phy_procedures_lte_eNb.c 140 KB
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/*******************************************************************************

  Eurecom OpenAirInterface
  Copyright(c) 1999 - 2011 Eurecom

  This program is free software; you can redistribute it and/or modify it
  under the terms and conditions of the GNU General Public License,
  version 2, as published by the Free Software Foundation.

  This program is distributed in the hope it will be useful, but WITHOUT
  ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
  more details.

  You should have received a copy of the GNU General Public License along with
  this program; if not, write to the Free Software Foundation, Inc.,
  51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA.

  The full GNU General Public License is included in this distribution in
  the file called "COPYING".

  Contact Information
  Openair Admin: openair_admin@eurecom.fr
  Openair Tech : openair_tech@eurecom.fr
  Forums       : http://forums.eurecom.fsr/openairinterface
  Address      : Eurecom, 2229, route des crêtes, 06560 Valbonne Sophia Antipolis, France

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*******************************************************************************/
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/*! \file phy_procedures_lte_eNB.c
 * \brief Implementation of eNB procedures from 36.213 LTE specifications
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 * \author R. Knopp, F. Kaltenberger, N. Nikaein
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 * \date 2011
 * \version 0.1
 * \company Eurecom
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 * \email: knopp@eurecom.fr,florian.kaltenberger@eurecom.fr,navid.nikaein@eurecom.fr
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 * \note
 * \warning
 */

#include "PHY/defs.h"
#include "PHY/extern.h"
#include "MAC_INTERFACE/defs.h"
#include "MAC_INTERFACE/extern.h"
#include "SCHED/defs.h"
#include "SCHED/extern.h"

#ifdef EMOS
#include "SCHED/phy_procedures_emos.h"
#endif

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#define DEBUG_PHY_PROC
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//#define DEBUG_ULSCH

#include "ARCH/CBMIMO1/DEVICE_DRIVER/extern.h"
#include "ARCH/CBMIMO1/DEVICE_DRIVER/defs.h"
#include "ARCH/CBMIMO1/DEVICE_DRIVER/from_grlib_softregs.h"

//#ifdef OPENAIR2
#include "LAYER2/MAC/extern.h"
#include "LAYER2/MAC/defs.h"
#include "UTIL/LOG/log.h"
#include "UTIL/LOG/vcd_signal_dumper.h"
//#endif

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#include "assertions.h"

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#if defined(ENABLE_ITTI)
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#   include "intertask_interface.h"
#   if defined(ENABLE_RAL)
#     include "timer.h"
#   endif
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#endif

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//#define DIAG_PHY

#define NS_PER_SLOT 500000

#define PUCCH 1

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#define PUCCH1_THRES 15
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#define PUCCH1a_THRES 15
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extern inline unsigned int taus(void);
extern int exit_openair;
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//extern void do_OFDM_mod(mod_sym_t **txdataF, int32_t **txdata, uint32_t frame, uint16_t next_slot, LTE_DL_FRAME_PARMS *frame_parms);
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unsigned char dlsch_input_buffer[2700] __attribute__ ((aligned(16)));
int eNB_sync_buffer0[640*6] __attribute__ ((aligned(16)));
int eNB_sync_buffer1[640*6] __attribute__ ((aligned(16)));
int *eNB_sync_buffer[2] = {eNB_sync_buffer0, eNB_sync_buffer1};


unsigned int max_peak_val; 
int max_sect_id, max_sync_pos;

//DCI_ALLOC_t dci_alloc[8];

#ifdef EMOS
fifo_dump_emos_eNB emos_dump_eNB;
#endif

#if defined(SMBV) && !defined(EXMIMO)
extern const char smbv_fname[];
extern unsigned short config_frames[4];
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extern uint8_t smbv_frame_cnt;
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#endif

#ifdef DIAG_PHY
extern int rx_sig_fifo;
#endif
static unsigned char I0_clear = 1;

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uint8_t is_SR_subframe(PHY_VARS_eNB *phy_vars_eNB,uint8_t UE_id,uint8_t subframe) {
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  LOG_D(PHY,"[eNB %d][SR %x] Frame %d subframe %d Checking for SR TXOp(sr_ConfigIndex %d)\n",
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	phy_vars_eNB->Mod_id,phy_vars_eNB->ulsch_eNB[UE_id]->rnti,phy_vars_eNB->proc[subframe].frame_rx,subframe,
	phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex);
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  if (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex <= 4) {        // 5 ms SR period
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    if ((subframe%5) == phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex)
      return(1);
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  }
  else if (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex <= 14) {  // 10 ms SR period
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    if (subframe==(phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex-5))
      return(1);
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  }
  else if (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex <= 34) { // 20 ms SR period
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    if ((10*(phy_vars_eNB->proc[subframe].frame_rx&1)+subframe) == (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex-15))
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      return(1);
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  }
  else if (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex <= 74) { // 40 ms SR period
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    if ((10*(phy_vars_eNB->proc[subframe].frame_rx&3)+subframe) == (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex-35))
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      return(1);
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  }
  else if (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex <= 154) { // 80 ms SR period
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    if ((10*(phy_vars_eNB->proc[subframe].frame_rx&7)+subframe) == (phy_vars_eNB->scheduling_request_config[UE_id].sr_ConfigIndex-75))
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      return(1);
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  }

  return(0);
}
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int32_t add_ue(int16_t rnti, PHY_VARS_eNB *phy_vars_eNB) {
  uint8_t i;
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  //#ifdef DEBUG_PHY_PROC
  LOG_I(PHY,"[eNB %d] Adding UE with rnti %x\n",phy_vars_eNB->Mod_id,rnti);
  //#endif
  for (i=0;i<NUMBER_OF_UE_MAX;i++) {
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    if ((phy_vars_eNB->dlsch_eNB[i]==NULL) || (phy_vars_eNB->ulsch_eNB[i]==NULL)) {
      LOG_E(PHY,"Can't add UE, not enough memory allocated\n");
      return(-1);
    }
    else {
      if (phy_vars_eNB->eNB_UE_stats[i].crnti==0) {
	LOG_I(PHY,"UE_id %d associated with rnti %x\n",i, rnti);
	phy_vars_eNB->dlsch_eNB[i][0]->rnti = rnti;
	phy_vars_eNB->ulsch_eNB[i]->rnti = rnti;
	phy_vars_eNB->eNB_UE_stats[i].crnti = rnti;
	return(i);
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      }
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    }
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  }
  return(-1);
}

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int32_t remove_ue(uint16_t rnti, PHY_VARS_eNB *phy_vars_eNB, uint8_t abstraction_flag) {
  uint8_t i;
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  //#ifdef DEBUG_PHY_PROC
  LOG_I(PHY,"eNB %d removing UE with rnti %x\n",phy_vars_eNB->Mod_id,rnti);
  //#endif
  for (i=0;i<NUMBER_OF_UE_MAX;i++) {
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    if ((phy_vars_eNB->dlsch_eNB[i]==NULL) || (phy_vars_eNB->ulsch_eNB[i]==NULL)) {
      LOG_E(PHY,"Can't remove UE, not enough memory allocated\n");
      return(-1);
    }
    else {
      if (phy_vars_eNB->eNB_UE_stats[i].crnti==rnti) {
	//msg("[PHY] UE_id %d\n",i);
	clean_eNb_dlsch(phy_vars_eNB->dlsch_eNB[i][0], abstraction_flag);
	clean_eNb_ulsch(phy_vars_eNB->ulsch_eNB[i],abstraction_flag);
	//phy_vars_eNB->eNB_UE_stats[i].crnti = 0;
	memset(&phy_vars_eNB->eNB_UE_stats[i],0,sizeof(LTE_eNB_UE_stats));
	return(i);
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      }
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    }
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  }

  return(-1);
}

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int8_t find_next_ue_index(PHY_VARS_eNB *phy_vars_eNB) {
  uint8_t i;
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  for (i=0;i<NUMBER_OF_UE_MAX;i++) {
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    if (phy_vars_eNB->eNB_UE_stats[i].crnti==0) {
      /*if ((phy_vars_eNB->dlsch_eNB[i]) && 
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	(phy_vars_eNB->dlsch_eNB[i][0]) && 
	(phy_vars_eNB->dlsch_eNB[i][0]->rnti==0))*/ 
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      LOG_D(PHY,"Next free UE id is %d\n",i);
      return(i);
    }
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  }
  return(-1);
}

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int get_ue_active_harq_pid(uint8_t Mod_id,uint16_t rnti,uint8_t subframe,uint8_t *harq_pid,uint8_t *round,uint8_t ul_flag) {
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  LTE_eNB_DLSCH_t *DLSCH_ptr;  
  LTE_eNB_ULSCH_t *ULSCH_ptr;  
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  //  uint8_t subframe_m4;
  uint8_t ulsch_subframe,ulsch_frame; 
  uint8_t i;
  int8_t UE_id = find_ue(rnti,PHY_vars_eNB_g[Mod_id]);
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  int subframe_sched = (subframe == 9) ? 0 : (subframe+1);
  uint32_t frame;

  frame = PHY_vars_eNB_g[Mod_id]->proc[subframe_sched].frame_tx;
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  if (UE_id==-1) {
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    LOG_E(PHY,"Cannot find UE with rnti %x\n",rnti);
    *round=0;
    return(-1);
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  }

  if (ul_flag == 0)  {// this is a DL request
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    DLSCH_ptr = PHY_vars_eNB_g[Mod_id]->dlsch_eNB[(uint32_t)UE_id][0];
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    /*    
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	  if (subframe<4)
	  subframe_m4 = subframe+6;
	  else
	  subframe_m4 = subframe-4;
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    */
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#ifdef DEBUG_PHY_PROC
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    LOG_D(PHY,"[eNB %d] get_ue_active_harq_pid: Frame %d subframe %d, current harq_id %d\n",
	  Mod_id,frame,subframe,DLSCH_ptr->harq_ids[subframe]);
#endif
    // switch on TDD or FDD configuration here later
    *harq_pid = DLSCH_ptr->harq_ids[subframe];
    if ((*harq_pid<DLSCH_ptr->Mdlharq) && 
	((DLSCH_ptr->harq_processes[*harq_pid]->round > 0))) {

      *round = DLSCH_ptr->harq_processes[*harq_pid]->round;
      LOG_D(PHY,"round %d\n",*round);
    
      //    else if ((subframe_m4==5) || (subframe_m4==6)) {
      //      *harq_pid = 0;//DLSCH_ptr->harq_ids[subframe_m4];//Ankit
      //     *round    = DLSCH_ptr->harq_processes[*harq_pid]->round;
      //    }
    }
    else {
      // get first free harq_pid (i.e. round 0)
      for (i=0;i<DLSCH_ptr->Mdlharq;i++) {
	if (DLSCH_ptr->harq_processes[i]!=NULL) {
	  if (DLSCH_ptr->harq_processes[i]->status != ACTIVE) {
	    *harq_pid = i;//0;//i; //(Ankit)
	    *round = 0;
	    return(0);
	  }
	  else {
	    LOG_D(PHY,"process %d is active\n",i);
	  }
	}
	else {
	  LOG_E(PHY,"[eNB %d] DLSCH process %d for rnti %x (UE_id %d) not allocated\n",Mod_id,i,rnti,UE_id);
	  return(-1);
	}
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      }
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    }
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  }
  else {  // This is a UL request

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    ULSCH_ptr = PHY_vars_eNB_g[Mod_id]->ulsch_eNB[(uint32_t)UE_id];
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    ulsch_subframe = pdcch_alloc2ul_subframe(&PHY_vars_eNB_g[Mod_id]->lte_frame_parms,subframe);
    ulsch_frame    = pdcch_alloc2ul_frame(&PHY_vars_eNB_g[Mod_id]->lte_frame_parms,frame,subframe);
    // Note this is for TDD configuration 3,4,5 only
    *harq_pid = subframe2harq_pid(&PHY_vars_eNB_g[Mod_id]->lte_frame_parms,
				  ulsch_frame,
				  ulsch_subframe);
    *round    = ULSCH_ptr->harq_processes[*harq_pid]->round;
    LOG_D(PHY,"[eNB %d][PUSCH %d] Frame %d subframe %d Checking HARQ, round %d\n",Mod_id,*harq_pid,frame,subframe,*round);
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  }
  return(0);
}


int CCE_table[800];

void init_nCCE_table(void) {
  memset(CCE_table,0,800*sizeof(int));
}


int get_nCCE_offset(unsigned char L, int nCCE, int common_dci, unsigned short rnti, unsigned char subframe) {

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  int search_space_free,m,nb_candidates = 0,l,i;
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  unsigned int Yk;
  /*
    printf("CCE Allocation: ");
    for (i=0;i<nCCE;i++)
    printf("%d.",CCE_table[i]);
    printf("\n");
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  */
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  if (common_dci == 1) {
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    // check CCE(0 ... L-1)
    nb_candidates = (L==4) ? 4 : 2;
    for (m = 0 ; m < nb_candidates ; m++) {
      search_space_free = 1;
      for (l=0;l<L;l++) {
	if (CCE_table[(m*L) + l] == 1) {
	  search_space_free = 0;
	  break;
	}
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      }
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      if (search_space_free == 1) {
	for (l=0;l<L;l++)
	  CCE_table[(m*L)+l]=1;
	return(m*L);
      }
    }
    return(-1);
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  }
  else {  // Find first available in ue specific search space
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          // according to procedure in Section 9.1.1 of 36.213 (v. 8.6)
    // compute Yk
    Yk = (unsigned int)rnti;

    for (i=0;i<=subframe;i++)
      Yk = (Yk*39827)%65537;

    Yk = Yk % (nCCE/L);


    switch (L) {
    case 1:
    case 2:
      nb_candidates = 6;
      break;
    case 4:
    case 8:
      nb_candidates = 2;
      break;
    default:
      DevParam(L, nCCE, rnti);
      break;
    }

    //        LOG_I(PHY,"rnti %x, Yk = %d, nCCE %d (nCCE/L %d),nb_cand %d\n",rnti,Yk,nCCE,nCCE/L,nb_candidates);

    for (m = 0 ; m < nb_candidates ; m++) {
      search_space_free = 1;
      for (l=0;l<L;l++) {
	if (CCE_table[(((Yk+m)%(nCCE/L))*L) + l] == 1) {
	  search_space_free = 0;
	  break;
	}
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      }
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      if (search_space_free == 1) {
	for (l=0;l<L;l++)
	  CCE_table[(((Yk+m)%(nCCE/L))*L)+l]=1;
	return(((Yk+m)%(nCCE/L))*L);
      }
    }
    return(-1);
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  }
}

#ifdef EMOS
void phy_procedures_emos_eNB_TX(unsigned char next_slot, PHY_VARS_eNB *phy_vars_eNB) {

}
#endif

/*
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  void phy_procedures_eNB_S_TX(unsigned char next_slot,PHY_VARS_eNB *phy_vars_eNB,uint8_t abstraction_flag) {
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  int sect_id = 0, aa;

  if (next_slot%2==0) {
  #ifdef DEBUG_PHY_PROC
  msg("[PHY][eNB %d] Frame %d, slot %d: Generating pilots for DL-S\n",
  phy_vars_eNB->Mod_id,phy_vars_eNB->frame,next_slot);
  #endif
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  for (sect_id=0;sect_id<number_of_cards;sect_id++) {
  if (abstraction_flag == 0) {

  for (aa=0; aa<phy_vars_eNB->lte_frame_parms.nb_antennas_tx; aa++) {
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  #ifdef IFFT_FPGA
  memset(&phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id][aa][next_slot*(phy_vars_eNB->lte_frame_parms.N_RB_DL*12)*(phy_vars_eNB->lte_frame_parms.symbols_per_tti>>1)],
  0,(phy_vars_eNB->lte_frame_parms.N_RB_DL*12)*(phy_vars_eNB->lte_frame_parms.symbols_per_tti>>1)*sizeof(mod_sym_t));
  #else
  memset(&phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id][aa][next_slot*phy_vars_eNB->lte_frame_parms.ofdm_symbol_size*(phy_vars_eNB->lte_frame_parms.symbols_per_tti>>1)],
  0,phy_vars_eNB->lte_frame_parms.ofdm_symbol_size*(phy_vars_eNB->lte_frame_parms.symbols_per_tti>>1)*sizeof(mod_sym_t));
  #endif
  }

  generate_pilots_slot(phy_vars_eNB,
  phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
  AMP,
  next_slot);

  msg("[PHY][eNB] Frame %d, subframe %d Generating PSS\n",
  phy_vars_eNB->frame,next_slot>>1);
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  generate_pss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
  4*AMP,
  &phy_vars_eNB->lte_frame_parms,
  2,
  next_slot);
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  }
  else {
  #ifdef PHY_ABSTRACTION
  generate_pss_emul(phy_vars_eNB,sect_id);
  #endif
  }
  }
  }
  }
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*/ 
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void phy_procedures_eNB_S_RX(unsigned char subframe,PHY_VARS_eNB *phy_vars_eNB,uint8_t abstraction_flag,relaying_type_t r_type) {
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  unsigned char sect_id=0; 

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#ifdef DEBUG_PHY_PROC
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  LOG_D(PHY,"[eNB %d] Frame %d: Doing phy_procedures_eNB_S_RX(%d)\n", phy_vars_eNB->Mod_id,phy_vars_eNB->proc[subframe].frame_rx, subframe);
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#endif    
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  for (sect_id=0;sect_id<number_of_cards;sect_id++) {
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    if (abstraction_flag == 0) {
      lte_eNB_I0_measurements(phy_vars_eNB,
			      sect_id,
			      phy_vars_eNB->first_run_I0_measurements);
    }
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#ifdef PHY_ABSTRACTION
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    else {
      lte_eNB_I0_measurements_emul(phy_vars_eNB,
				   sect_id);
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    }
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#endif
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  }
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  if (I0_clear == 1)
    I0_clear = 0;
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}

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#ifdef EMOS
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void phy_procedures_emos_eNB_RX(unsigned char subframe,PHY_VARS_eNB *phy_vars_eNB) {
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  uint8_t aa;
  uint16_t last_subframe_emos;
  uint16_t pilot_pos1 = 3 - phy_vars_eNB->lte_frame_parms.Ncp, pilot_pos2 = 10 - 2*phy_vars_eNB->lte_frame_parms.Ncp;
  uint32_t bytes;
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  last_subframe_emos=0;

#ifdef EMOS_CHANNEL
  //if (last_slot%2==1) // this is for all UL subframes
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  if (subframe==3) 
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    for (aa=0; aa<phy_vars_eNB->lte_frame_parms.nb_antennas_rx; aa++) {
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      memcpy(&emos_dump_eNB.channel[aa][last_subframe_emos*2*phy_vars_eNB->lte_frame_parms.N_RB_UL*12],              
	     &phy_vars_eNB->lte_eNB_pusch_vars[0]->drs_ch_estimates[0][aa][phy_vars_eNB->lte_frame_parms.N_RB_UL*12*pilot_pos1],
	     phy_vars_eNB->lte_frame_parms.N_RB_UL*12*sizeof(int));
      memcpy(&emos_dump_eNB.channel[aa][(last_subframe_emos*2+1)*phy_vars_eNB->lte_frame_parms.N_RB_UL*12],          
	     &phy_vars_eNB->lte_eNB_pusch_vars[0]->drs_ch_estimates[0][aa][phy_vars_eNB->lte_frame_parms.N_RB_UL*12*pilot_pos2],
	     phy_vars_eNB->lte_frame_parms.N_RB_UL*12*sizeof(int));
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    }
#endif

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  if (subframe==4) {
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    emos_dump_eNB.timestamp = rt_get_time_ns();
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    emos_dump_eNB.frame_tx = phy_vars_eNB->proc[subframe].frame;
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    emos_dump_eNB.rx_total_gain_dB = phy_vars_eNB->rx_total_gain_eNB_dB;
    emos_dump_eNB.mimo_mode = phy_vars_eNB->transmission_mode[0];
    memcpy(&emos_dump_eNB.PHY_measurements_eNB,
           &phy_vars_eNB->PHY_measurements_eNB[0],
           sizeof(PHY_MEASUREMENTS_eNB));
    memcpy(&emos_dump_eNB.eNB_UE_stats[0],&phy_vars_eNB->eNB_UE_stats[0],NUMBER_OF_UE_MAX*sizeof(LTE_eNB_UE_stats));

    bytes = rtf_put(CHANSOUNDER_FIFO_MINOR, &emos_dump_eNB, sizeof(fifo_dump_emos_eNB));
    //bytes = rtf_put(CHANSOUNDER_FIFO_MINOR, "test", sizeof("test"));
    if (bytes!=sizeof(fifo_dump_emos_eNB)) {
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      LOG_W(PHY,"[eNB %d] Frame %d, subframe %d, Problem writing EMOS data to FIFO (bytes=%d, size=%d)\n",
            phy_vars_eNB->Mod_id,phy_vars_eNB->frame, subframe,bytes,sizeof(fifo_dump_emos_eNB));
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    }
    else {
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      if (phy_vars_eNB->proc[(subframe+1)%10].frame_tx%100==0) {
        LOG_I(PHY,"[eNB %d] Frame %d (%d), subframe %d, Writing %d bytes EMOS data to FIFO\n",
              phy_vars_eNB->Mod_id,phy_vars_eNB->proc[(subframe+1)%10]->frame_tx, ((fifo_dump_emos_eNB*)&emos_dump_eNB)->frame_tx, subframe, bytes);
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      }
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    }
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  }
}
#endif

#ifndef OPENAIR2
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void fill_dci(DCI_PDU *DCI_pdu, uint8_t subframe, PHY_VARS_eNB *phy_vars_eNB) {
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  int i;
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  uint8_t cooperation_flag = phy_vars_eNB->cooperation_flag;
  uint8_t transmission_mode = phy_vars_eNB->transmission_mode[0];
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  uint32_t rballoc = 0x7FFF;
  uint32_t rballoc2 = 0x000F;
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  int sched_subframe = (subframe == 0) ? 9 : (subframe-1);
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  /*
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    uint32_t rand = taus();
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    if ((subframe==8) || (subframe==9) || (subframe==0))
    rand = (rand%5)+5;
    else
    rand = (rand%4)+5;
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  */
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  DCI_pdu->Num_common_dci = 0;
  DCI_pdu->Num_ue_spec_dci=0;

  switch (subframe) {
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  case 5:
    DCI_pdu->Num_common_dci = 1;
    DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1A_5MHz_TDD_1_6_t;
    DCI_pdu->dci_alloc[0].L          = 2;
    DCI_pdu->dci_alloc[0].rnti       = SI_RNTI;
    DCI_pdu->dci_alloc[0].format     = format1A;
    DCI_pdu->dci_alloc[0].ra_flag    = 0;
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    BCCH_alloc_pdu.type              = 1;
    BCCH_alloc_pdu.vrb_type          = 0;
    BCCH_alloc_pdu.rballoc           = computeRIV(25,10,3);
    BCCH_alloc_pdu.ndi               = phy_vars_eNB->proc[sched_subframe].frame_tx&1;
    BCCH_alloc_pdu.rv                = 1;
    BCCH_alloc_pdu.mcs               = 1;
    BCCH_alloc_pdu.harq_pid          = 0;
    BCCH_alloc_pdu.TPC               = 1;      // set to 3 PRB
    memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],&BCCH_alloc_pdu,sizeof(DCI1A_5MHz_TDD_1_6_t));
    break;
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  case 6:
    /*
      DCI_pdu->Num_ue_spec_dci = 1;
      DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI2_5MHz_2A_M10PRB_TDD_t;
      DCI_pdu->dci_alloc[0].L          = 2;
      DCI_pdu->dci_alloc[0].rnti       = 0x1236;
      DCI_pdu->dci_alloc[0].format     = format2_2A_M10PRB;
      DCI_pdu->dci_alloc[0].ra_flag    = 0;

      DLSCH_alloc_pdu1.rballoc          = 0x00ff;
      DLSCH_alloc_pdu1.TPC              = 0;
      DLSCH_alloc_pdu1.dai              = 0;
      DLSCH_alloc_pdu1.harq_pid         = 0;
      DLSCH_alloc_pdu1.tb_swap          = 0;
      DLSCH_alloc_pdu1.mcs1             = 0;
      DLSCH_alloc_pdu1.ndi1             = 1;
      DLSCH_alloc_pdu1.rv1              = 0;
      DLSCH_alloc_pdu1.tpmi             = 0;
      memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&DLSCH_alloc_pdu1,sizeof(DCI2_5MHz_2A_M10PRB_TDD_t));
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    */
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    break;
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  case 7:
    DCI_pdu->Num_ue_spec_dci = 1;
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    if (transmission_mode<3) {
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      //user 1
      DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1_5MHz_TDD_t; 
      DCI_pdu->dci_alloc[0].L          = 2;
      DCI_pdu->dci_alloc[0].rnti       = 0x1235;
      DCI_pdu->dci_alloc[0].format     = format1;
      DCI_pdu->dci_alloc[0].ra_flag    = 0;
      
      DLSCH_alloc_pdu.rballoc          = rballoc;
      DLSCH_alloc_pdu.TPC              = 0;
      DLSCH_alloc_pdu.dai              = 0;
      DLSCH_alloc_pdu.harq_pid         = 0;
      DLSCH_alloc_pdu.mcs              = openair_daq_vars.target_ue_dl_mcs;
      //DLSCH_alloc_pdu.mcs              = (unsigned char) ((phy_vars_eNB->frame%1024)%28);      
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      DLSCH_alloc_pdu.ndi              = phy_vars_eNB->proc[sched_subframe].frame_tx&1;
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      DLSCH_alloc_pdu.rv               = 0;
      memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&DLSCH_alloc_pdu,sizeof(DCI1_5MHz_TDD_t));

      /*
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      //user2
      DCI_pdu->dci_alloc[1].dci_length = sizeof_DCI1_5MHz_TDD_t; 
      DCI_pdu->dci_alloc[1].L          = 2;
      DCI_pdu->dci_alloc[1].rnti       = 0x1236;
      DCI_pdu->dci_alloc[1].format     = format1;
      DCI_pdu->dci_alloc[1].ra_flag    = 0;

      DLSCH_alloc_pdu.rballoc          = rballoc2;
      DLSCH_alloc_pdu.TPC              = 0;
      DLSCH_alloc_pdu.dai              = 0;
      DLSCH_alloc_pdu.harq_pid         = 1;
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      //DLSCH_alloc_pdu.mcs              = (unsigned char) ((phy_vars_eNB->proc[subframe].frame%1024)%28);      
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      DLSCH_alloc_pdu.mcs              = openair_daq_vars.target_ue_dl_mcs;
      DLSCH_alloc_pdu.ndi              = 1;
      DLSCH_alloc_pdu.rv               = 0;
      memcpy((void*)&DCI_pdu->dci_alloc[1].dci_pdu[0],(void *)&DLSCH_alloc_pdu,sizeof(DCI1_5MHz_TDD_t));
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      */
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    }
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    else if (transmission_mode==5) {
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      DCI_pdu->Num_ue_spec_dci = 2;
      // user 1
      DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1E_5MHz_2A_M10PRB_TDD_t; 
      DCI_pdu->dci_alloc[0].L          = 3;
      DCI_pdu->dci_alloc[0].rnti       = 0x1235;
      DCI_pdu->dci_alloc[0].format     = format1E_2A_M10PRB;
      DCI_pdu->dci_alloc[0].ra_flag    = 0;
      
      DLSCH_alloc_pdu1E.tpmi             = 5; //5=use feedback
      DLSCH_alloc_pdu1E.rv               = 0;
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      DLSCH_alloc_pdu1E.ndi              = phy_vars_eNB->proc[sched_subframe].frame_tx&1;
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      //DLSCH_alloc_pdu1E.mcs            = cqi_to_mcs[phy_vars_eNB->eNB_UE_stats->DL_cqi[0]];
      //DLSCH_alloc_pdu1E.mcs            = (unsigned char) (taus()%28);
      DLSCH_alloc_pdu1E.mcs              = openair_daq_vars.target_ue_dl_mcs;
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      //DLSCH_alloc_pdu1E.mcs            = (unsigned char) ((phy_vars_eNB->proc[subframe].frame%1024)%28);      
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      phy_vars_eNB->eNB_UE_stats[0].dlsch_mcs1 = DLSCH_alloc_pdu1E.mcs;
      DLSCH_alloc_pdu1E.harq_pid         = 0;
      DLSCH_alloc_pdu1E.dai              = 0;
      DLSCH_alloc_pdu1E.TPC              = 0;
      DLSCH_alloc_pdu1E.rballoc          = openair_daq_vars.ue_dl_rb_alloc;
      DLSCH_alloc_pdu1E.rah              = 0;
      DLSCH_alloc_pdu1E.dl_power_off     = 0; //0=second user present
      memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&DLSCH_alloc_pdu1E,sizeof(DCI1E_5MHz_2A_M10PRB_TDD_t));
      
      //user 2
      DCI_pdu->dci_alloc[1].dci_length = sizeof_DCI1E_5MHz_2A_M10PRB_TDD_t; 
      DCI_pdu->dci_alloc[1].L          = 0;
      DCI_pdu->dci_alloc[1].rnti       = 0x1236;
      DCI_pdu->dci_alloc[1].format     = format1E_2A_M10PRB;
      DCI_pdu->dci_alloc[1].ra_flag    = 0;
      //DLSCH_alloc_pdu1E.mcs            = openair_daq_vars.target_ue_dl_mcs; 
      //DLSCH_alloc_pdu1E.mcs            = (unsigned char) (taus()%28);
      //DLSCH_alloc_pdu1E.mcs            = (unsigned char) ((phy_vars_eNB->frame%1024)%28);
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      DLSCH_alloc_pdu1E.mcs            = (unsigned char) (((phy_vars_eNB->proc[sched_subframe].frame_tx%1024)/3)%28);
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      phy_vars_eNB->eNB_UE_stats[1].dlsch_mcs1 = DLSCH_alloc_pdu1E.mcs;
      
      memcpy((void*)&DCI_pdu->dci_alloc[1].dci_pdu[0],(void *)&DLSCH_alloc_pdu1E,sizeof(DCI1E_5MHz_2A_M10PRB_TDD_t));

      // set the precoder of the second UE orthogonal to the first
      phy_vars_eNB->eNB_UE_stats[1].DL_pmi_single = (phy_vars_eNB->eNB_UE_stats[0].DL_pmi_single ^ 0x1555); 
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    }
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    break;
    /*
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      case 8:
      DCI_pdu->Num_common_dci = 1;
      DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1A_5MHz_TDD_1_6_t;
      DCI_pdu->dci_alloc[0].L          = 2;
      DCI_pdu->dci_alloc[0].rnti       = 0xbeef;
      DCI_pdu->dci_alloc[0].format     = format1A;
      DCI_pdu->dci_alloc[0].ra_flag    = 1;

      RA_alloc_pdu.type                = 1;
      RA_alloc_pdu.vrb_type            = 0;
      RA_alloc_pdu.rballoc             = computeRIV(25,12,3);
      RA_alloc_pdu.ndi      = 1;
      RA_alloc_pdu.rv       = 1;
      RA_alloc_pdu.mcs      = 4;
      RA_alloc_pdu.harq_pid = 0;
      RA_alloc_pdu.TPC      = 1;

      memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],&RA_alloc_pdu,sizeof(DCI1A_5MHz_TDD_1_6_t));
      break;
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    */
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  case 9:
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    DCI_pdu->Num_ue_spec_dci = 2;
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    //user 1
    DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI0_5MHz_TDD_1_6_t ; 
    DCI_pdu->dci_alloc[0].L          = 2;
    DCI_pdu->dci_alloc[0].rnti       = 0x1235;
    DCI_pdu->dci_alloc[0].format     = format0;
    DCI_pdu->dci_alloc[0].ra_flag    = 0;

    UL_alloc_pdu.type    = 0;
    UL_alloc_pdu.hopping = 0;
    UL_alloc_pdu.rballoc = computeRIV(25,2,openair_daq_vars.ue_ul_nb_rb);
    UL_alloc_pdu.mcs     = openair_daq_vars.target_ue_ul_mcs;
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    UL_alloc_pdu.ndi     = phy_vars_eNB->proc[sched_subframe].frame_tx&1;
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    UL_alloc_pdu.TPC     = 0;
    UL_alloc_pdu.cshift  = 0;
    UL_alloc_pdu.dai     = 0;
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    UL_alloc_pdu.cqi_req = 1;
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    memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&UL_alloc_pdu,sizeof(DCI0_5MHz_TDD_1_6_t));
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    DCI_pdu->dci_alloc[1].dci_length = sizeof_DCI0_5MHz_TDD_1_6_t ; 
    DCI_pdu->dci_alloc[1].L          = 2;
    DCI_pdu->dci_alloc[1].rnti       = 0x1236;
    DCI_pdu->dci_alloc[1].format     = format0;
    DCI_pdu->dci_alloc[1].ra_flag    = 0;

    UL_alloc_pdu.type    = 0;
    UL_alloc_pdu.hopping = 0;
    if (cooperation_flag==0)
      UL_alloc_pdu.rballoc = computeRIV(25,2+openair_daq_vars.ue_ul_nb_rb,openair_daq_vars.ue_ul_nb_rb);
    else 
      UL_alloc_pdu.rballoc = computeRIV(25,0,openair_daq_vars.ue_ul_nb_rb);
    UL_alloc_pdu.mcs     = openair_daq_vars.target_ue_ul_mcs;
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    UL_alloc_pdu.ndi     = phy_vars_eNB->proc[sched_subframe].frame_tx&1;
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    UL_alloc_pdu.TPC     = 0;
    if ((cooperation_flag==0) || (cooperation_flag==1))
      UL_alloc_pdu.cshift  = 0;
    else
      UL_alloc_pdu.cshift  = 1;
    UL_alloc_pdu.dai     = 0;
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    UL_alloc_pdu.cqi_req = 1;
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    memcpy((void*)&DCI_pdu->dci_alloc[1].dci_pdu[0],(void *)&UL_alloc_pdu,sizeof(DCI0_5MHz_TDD_1_6_t));

    break;

  default:
    break;
  }

  DCI_pdu->nCCE = 0;
  for (i=0;i<DCI_pdu->Num_common_dci+DCI_pdu->Num_ue_spec_dci;i++) {
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    DCI_pdu->nCCE += (1<<(DCI_pdu->dci_alloc[i].L));
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  }

}

#ifdef EMOS
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void fill_dci_emos(DCI_PDU *DCI_pdu, uint8_t subframe, PHY_VARS_eNB *phy_vars_eNB) {
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  int i;
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  uint8_t cooperation_flag = phy_vars_eNB->cooperation_flag;
  uint8_t transmission_mode = phy_vars_eNB->transmission_mode[0];
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  //uint32_t rballoc = 0x00F0;
  //uint32_t rballoc2 = 0x000F;
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  /*
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    uint32_t rand = taus();
    if ((subframe==8) || (subframe==9) || (subframe==0))
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    rand = (rand%5)+5;
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    else
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    rand = (rand%4)+5;
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  */
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  DCI_pdu->Num_common_dci = 0;
  DCI_pdu->Num_ue_spec_dci=0;

  switch (subframe) {
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  case 5:
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    DCI_pdu->Num_ue_spec_dci = 1;
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    if (transmission_mode<3) {
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      //user 1
      DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1_5MHz_TDD_t; 
      DCI_pdu->dci_alloc[0].L          = 2;
      DCI_pdu->dci_alloc[0].rnti       = 0x1235;
      DCI_pdu->dci_alloc[0].format     = format1;
      DCI_pdu->dci_alloc[0].ra_flag    = 0;
      
      DLSCH_alloc_pdu.rballoc          = openair_daq_vars.ue_dl_rb_alloc;
      DLSCH_alloc_pdu.TPC              = 0;
      DLSCH_alloc_pdu.dai              = 0;
      DLSCH_alloc_pdu.harq_pid         = 1;
      DLSCH_alloc_pdu.mcs              = openair_daq_vars.target_ue_dl_mcs;
      DLSCH_alloc_pdu.ndi              = 1;
      DLSCH_alloc_pdu.rv               = 0;
      memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&DLSCH_alloc_pdu,sizeof(DCI1_5MHz_TDD_t));

      /*
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      //user2
      DCI_pdu->dci_alloc[1].dci_length = sizeof_DCI1_5MHz_TDD_t; 
      DCI_pdu->dci_alloc[1].L          = 2;
      DCI_pdu->dci_alloc[1].rnti       = 0x1236;
      DCI_pdu->dci_alloc[1].format     = format1;
      DCI_pdu->dci_alloc[1].ra_flag    = 0;
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      DLSCH_alloc_pdu.rballoc          = rballoc2;
      DLSCH_alloc_pdu.TPC              = 0;
      DLSCH_alloc_pdu.dai              = 0;
      DLSCH_alloc_pdu.harq_pid         = 1;
      DLSCH_alloc_pdu.mcs              = openair_daq_vars.target_ue_dl_mcs;
      DLSCH_alloc_pdu.ndi              = 1;
      DLSCH_alloc_pdu.rv               = 0;
      memcpy((void*)&DCI_pdu->dci_alloc[1].dci_pdu[0],(void *)&DLSCH_alloc_pdu,sizeof(DCI1_5MHz_TDD_t));
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      */
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    }
    else if (transmission_mode==5) {
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      DCI_pdu->Num_ue_spec_dci = 2;
      // user 1
      DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1E_5MHz_2A_M10PRB_TDD_t; 
      DCI_pdu->dci_alloc[0].L          = 2;
      DCI_pdu->dci_alloc[0].rnti       = 0x1235;
      DCI_pdu->dci_alloc[0].format     = format1E_2A_M10PRB;
      DCI_pdu->dci_alloc[0].ra_flag    = 0;
      
      DLSCH_alloc_pdu1E.tpmi             = 5; //5=use feedback
      DLSCH_alloc_pdu1E.rv               = 0;
      DLSCH_alloc_pdu1E.ndi              = 1;
      DLSCH_alloc_pdu1E.mcs              = openair_daq_vars.target_ue_dl_mcs;
      DLSCH_alloc_pdu1E.harq_pid         = 1;
      DLSCH_alloc_pdu1E.dai              = 0;
      DLSCH_alloc_pdu1E.TPC              = 0;
      DLSCH_alloc_pdu1E.rballoc          = openair_daq_vars.ue_dl_rb_alloc;
      DLSCH_alloc_pdu1E.rah              = 0;
      DLSCH_alloc_pdu1E.dl_power_off     = 0; //0=second user present
      memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&DLSCH_alloc_pdu1E,sizeof(DCI1E_5MHz_2A_M10PRB_TDD_t));
      
      //user 2
      DCI_pdu->dci_alloc[1].dci_length = sizeof_DCI1E_5MHz_2A_M10PRB_TDD_t; 
      DCI_pdu->dci_alloc[1].L          = 2;
      DCI_pdu->dci_alloc[1].rnti       = 0x1236;
      DCI_pdu->dci_alloc[1].format     = format1E_2A_M10PRB;
      DCI_pdu->dci_alloc[1].ra_flag    = 0;
      
      memcpy((void*)&DCI_pdu->dci_alloc[1].dci_pdu[0],(void *)&DLSCH_alloc_pdu1E,sizeof(DCI1E_5MHz_2A_M10PRB_TDD_t));

      // set the precoder of the second UE orthogonal to the first
      phy_vars_eNB->eNB_UE_stats[1].DL_pmi_single = (phy_vars_eNB->eNB_UE_stats[0].DL_pmi_single ^ 0x1555); 
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    }
    break;

  case 7:
    DCI_pdu->Num_common_dci = 1;
    DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI1A_5MHz_TDD_1_6_t;
    DCI_pdu->dci_alloc[0].L          = 2;
    DCI_pdu->dci_alloc[0].rnti       = 0xbeef;
    DCI_pdu->dci_alloc[0].format     = format1A;
    DCI_pdu->dci_alloc[0].ra_flag    = 1;

    RA_alloc_pdu.type                = 1;
    RA_alloc_pdu.vrb_type            = 0;
    RA_alloc_pdu.rballoc             = computeRIV(25,12,3);
    RA_alloc_pdu.ndi      = 1;
    RA_alloc_pdu.rv       = 1;
    RA_alloc_pdu.mcs      = 4;
    RA_alloc_pdu.harq_pid = 0;
    RA_alloc_pdu.TPC      = 1;

    memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],&RA_alloc_pdu,sizeof(DCI1A_5MHz_TDD_1_6_t));
    break;

  case 9:
    DCI_pdu->Num_ue_spec_dci = 1;

    //user 1
    DCI_pdu->dci_alloc[0].dci_length = sizeof_DCI0_5MHz_TDD_1_6_t ; 
    DCI_pdu->dci_alloc[0].L          = 2;
    DCI_pdu->dci_alloc[0].rnti       = 0x1235;
    DCI_pdu->dci_alloc[0].format     = format0;
    DCI_pdu->dci_alloc[0].ra_flag    = 0;

    UL_alloc_pdu.type    = 0;
    UL_alloc_pdu.hopping = 0;
    UL_alloc_pdu.rballoc = computeRIV(25,0,openair_daq_vars.ue_ul_nb_rb);
    UL_alloc_pdu.mcs     = openair_daq_vars.target_ue_ul_mcs;
    UL_alloc_pdu.ndi     = 1;
    UL_alloc_pdu.TPC     = 0;
    UL_alloc_pdu.cshift  = 0;
    UL_alloc_pdu.dai     = 0;
    UL_alloc_pdu.cqi_req = 1;
    memcpy((void*)&DCI_pdu->dci_alloc[0].dci_pdu[0],(void *)&UL_alloc_pdu,sizeof(DCI0_5MHz_TDD_1_6_t));

    /*
    //user 2
    DCI_pdu->dci_alloc[1].dci_length = sizeof_DCI0_5MHz_TDD_1_6_t ; 
    DCI_pdu->dci_alloc[1].L          = 2;
    DCI_pdu->dci_alloc[1].rnti       = 0x1236;
    DCI_pdu->dci_alloc[1].format     = format0;
    DCI_pdu->dci_alloc[1].ra_flag    = 0;

    UL_alloc_pdu.type    = 0;
    UL_alloc_pdu.hopping = 0;
    if (cooperation_flag==0)
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    UL_alloc_pdu.rballoc = computeRIV(25,2+openair_daq_vars.ue_ul_nb_rb,openair_daq_vars.ue_ul_nb_rb);
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    else 
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    UL_alloc_pdu.rballoc = computeRIV(25,0,openair_daq_vars.ue_ul_nb_rb);
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    UL_alloc_pdu.mcs     = openair_daq_vars.target_ue_ul_mcs;
    UL_alloc_pdu.ndi     = 1;
    UL_alloc_pdu.TPC     = 0;
    if ((cooperation_flag==0) || (cooperation_flag==1))
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    UL_alloc_pdu.cshift  = 0;
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    else
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    UL_alloc_pdu.cshift  = 1;
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    UL_alloc_pdu.dai     = 0;
    UL_alloc_pdu.cqi_req = 1;
    memcpy((void*)&DCI_pdu->dci_alloc[1].dci_pdu[0],(void *)&UL_alloc_pdu,sizeof(DCI0_5MHz_TDD_1_6_t));
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    */
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    break;
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  default:
    break;
  }

  DCI_pdu->nCCE = 0;
  for (i=0;i<DCI_pdu->Num_common_dci+DCI_pdu->Num_ue_spec_dci;i++) {
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    DCI_pdu->nCCE += (1<<(DCI_pdu->dci_alloc[i].L));
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  }

}
#endif //EMOS
#endif //OPENAIR2

#define AMP_OVER_SQRT2 ((AMP*ONE_OVER_SQRT2_Q15)>>15)
#define AMP_OVER_2 (AMP>>1)
int QPSK[4]={AMP_OVER_SQRT2|(AMP_OVER_SQRT2<<16),AMP_OVER_SQRT2|((65536-AMP_OVER_SQRT2)<<16),((65536-AMP_OVER_SQRT2)<<16)|AMP_OVER_SQRT2,((65536-AMP_OVER_SQRT2)<<16)|(65536-AMP_OVER_SQRT2)};
int QPSK2[4]={AMP_OVER_2|(AMP_OVER_2<<16),AMP_OVER_2|((65536-AMP_OVER_2)<<16),((65536-AMP_OVER_2)<<16)|AMP_OVER_2,((65536-AMP_OVER_2)<<16)|(65536-AMP_OVER_2)};

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#if defined(ENABLE_ITTI)
#   if defined(ENABLE_RAL)
extern PHY_MEASUREMENTS PHY_measurements;

void phy_eNB_lte_measurement_thresholds_test_and_report(instance_t instanceP, ral_threshold_phy_t* threshold_phy_pP, uint16_t valP) {
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  MessageDef *message_p = NULL;
  if (
      (
       ((threshold_phy_pP->threshold.threshold_val <  valP) && (threshold_phy_pP->threshold.threshold_xdir == RAL_ABOVE_THRESHOLD)) ||
       ((threshold_phy_pP->threshold.threshold_val >  valP) && (threshold_phy_pP->threshold.threshold_xdir == RAL_BELOW_THRESHOLD))
       )  ||
      (threshold_phy_pP->threshold.threshold_xdir == RAL_NO_THRESHOLD)
      ){
    message_p = itti_alloc_new_message(TASK_PHY_ENB , PHY_MEAS_REPORT_IND);
    memset(&PHY_MEAS_REPORT_IND(message_p), 0, sizeof(PHY_MEAS_REPORT_IND(message_p)));

    memcpy(&PHY_MEAS_REPORT_IND (message_p).threshold,
	   &threshold_phy_pP->threshold,
	   sizeof(PHY_MEAS_REPORT_IND (message_p).threshold));

    memcpy(&PHY_MEAS_REPORT_IND (message_p).link_param,
	   &threshold_phy_pP->link_param,
	   sizeof(PHY_MEAS_REPORT_IND (message_p).link_param));\

    switch (threshold_phy_pP->link_param.choice) {
    case RAL_LINK_PARAM_CHOICE_LINK_PARAM_VAL:
      PHY_MEAS_REPORT_IND (message_p).link_param._union.link_param_val = valP;
      break;
    case RAL_LINK_PARAM_CHOICE_QOS_PARAM_VAL:
      //PHY_MEAS_REPORT_IND (message_p).link_param._union.qos_param_val.
      AssertFatal (1 == 0, "TO DO RAL_LINK_PARAM_CHOICE_QOS_PARAM_VAL\n");
      break;
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    }
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    itti_send_msg_to_task(TASK_RRC_ENB, instanceP, message_p);
  }
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}

void phy_eNB_lte_check_measurement_thresholds(instance_t instanceP, ral_threshold_phy_t* threshold_phy_pP) {
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  unsigned int  mod_id;

  mod_id = instanceP;

  switch (threshold_phy_pP->link_param.link_param_type.choice) {

  case RAL_LINK_PARAM_TYPE_CHOICE_GEN:
    switch (threshold_phy_pP->link_param.link_param_type._union.link_param_gen) {
    case RAL_LINK_PARAM_GEN_DATA_RATE:
      phy_eNB_lte_measurement_thresholds_test_and_report(instanceP, threshold_phy_pP, 0);
      break;
    case RAL_LINK_PARAM_GEN_SIGNAL_STRENGTH:
      phy_eNB_lte_measurement_thresholds_test_and_report(instanceP, threshold_phy_pP, 0);
      break;
    case RAL_LINK_PARAM_GEN_SINR:
      phy_eNB_lte_measurement_thresholds_test_and_report(instanceP, threshold_phy_pP, 0);
      break;
    case RAL_LINK_PARAM_GEN_THROUGHPUT:
      break;
    case RAL_LINK_PARAM_GEN_PACKET_ERROR_RATE:
      break;
    default:;
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    }
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    break;

  case RAL_LINK_PARAM_TYPE_CHOICE_LTE:
    switch (threshold_phy_pP->link_param.link_param_type._union.link_param_gen) {
    case RAL_LINK_PARAM_LTE_UE_RSRP:
      break;
    case RAL_LINK_PARAM_LTE_UE_RSRQ:
      break;
    case RAL_LINK_PARAM_LTE_UE_CQI:
      break;
    case RAL_LINK_PARAM_LTE_AVAILABLE_BW:
      break;
    case RAL_LINK_PARAM_LTE_PACKET_DELAY:
      break;
    case RAL_LINK_PARAM_LTE_PACKET_LOSS_RATE:
      break;
    case RAL_LINK_PARAM_LTE_L2_BUFFER_STATUS:
      break;
    case RAL_LINK_PARAM_LTE_MOBILE_NODE_CAPABILITIES:
      break;
    case RAL_LINK_PARAM_LTE_EMBMS_CAPABILITY:
      break;
    case RAL_LINK_PARAM_LTE_JUMBO_FEASIBILITY:
      break;
    case RAL_LINK_PARAM_LTE_JUMBO_SETUP_STATUS:
      break;
    case RAL_LINK_PARAM_LTE_NUM_ACTIVE_EMBMS_RECEIVERS_PER_FLOW:
      break;
    default:;
    }
    break;

  default:;
  }
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}
#   endif
#endif

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void phy_procedures_eNB_TX(unsigned char subframe,PHY_VARS_eNB *phy_vars_eNB,uint8_t abstraction_flag,
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			   relaying_type_t r_type,PHY_VARS_RN *phy_vars_rn) {
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  uint8_t *pbch_pdu=&phy_vars_eNB->pbch_pdu[0];
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  //  unsigned int nb_dci_ue_spec = 0, nb_dci_common = 0;
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  uint16_t input_buffer_length, re_allocated=0;
  uint32_t sect_id = 0,i,aa;
  uint8_t harq_pid;
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  DCI_PDU *DCI_pdu;
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  uint8_t *DLSCH_pdu=NULL;
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#ifndef OPENAIR2
  DCI_PDU DCI_pdu_tmp;
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  uint8_t DLSCH_pdu_tmp[768*8];
  uint8_t rar;
#endif
  int8_t UE_id;
  uint8_t num_pdcch_symbols=0;
  int16_t crnti;
  uint16_t frame_tx;
  //  int16_t amp;
  uint8_t ul_subframe;
  uint32_t ul_frame;
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#ifdef Rel10
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  MCH_PDU *mch_pduP;
  MCH_PDU  mch_pdu;
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  uint8_t sync_area=255;
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#endif
#if defined(SMBV) && !defined(EXMIMO)
  // counts number of allocations in subframe
  // there is at least one allocation for PDCCH
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  uint8_t smbv_alloc_cnt = 1;
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#endif
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  int sched_subframe = (subframe==0)?9:(subframe-1);
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  vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_PROCEDURES_ENB_TX,1);
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  start_meas(&phy_vars_eNB->phy_proc_tx);
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#ifdef DEBUG_PHY_PROC
  LOG_D(PHY,"[%s %d] Frame %d subframe %d : Doing phy_procedures_eNB_TX(%d)\n", 
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	(r_type == multicast_relay) ? "RN/eNB" : "eNB",
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	phy_vars_eNB->Mod_id,phy_vars_eNB->proc[sched_subframe].frame_tx, subframe, subframe);
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#endif
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#ifdef OPENAIR2
  // Get scheduling info for next subframe during odd slot of previous subframe (next_slot is even)
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  mac_xface->eNB_dlsch_ulsch_scheduler(phy_vars_eNB->Mod_id,0,phy_vars_eNB->proc[sched_subframe].frame_tx,subframe);//,1);
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#endif
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  for (sect_id = 0 ; sect_id < number_of_cards; sect_id++) {
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    if (abstraction_flag==0) {
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      for (aa=0; aa<phy_vars_eNB->lte_frame_parms.nb_antennas_tx_eNB;aa++) {
	
	memset(&phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id][aa][subframe*phy_vars_eNB->lte_frame_parms.ofdm_symbol_size*(phy_vars_eNB->lte_frame_parms.symbols_per_tti)],
	       0,phy_vars_eNB->lte_frame_parms.ofdm_symbol_size*(phy_vars_eNB->lte_frame_parms.symbols_per_tti)*sizeof(mod_sym_t));
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      }
    }
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    if (is_pmch_subframe(phy_vars_eNB->proc[sched_subframe].frame_tx,subframe,&phy_vars_eNB->lte_frame_parms)) {
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      if (abstraction_flag==0){
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	// This is DL-Cell spec pilots in Control region
	generate_pilots_slot(phy_vars_eNB,
			     phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
			     AMP,
			     subframe<<1,1);
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      }
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#ifdef Rel10
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      // if mcch is active, send regardless of the node type: eNB or RN
      // when mcch is active, MAC sched does not allow MCCH and MTCH multiplexing 
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      mch_pduP = mac_xface->get_mch_sdu(phy_vars_eNB->Mod_id,phy_vars_eNB->proc[sched_subframe].frame_tx,subframe);
      switch (r_type){
      case no_relay:
	if ((mch_pduP->Pdu_size > 0) && (mch_pduP->sync_area == 0)) // TEST: only transmit mcch for sync area 0 
	  //if ((mch_pduP->sync_area == 0)) // TEST: only transmit mcch for sync area 0 
	  LOG_I(PHY,"[eNB%d] Frame %d subframe %d : Got MCH pdu for MBSFN (MCS %d, TBS %d) \n",
		phy_vars_eNB->Mod_id,phy_vars_eNB->proc[sched_subframe].frame_tx,subframe,mch_pduP->mcs,
		phy_vars_eNB->dlsch_eNB_MCH->harq_processes[0]->TBS>>3);
	else {
	  LOG_D(PHY,"[DeNB %d] Frame %d subframe %d : Do not transmit MCH pdu for MBSFN sync area %d (%s)\n",
		phy_vars_eNB->Mod_id,phy_vars_eNB->proc[sched_subframe].frame_tx,subframe,mch_pduP->sync_area,
		(mch_pduP->Pdu_size == 0)? "Empty MCH PDU":"Let RN transmit for the moment");
	  mch_pduP = NULL;
	}
	break;
      case multicast_relay:
	if ((mch_pduP->Pdu_size > 0) && ((mch_pduP->mcch_active == 1) || mch_pduP->msi_active==1)){
	  //if (((mch_pduP->mcch_active == 1) || mch_pduP->msi_active==1)){
	  LOG_I(PHY,"[RN %d] Frame %d subframe %d: Got the MCH PDU for MBSFN  sync area %d (MCS %d, TBS %d)\n",
		phy_vars_rn->Mod_id,phy_vars_rn->frame, subframe,
		mch_pduP->sync_area,mch_pduP->mcs,mch_pduP->Pdu_size);
	} else if (phy_vars_rn->mch_avtive[subframe%5] == 1){ // SF2 -> SF7, SF3 -> SF8
	  mch_pduP= &mch_pdu;
	  memcpy(&mch_pduP->payload, // could be a simple copy
		 phy_vars_rn->dlsch_rn_MCH[subframe%5]->harq_processes[0]->b,
		 phy_vars_rn->dlsch_rn_MCH[subframe%5]->harq_processes[0]->TBS>>3);
	  mch_pduP->Pdu_size = (uint16_t) (phy_vars_rn->dlsch_rn_MCH[subframe%5]->harq_processes[0]->TBS>>3);
	  mch_pduP->mcs = phy_vars_rn->dlsch_rn_MCH[subframe%5]->harq_processes[0]->mcs;
	  LOG_I(PHY,"[RN %d] Frame %d subframe %d: Forward the MCH PDU for MBSFN received on SF %d sync area %d (MCS %d, TBS %d)\n",
		phy_vars_rn->Mod_id,phy_vars_rn->frame, subframe,subframe%5,
		phy_vars_rn->sync_area[subframe%5],mch_pduP->mcs,mch_pduP->Pdu_size);
	} else {
	  /* LOG_I(PHY,"[RN %d] Frame %d subframe %d: do not forward MCH pdu for MBSFN  sync area %d (MCS %d, TBS %d)\n",
	     phy_vars_rn->Mod_id,phy_vars_rn->frame, next_slot>>1,
	     mch_pduP->sync_area,mch_pduP->mcs,mch_pduP->Pdu_size);*/
	  mch_pduP=NULL;
	}
	phy_vars_rn->mch_avtive[subframe]=0;
	break;
      default:
	LOG_W(PHY,"[eNB %d] Frame %d subframe %d: unknown relaying type %d \n",
	      phy_vars_eNB->Mod_id,phy_vars_eNB->proc[sched_subframe].frame_tx,subframe,r_type);
	mch_pduP=NULL;
	break;
      }// switch 
      
      if (mch_pduP){
	fill_eNB_dlsch_MCH(phy_vars_eNB,mch_pduP->mcs,1,0, abstraction_flag);
	// Generate PMCH
	generate_mch(phy_vars_eNB,subframe,(uint8_t*)mch_pduP->payload,abstraction_flag);
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#ifdef DEBUG_PHY
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	for (i=0;i<mch_pduP->Pdu_size;i++)
	  msg("%2x.",(uint8_t)mch_pduP->payload[i]);
	msg("\n");
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#endif 
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      } else {
	LOG_D(PHY,"[eNB/RN] Frame %d subframe %d: MCH not generated \n",phy_vars_eNB->proc[sched_subframe].frame_tx,subframe);
      }
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#endif
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    }
    
    else {
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      if (abstraction_flag==0){
	vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_ENB_RS_TX,1);
	generate_pilots_slot(phy_vars_eNB,
			     phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
			     AMP,
			     subframe<<1,0);
	generate_pilots_slot(phy_vars_eNB,
			     phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
			     AMP,
			     (subframe<<1)+1,0);
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	vcd_signal_dumper_dump_function_by_name(VCD_SIGNAL_DUMPER_FUNCTIONS_PHY_ENB_RS_TX,0);
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	// First half of PSS/SSS (FDD)
	if (subframe == 0) {
	  if (phy_vars_eNB->lte_frame_parms.frame_type == FDD) {
	    generate_pss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
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			 AMP,
			 &phy_vars_eNB->lte_frame_parms,
			 (phy_vars_eNB->lte_frame_parms.Ncp==0) ? 6 : 5,
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			 0);
	    generate_sss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
			 AMP,
			 &phy_vars_eNB->lte_frame_parms,
			 (phy_vars_eNB->lte_frame_parms.Ncp==0) ? 5 : 4,
			 0);
	    
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	  }
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	}    
      }
    }

    if (subframe == 0) {
      if ((phy_vars_eNB->proc[sched_subframe].frame_tx&3) == 0) {
	((uint8_t*) pbch_pdu)[2] = 0;
	switch (phy_vars_eNB->lte_frame_parms.N_RB_DL) {
	case 6:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (0<<5);
	  break;
	case 15:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (1<<5);
	  break;
	case 25:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (2<<5);
	  break;
	case 50:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (3<<5);
	  break;
	case 75:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (4<<5);
	  break;
	case 100:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (5<<5);
	  break;
	default:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0x1f) | (2<<5);
	  break;
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	}
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	((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0xef) | 
	  ((phy_vars_eNB->lte_frame_parms.phich_config_common.phich_duration << 4)&0x10);
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	switch (phy_vars_eNB->lte_frame_parms.phich_config_common.phich_resource) {
	case oneSixth:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0xf3) | (0<<2);
	  break;
	case half:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0xf3) | (1<<2);
	  break;
	case one:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0xf3) | (2<<2);
	  break;
	case two:
	  ((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0xf3) | (3<<2);
	  break;
	default:
	  break;
	}
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	((uint8_t*) pbch_pdu)[2] = (((uint8_t*) pbch_pdu)[2]&0xfc) | ((phy_vars_eNB->proc[sched_subframe].frame_tx>>8)&0x3);
	((uint8_t*) pbch_pdu)[1] = phy_vars_eNB->proc[sched_subframe].frame_tx&0xfc;
	((uint8_t*) pbch_pdu)[0] = 0;
      }
	/// First half of SSS (TDD)
      if (abstraction_flag==0) {
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	if (phy_vars_eNB->lte_frame_parms.frame_type == TDD) {
	  generate_sss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
		       AMP,
		       &phy_vars_eNB->lte_frame_parms,
		       (phy_vars_eNB->lte_frame_parms.Ncp==0) ? 6 : 5,
		       1);
	}
      }
      
      
      
      frame_tx = (((int) (pbch_pdu[2]&0x3))<<8) + ((int) (pbch_pdu[1]&0xfc)) + phy_vars_eNB->proc[sched_subframe].frame_tx%4;
      
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#ifdef DEBUG_PHY_PROC
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      LOG_D(PHY,"[eNB %d] Frame %d, subframe %d: Generating PBCH, mode1_flag=%d, frame_tx=%d, pdu=%02x%02x%02x\n",
	    phy_vars_eNB->Mod_id,
	    phy_vars_eNB->proc[sched_subframe].frame_tx, 
	    subframe,
	    phy_vars_eNB->lte_frame_parms.mode1_flag,
	    frame_tx,
	    ((uint8_t*) pbch_pdu)[2],
	    ((uint8_t*) pbch_pdu)[1],
	    ((uint8_t*) pbch_pdu)[0]);
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#endif
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      if (abstraction_flag==0) {
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	generate_pbch(&phy_vars_eNB->lte_eNB_pbch,
		      phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
		      AMP,
		      &phy_vars_eNB->lte_frame_parms,
		      pbch_pdu,
		      phy_vars_eNB->proc[sched_subframe].frame_tx&3);
	
      }
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#ifdef PHY_ABSTRACTION
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      else {
	generate_pbch_emul(phy_vars_eNB,pbch_pdu); 
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      }
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#endif
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    }
  
    if (subframe == 1) {
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      if (abstraction_flag==0) {
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	if (phy_vars_eNB->lte_frame_parms.frame_type == TDD) {
	  //	  printf("Generating PSS (frame %d, subframe %d)\n",phy_vars_eNB->proc[sched_subframe].frame_tx,next_slot>>1);
	  generate_pss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
		       AMP,
		       &phy_vars_eNB->lte_frame_parms,
		       2,
		       2);
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	}
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      }
    } 
  
    // Second half of PSS/SSS (FDD)
    if (subframe == 5) {
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      if (abstraction_flag==0) {
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	if (phy_vars_eNB->lte_frame_parms.frame_type == FDD) {
	  generate_pss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
		       AMP,
		       &phy_vars_eNB->lte_frame_parms,
		       (phy_vars_eNB->lte_frame_parms.Ncp==0) ? 6 : 5,
		       10);
	  generate_sss(phy_vars_eNB->lte_eNB_common_vars.txdataF[sect_id],
		       AMP,
		       &phy_vars_eNB->lte_frame_parms,
		       (phy_vars_eNB->lte_frame_parms.Ncp==0) ? 5 : 4,
		       10);
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	}
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