frame_parms.N_RB_DL, abstraction_flag);
ue->dlsch_ra[i] = new_ue_dlsch(1,1,NSOFT,MAX_TURBO_ITERATIONS,ue->frame_parms.N_RB_DL, abstraction_flag);
ue->transmission_mode[i] = ue->frame_parms.nb_antenna_ports_eNB==1 ? 1 : 2;
}
ue->frame_parms.pucch_config_common.deltaPUCCH_Shift = 1;
ue->dlsch_MCH[0] = new_ue_dlsch(1,NUMBER_OF_HARQ_PID_MAX,NSOFT,MAX_TURBO_ITERATIONS_MBSFN,ue->frame_parms.N_RB_DL,0);
}*/
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