asn1_msg.c

/*
 * 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 1.0  (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
 */

/*! \file asn1_msg.c
* \brief primitives to build the asn1 messages
* \author Raymond Knopp and Navid Nikaein
* \date 2011
* \version 1.0
* \company Eurecom
* \email: raymond.knopp@eurecom.fr and  navid.nikaein@eurecom.fr
*/

#ifdef USER_MODE
#include <stdio.h>
#include <sys/types.h>
#include <stdlib.h> /* for atoi(3) */
#include <unistd.h> /* for getopt(3) */
#include <string.h> /* for strerror(3) */
#include <sysexits.h> /* for EX_* exit codes */
#include <errno.h>  /* for errno */
#else
#include <linux/module.h>  /* Needed by all modules */
#endif
#ifdef USER_MODE
//#include "RRC/LITE/defs.h"
//#include "COMMON/mac_rrc_primitives.h"
#include "UTIL/LOG/log.h"
#endif
#include <asn_application.h>
#include <asn_internal.h> /* for _ASN_DEFAULT_STACK_MAX */
#include <per_encoder.h>

#include "assertions.h"
#include "RRCConnectionRequest.h"
#include "UL-CCCH-Message.h"
#include "UL-DCCH-Message.h"
#include "DL-CCCH-Message.h"
#include "DL-DCCH-Message.h"
#include "EstablishmentCause.h"
#include "RRCConnectionSetup.h"
#include "SRB-ToAddModList.h"
#include "DRB-ToAddModList.h"
#ifdef Rel10
#include "MCCH-Message.h"
//#define MRB1 1
#endif

#include "RRC/LITE/defs.h"
#include "RRCConnectionSetupComplete.h"
#include "RRCConnectionReconfigurationComplete.h"
#include "RRCConnectionReconfiguration.h"
#include "MasterInformationBlock.h"
#include "SystemInformation.h"

#include "SystemInformationBlockType1.h"

#include "SIB-Type.h"

#include "BCCH-DL-SCH-Message.h"

#include "PHY/defs.h"

#include "MeasObjectToAddModList.h"
#include "ReportConfigToAddModList.h"
#include "MeasIdToAddModList.h"
#include "enb_config.h"

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

//#include "PHY/defs.h"
#ifndef USER_MODE
#define msg printk
#ifndef errno
int errno;
#endif
#else
# if !defined (msg)
#   define msg printf
# endif
#endif

//#define XER_PRINT

extern Enb_properties_array_t enb_properties;
typedef struct xer_sprint_string_s {
  char *string;
  size_t string_size;
  size_t string_index;
} xer_sprint_string_t;

extern unsigned char NB_eNB_INST;
extern uint8_t usim_test;

uint16_t two_tier_hexagonal_cellIds[7] = {0,1,2,4,5,7,8};
uint16_t two_tier_hexagonal_adjacent_cellIds[7][6] = {{1,2,4,5,7,8},    // CellId 0
  {11,18,2,0,8,15}, // CellId 1
  {18,13,3,4,0,1},  // CellId 2
  {2,3,14,6,5,0},   // CellId 4
  {0,4,6,16,9,7},   // CellId 5
  {8,0,5,9,17,12},  // CellId 7
  {15,1,0,7,12,10}
};// CellId 8

/*
 * This is a helper function for xer_sprint, which directs all incoming data
 * into the provided string.
 */
static int xer__print2s (const void *buffer, size_t size, void *app_key)
{
  xer_sprint_string_t *string_buffer = (xer_sprint_string_t *) app_key;
  size_t string_remaining = string_buffer->string_size - string_buffer->string_index;

  if (string_remaining > 0) {
    if (size > string_remaining) {
      size = string_remaining;
    }

    memcpy(&string_buffer->string[string_buffer->string_index], buffer, size);
    string_buffer->string_index += size;
  }

  return 0;
}

int xer_sprint (char *string, size_t string_size, asn_TYPE_descriptor_t *td, void *sptr)
{
  asn_enc_rval_t er;
  xer_sprint_string_t string_buffer;

  string_buffer.string = string;
  string_buffer.string_size = string_size;
  string_buffer.string_index = 0;

  er = xer_encode(td, sptr, XER_F_BASIC, xer__print2s, &string_buffer);

  if (er.encoded < 0) {
    LOG_E(RRC, "xer_sprint encoding error (%d)!", er.encoded);
    er.encoded = string_buffer.string_size;
  } else {
    if (er.encoded > string_buffer.string_size) {
      LOG_E(RRC, "xer_sprint string buffer too small, got %d need %d!", string_buffer.string_size, er.encoded);
      er.encoded = string_buffer.string_size;
    }
  }

  return er.encoded;
}

uint16_t get_adjacent_cell_id(uint8_t Mod_id,uint8_t index)
{
  return(two_tier_hexagonal_adjacent_cellIds[Mod_id][index]);
}
/* This only works for the hexagonal topology...need a more general function for other topologies */

uint8_t get_adjacent_cell_mod_id(uint16_t phyCellId)
{
  uint8_t i;

  for(i=0; i<7; i++) {
    if(two_tier_hexagonal_cellIds[i] == phyCellId) {
      return i;
    }
  }

  LOG_E(RRC,"\nCannot get adjacent cell mod id! Fatal error!\n");
  return 0xFF; //error!
}

/*
uint8_t do_SIB1(LTE_DL_FRAME_PARMS *frame_parms, uint8_t *buffer,
    SystemInformationBlockType1_t *sib1) {


  PLMN_IdentityInfo_t PLMN_identity_info;
  MCC_MNC_Digit_t dummy;
  asn_enc_rval_t enc_rval;
  SchedulingInfo_t schedulingInfo;
  SIB_Type_t sib_type;

  memset(sib1,0,sizeof(SystemInformationBlockType1_t));
  memset(&PLMN_identity_info,0,sizeof(PLMN_IdentityInfo_t));
  memset(&schedulingInfo,0,sizeof(SchedulingInfo_t));
  memset(&sib_type,0,sizeof(SIB_Type_t));

  PLMN_identity_info.plmn_Identity.mcc = CALLOC(1,sizeof(*PLMN_identity_info.plmn_Identity.mcc));
  memset(PLMN_identity_info.plmn_Identity.mcc,0,sizeof(*PLMN_identity_info.plmn_Identity.mcc));

  asn_set_empty(&PLMN_identity_info.plmn_Identity.mcc->list);//.size=0;

  dummy=2;ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mcc->list,&dummy);
  dummy=6;ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mcc->list,&dummy);
  dummy=2;ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mcc->list,&dummy);

  PLMN_identity_info.plmn_Identity.mnc.list.size=0;
  PLMN_identity_info.plmn_Identity.mnc.list.count=0;
  dummy=8;ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mnc.list,&dummy);
  dummy=0;ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mnc.list,&dummy);
  //assign_enum(&PLMN_identity_info.cellReservedForOperatorUse,PLMN_IdentityInfo__cellReservedForOperatorUse_notReserved);
  PLMN_identity_info.cellReservedForOperatorUse=PLMN_IdentityInfo__cellReservedForOperatorUse_notReserved;

  ASN_SEQUENCE_ADD(&sib1->cellAccessRelatedInfo.plmn_IdentityList.list,&PLMN_identity_info);


  // 16 bits
  sib1->cellAccessRelatedInfo.trackingAreaCode.buf = MALLOC(2);
  sib1->cellAccessRelatedInfo.trackingAreaCode.buf[0]=0x00;
  sib1->cellAccessRelatedInfo.trackingAreaCode.buf[1]=0x10;
  sib1->cellAccessRelatedInfo.trackingAreaCode.size=2;
  sib1->cellAccessRelatedInfo.trackingAreaCode.bits_unused=0;

  // 28 bits
  sib1->cellAccessRelatedInfo.cellIdentity.buf = MALLOC(8);
  sib1->cellAccessRelatedInfo.cellIdentity.buf[0]=0x01;
  sib1->cellAccessRelatedInfo.cellIdentity.buf[1]=0x48;
  sib1->cellAccessRelatedInfo.cellIdentity.buf[2]=0x0f;
  sib1->cellAccessRelatedInfo.cellIdentity.buf[3]=0x03;
  sib1->cellAccessRelatedInfo.cellIdentity.size=4;
  sib1->cellAccessRelatedInfo.cellIdentity.bits_unused=4;

  //  assign_enum(&sib1->cellAccessRelatedInfo.cellBarred,SystemInformationBlockType1__cellAccessRelatedInfo__cellBarred_notBarred);
  sib1->cellAccessRelatedInfo.cellBarred=SystemInformationBlockType1__cellAccessRelatedInfo__cellBarred_notBarred;

  //  assign_enum(&sib1->cellAccessRelatedInfo.intraFreqReselection,SystemInformationBlockType1__cellAccessRelatedInfo__intraFreqReselection_allowed);
  sib1->cellAccessRelatedInfo.intraFreqReselection=SystemInformationBlockType1__cellAccessRelatedInfo__intraFreqReselection_allowed;
  sib1->cellAccessRelatedInfo.csg_Indication=0;

  sib1->cellSelectionInfo.q_RxLevMin=-70;
  sib1->cellSelectionInfo.q_RxLevMinOffset=NULL;

  sib1->freqBandIndicator = 2;

  //  assign_enum(&schedulingInfo.si_Periodicity,SchedulingInfo__si_Periodicity_rf8);
  schedulingInfo.si_Periodicity=SchedulingInfo__si_Periodicity_rf8;

  //  assign_enum(&sib_type,SIB_Type_sibType3);
  sib_type=SIB_Type_sibType3;

  ASN_SEQUENCE_ADD(&schedulingInfo.sib_MappingInfo.list,&sib_type);
  ASN_SEQUENCE_ADD(&sib1->schedulingInfoList.list,&schedulingInfo);

  sib1->tdd_Config = CALLOC(1,sizeof(struct TDD_Config));

  //assign_enum(&sib1->tdd_Config->subframeAssignment,TDD_Config__subframeAssignment_sa3);
  sib1->tdd_Config->subframeAssignment=frame_parms->tdd_config; //TDD_Config__subframeAssignment_sa3;

  //  assign_enum(&sib1->tdd_Config->specialSubframePatterns,TDD_Config__specialSubframePatterns_ssp0);
  sib1->tdd_Config->specialSubframePatterns=frame_parms->tdd_config_S;//TDD_Config__specialSubframePatterns_ssp0;

  //  assign_enum(&sib1->si_WindowLength,SystemInformationBlockType1__si_WindowLength_ms10);
  sib1->si_WindowLength=SystemInformationBlockType1__si_WindowLength_ms10;
  sib1->systemInfoValueTag=0;
  //  sib1.nonCriticalExtension = calloc(1,sizeof(*sib1.nonCriticalExtension));

#ifdef USER_MODE
  xer_fprint(stdout, &asn_DEF_SystemInformationBlockType1, (void*)sib1);
#endif

  enc_rval = uper_encode_to_buffer(&asn_DEF_SystemInformationBlockType1,
           (void*)sib1,
           buffer,
           200);
#ifdef USER_MODE
  LOG_D(RRC,"[eNB] SystemInformationBlockType1 Encoded %d bits (%d bytes)\n",enc_rval.encoded,(enc_rval.encoded+7)/8);
#endif

  if (enc_rval.encoded==-1)
    return(-1);
  return((enc_rval.encoded+7)/8);
}
*/
// AT4 packet
uint8_t do_MIB(uint8_t Mod_id, LTE_DL_FRAME_PARMS *frame_parms, uint32_t frame, uint8_t *buffer)
{

  asn_enc_rval_t enc_rval;
  BCCH_BCH_Message_t mib;
  uint8_t sfn = (uint8_t)((frame>>2)&0xff);
  uint16_t spare=0;

  switch (frame_parms->N_RB_DL) {

  case 6:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n6;
    break;

  case 15:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n15;
    break;

  case 25:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n25;
    break;

  case 50:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n50;
    break;

  case 75:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n75;
    break;

  case 100:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n100;
    break;

  default:
    mib.message.dl_Bandwidth = MasterInformationBlock__dl_Bandwidth_n6;
    break;
  }

  switch (frame_parms->phich_config_common.phich_resource) {
  case oneSixth:
    mib.message.phich_Config.phich_Resource = 0;
    break;

  case half:
    mib.message.phich_Config.phich_Resource = 1;
    break;

  case one:
    mib.message.phich_Config.phich_Resource = 2;
    break;

  case two:
    mib.message.phich_Config.phich_Resource = 3;
    break;
  }

  printf("[MIB] systemBandwidth %x, phich_duration %x, phich_resource %x,sfn %x\n",
         (uint32_t)mib.message.dl_Bandwidth,
         (uint32_t)frame_parms->phich_config_common.phich_duration,
         (uint32_t)mib.message.phich_Config.phich_Resource,
         (uint32_t)sfn);
  mib.message.phich_Config.phich_Duration = frame_parms->phich_config_common.phich_duration;
  mib.message.systemFrameNumber.buf = &sfn;
  mib.message.systemFrameNumber.size = 1;
  mib.message.systemFrameNumber.bits_unused=0;
  mib.message.spare.buf = (uint8_t *)&spare;
  mib.message.spare.size = 2;
  mib.message.spare.bits_unused = 6;  // This makes a spare of 10 bits

  enc_rval = uper_encode_to_buffer(&asn_DEF_BCCH_BCH_Message,
                                   (void*)&mib,
                                   buffer,
                                   100);
  AssertFatal (enc_rval.encoded > 0, "ASN1 message encoding failed (%s, %lu)!\n",
               enc_rval.failed_type->name, enc_rval.encoded);

#if defined(ENABLE_ITTI)
# if !defined(DISABLE_XER_SPRINT)
  {
    char        message_string[20000];
    size_t      message_string_size;

    if ((message_string_size = xer_sprint(message_string, sizeof(message_string), &asn_DEF_BCCH_BCH_Message, (void *) &mib)) > 0) {
      MessageDef *msg_p;

      msg_p = itti_alloc_new_message_sized (TASK_RRC_ENB, RRC_DL_BCCH, message_string_size + sizeof (IttiMsgText));
      msg_p->ittiMsg.rrc_dl_bcch.size = message_string_size;
      memcpy(&msg_p->ittiMsg.rrc_dl_bcch.text, message_string, message_string_size);

      itti_send_msg_to_task(TASK_UNKNOWN, Mod_id, msg_p);
    }
  }
# endif
#endif

  if (enc_rval.encoded==-1) {
    return(-1);
  }

  return((enc_rval.encoded+7)/8);
  /*
  printf("MIB: %x ((MIB>>10)&63)+(MIB&3<<6)=SFN %x, MIB>>2&3 = phich_resource %d, MIB>>4&1 = phich_duration %d, MIB>>5&7 = system_bandwidth %d)\n",*(uint32_t *)buffer,
   (((*(uint32_t *)buffer)>>10)&0x3f)+(((*(uint32_t *)buffer)&3)<<6),
   ((*(uint32_t *)buffer)>>2)&0x3,
   ((*(uint32_t *)buffer)>>4)&0x1,
   ((*(uint32_t *)buffer)>>5)&0x7
   );
  */
}

uint8_t do_SIB1(uint8_t Mod_id, int CC_id,
                LTE_DL_FRAME_PARMS *frame_parms, uint8_t *buffer,
                BCCH_DL_SCH_Message_t *bcch_message,
                SystemInformationBlockType1_t **sib1
#if defined(ENABLE_ITTI)
                , RrcConfigurationReq *configuration
#endif
               )
{

  //  SystemInformation_t systemInformation;
  PLMN_IdentityInfo_t PLMN_identity_info;
  MCC_MNC_Digit_t dummy_mcc[3],dummy_mnc[3];
  asn_enc_rval_t enc_rval;
  SchedulingInfo_t schedulingInfo;
  SIB_Type_t sib_type;

  memset(bcch_message,0,sizeof(BCCH_DL_SCH_Message_t));
  bcch_message->message.present = BCCH_DL_SCH_MessageType_PR_c1;
  bcch_message->message.choice.c1.present = BCCH_DL_SCH_MessageType__c1_PR_systemInformationBlockType1;
  //  memcpy(&bcch_message.message.choice.c1.choice.systemInformationBlockType1,sib1,sizeof(SystemInformationBlockType1_t));

  *sib1 = &bcch_message->message.choice.c1.choice.systemInformationBlockType1;

  memset(&PLMN_identity_info,0,sizeof(PLMN_IdentityInfo_t));
  memset(&schedulingInfo,0,sizeof(SchedulingInfo_t));
  memset(&sib_type,0,sizeof(SIB_Type_t));



  PLMN_identity_info.plmn_Identity.mcc = CALLOC(1,sizeof(*PLMN_identity_info.plmn_Identity.mcc));
  memset(PLMN_identity_info.plmn_Identity.mcc,0,sizeof(*PLMN_identity_info.plmn_Identity.mcc));

  asn_set_empty(&PLMN_identity_info.plmn_Identity.mcc->list);//.size=0;

#if defined(ENABLE_ITTI)
  dummy_mcc[0] = (configuration->mcc / 100) % 10;
  dummy_mcc[1] = (configuration->mcc / 10) % 10;
  dummy_mcc[2] = (configuration->mcc / 1) % 10;
#else
  dummy_mcc[0] = 0;
  dummy_mcc[1] = 0;
  dummy_mcc[2] = 1;
#endif
  ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mcc->list,&dummy_mcc[0]);
  ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mcc->list,&dummy_mcc[1]);
  ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mcc->list,&dummy_mcc[2]);

  PLMN_identity_info.plmn_Identity.mnc.list.size=0;
  PLMN_identity_info.plmn_Identity.mnc.list.count=0;
#if defined(ENABLE_ITTI)

  if (configuration->mnc >= 100) {
    dummy_mnc[0] = (configuration->mnc / 100) % 10;
    dummy_mnc[1] = (configuration->mnc / 10) % 10;
    dummy_mnc[2] = (configuration->mnc / 1) % 10;
  } else {
    if (configuration->mnc_digit_length == 2) {
      dummy_mnc[0] = (configuration->mnc / 10) % 10;
      dummy_mnc[1] = (configuration->mnc / 1) % 10;
      dummy_mnc[2] = 0xf;
    } else {
      dummy_mnc[0] = (configuration->mnc / 100) % 100;
      dummy_mnc[1] = (configuration->mnc / 10) % 10;
      dummy_mnc[2] = (configuration->mnc / 1) % 10;
    }
  }

#else
  dummy_mnc[0] = 0;
  dummy_mnc[1] = 1;
  dummy_mnc[2] = 0xf;
#endif
  ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mnc.list,&dummy_mnc[0]);
  ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mnc.list,&dummy_mnc[1]);

  if (dummy_mnc[2] != 0xf) {
    ASN_SEQUENCE_ADD(&PLMN_identity_info.plmn_Identity.mnc.list,&dummy_mnc[2]);
  }

  //assign_enum(&PLMN_identity_info.cellReservedForOperatorUse,PLMN_IdentityInfo__cellReservedForOperatorUse_notReserved);
  PLMN_identity_info.cellReservedForOperatorUse=PLMN_IdentityInfo__cellReservedForOperatorUse_notReserved;

  ASN_SEQUENCE_ADD(&(*sib1)->cellAccessRelatedInfo.plmn_IdentityList.list,&PLMN_identity_info);


  // 16 bits
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.buf = MALLOC(2);
#if defined(ENABLE_ITTI)
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.buf[0] = (configuration->tac >> 8) & 0xff;
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.buf[1] = (configuration->tac >> 0) & 0xff;
#else
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.buf[0] = 0x00;
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.buf[1] = 0x01;
#endif
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.size=2;
  (*sib1)->cellAccessRelatedInfo.trackingAreaCode.bits_unused=0;

  // 28 bits
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf = MALLOC(8);
#if defined(ENABLE_ITTI)
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[0] = (configuration->cell_identity >> 20) & 0xff;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[1] = (configuration->cell_identity >> 12) & 0xff;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[2] = (configuration->cell_identity >>  4) & 0xff;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[3] = (configuration->cell_identity <<  4) & 0xf0;
#else
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[0] = 0x00;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[1] = 0x00;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[2] = 0x00;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.buf[3] = 0x10;
#endif
  (*sib1)->cellAccessRelatedInfo.cellIdentity.size=4;
  (*sib1)->cellAccessRelatedInfo.cellIdentity.bits_unused=4;

  //  assign_enum(&(*sib1)->cellAccessRelatedInfo.cellBarred,SystemInformationBlockType1__cellAccessRelatedInfo__cellBarred_notBarred);
  (*sib1)->cellAccessRelatedInfo.cellBarred=SystemInformationBlockType1__cellAccessRelatedInfo__cellBarred_notBarred;

  //  assign_enum(&(*sib1)->cellAccessRelatedInfo.intraFreqReselection,SystemInformationBlockType1__cellAccessRelatedInfo__intraFreqReselection_allowed);
  (*sib1)->cellAccessRelatedInfo.intraFreqReselection=SystemInformationBlockType1__cellAccessRelatedInfo__intraFreqReselection_notAllowed;
  (*sib1)->cellAccessRelatedInfo.csg_Indication=0;

  (*sib1)->cellSelectionInfo.q_RxLevMin=-65;
  (*sib1)->cellSelectionInfo.q_RxLevMinOffset=NULL;
  //(*sib1)->p_Max = CALLOC(1, sizeof(P_Max_t));
  //*((*sib1)->p_Max) = 23;
  (*sib1)->freqBandIndicator =
#if defined(ENABLE_ITTI)
    configuration->eutra_band[CC_id];
#else
    7;
#endif

  schedulingInfo.si_Periodicity=SchedulingInfo__si_Periodicity_rf8;

  // This is for SIB2/3
  sib_type=SIB_Type_sibType3;
  ASN_SEQUENCE_ADD(&schedulingInfo.sib_MappingInfo.list,&sib_type);
  ASN_SEQUENCE_ADD(&(*sib1)->schedulingInfoList.list,&schedulingInfo);

  //  ASN_SEQUENCE_ADD(&schedulingInfo.sib_MappingInfo.list,NULL);

#if defined(ENABLE_ITTI)

  if (configuration->frame_type[CC_id] == TDD)
#endif
  {
    (*sib1)->tdd_Config =                             CALLOC(1,sizeof(struct TDD_Config));

    (*sib1)->tdd_Config->subframeAssignment =
#if defined(ENABLE_ITTI)
      configuration->tdd_config[CC_id];
#else
      frame_parms->tdd_config;
#endif

    (*sib1)->tdd_Config->specialSubframePatterns =
#if defined(ENABLE_ITTI)
      configuration->tdd_config_s[CC_id];
#else
      frame_parms->tdd_config_S;
#endif
  }

  (*sib1)->si_WindowLength=SystemInformationBlockType1__si_WindowLength_ms20;
  (*sib1)->systemInfoValueTag=0;
  //  (*sib1).nonCriticalExtension = calloc(1,sizeof(*(*sib1).nonCriticalExtension));

#ifdef XER_PRINT
  xer_fprint(stdout, &asn_DEF_BCCH_DL_SCH_Message, (void*)bcch_message);
#endif
  enc_rval = uper_encode_to_buffer(&asn_DEF_BCCH_DL_SCH_Message,
                                   (void*)bcch_message,
                                   buffer,
                                   100);
  AssertFatal (enc_rval.encoded > 0, "ASN1 message encoding failed (%s, %lu)!\n",
               enc_rval.failed_type->name, enc_rval.encoded);

#if defined(ENABLE_ITTI)
# if !defined(DISABLE_XER_SPRINT)
  {
    char        message_string[10000];
    size_t      message_string_size;

    if ((message_string_size = xer_sprint(message_string, sizeof(message_string), &asn_DEF_BCCH_DL_SCH_Message, (void *)bcch_message)) > 0) {
      MessageDef *msg_p;

      msg_p = itti_alloc_new_message_sized (TASK_RRC_ENB, RRC_DL_BCCH, message_string_size + sizeof (IttiMsgText));
      msg_p->ittiMsg.rrc_dl_bcch.size = message_string_size;
      memcpy(&msg_p->ittiMsg.rrc_dl_bcch.text, message_string, message_string_size);

      itti_send_msg_to_task(TASK_UNKNOWN, Mod_id, msg_p);
    }
  }
# endif
#endif

#ifdef USER_MODE
  LOG_D(RRC,"[eNB] SystemInformationBlockType1 Encoded %d bits (%d bytes)\n",enc_rval.encoded,(enc_rval.encoded+7)/8);
#endif

  if (enc_rval.encoded==-1) {
    return(-1);
  }

  return((enc_rval.encoded+7)/8);
}

uint8_t do_SIB23(uint8_t Mod_id,
                 int CC_id,
                 LTE_DL_FRAME_PARMS *frame_parms,
                 uint8_t *buffer,
                 BCCH_DL_SCH_Message_t *bcch_message,
                 SystemInformationBlockType2_t **sib2,
                 SystemInformationBlockType3_t **sib3
#ifdef Rel10
                 ,
                 SystemInformationBlockType13_r9_t **sib13,
                 uint8_t MBMS_flag
#endif
#if defined(ENABLE_ITTI)
                 , RrcConfigurationReq *configuration
#endif
                )
{
  struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member *sib2_part,*sib3_part;
#ifdef Rel10
  struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member *sib13_part;
  MBSFN_SubframeConfigList_t *MBSFNSubframeConfigList;
  MBSFN_AreaInfoList_r9_t *MBSFNArea_list;
  struct MBSFN_AreaInfo_r9 *MBSFN_Area1, *MBSFN_Area2;
#endif
  asn_enc_rval_t enc_rval;

  if (bcch_message) {
    memset(bcch_message,0,sizeof(BCCH_DL_SCH_Message_t));
  } else {
    LOG_E(RRC,"[eNB %d] BCCH_MESSAGE is null, exiting\n", Mod_id);
    exit(-1);
  }

  if (!sib2) {
    LOG_E(RRC,"[eNB %d] sib2 is null, exiting\n", Mod_id);
    exit(-1);
  }

  if (!sib3) {
    LOG_E(RRC,"[eNB %d] sib3 is null, exiting\n", Mod_id);
    exit(-1);
  }

#ifdef Rel10
  LOG_I(RRC,"[eNB %d] Configuration SIB2/3, MBMS = %d\n", Mod_id, MBMS_flag);
#else
  LOG_I(RRC,"[eNB %d] Configuration SIB2/3\n", Mod_id);
#endif
  sib2_part = CALLOC(1,sizeof(struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member));
  sib3_part = CALLOC(1,sizeof(struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member));
  memset(sib2_part,0,sizeof(struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member));
  memset(sib3_part,0,sizeof(struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member));

  sib2_part->present = SystemInformation_r8_IEs__sib_TypeAndInfo__Member_PR_sib2;
  sib3_part->present = SystemInformation_r8_IEs__sib_TypeAndInfo__Member_PR_sib3;

  *sib2 = &sib2_part->choice.sib2;
  *sib3 = &sib3_part->choice.sib3;

#ifdef Rel10

  if (MBMS_flag > 0) {
    sib13_part = CALLOC(1,sizeof(struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member));
    memset(sib13_part,0,sizeof(struct SystemInformation_r8_IEs__sib_TypeAndInfo__Member));
    sib13_part->present = SystemInformation_r8_IEs__sib_TypeAndInfo__Member_PR_sib13_v920;
    *sib13 = &sib13_part->choice.sib13_v920;
  }

#endif

  // sib2

  (*sib2)->ac_BarringInfo = NULL;
#ifdef Rel10
#if 0
  (*sib2)->ssac_BarringForMMTEL_Voice_r9 = NULL;
  (*sib2)->ssac_BarringForMMTEL_Video_r9 = NULL;
  (*sib2)->ac_BarringForCSFB_r10 = NULL;
#endif
  (*sib2)->ext1 = NULL;
  (*sib2)->ext2 = NULL;
#endif

#if defined(ENABLE_ITTI)

  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.numberOfRA_Preambles                         = configuration->rach_numberOfRA_Preambles[CC_id];
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.preamblesGroupAConfig                        = NULL;

  if (configuration->rach_preamblesGroupAConfig[CC_id]) {
    (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.preamblesGroupAConfig
      = CALLOC(1,sizeof(struct RACH_ConfigCommon__preambleInfo__preamblesGroupAConfig));
    (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.preamblesGroupAConfig->sizeOfRA_PreamblesGroupA
      = configuration->rach_sizeOfRA_PreamblesGroupA[CC_id];
    (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.preamblesGroupAConfig->messageSizeGroupA
      = configuration->rach_messageSizeGroupA[CC_id];
    (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.preamblesGroupAConfig->messagePowerOffsetGroupB
      = configuration->rach_messagePowerOffsetGroupB[CC_id];
  }

  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.powerRampingParameters.powerRampingStep                   = configuration->rach_powerRampingStep[CC_id];
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.powerRampingParameters.preambleInitialReceivedTargetPower =
    configuration->rach_preambleInitialReceivedTargetPower[CC_id];
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.ra_SupervisionInfo.preambleTransMax                       = configuration->rach_preambleTransMax[CC_id];
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.ra_SupervisionInfo.ra_ResponseWindowSize                  = configuration->rach_raResponseWindowSize[CC_id];
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.ra_SupervisionInfo.mac_ContentionResolutionTimer          =
    configuration->rach_macContentionResolutionTimer[CC_id];
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.maxHARQ_Msg3Tx                                            = configuration->rach_maxHARQ_Msg3Tx[CC_id];

  // BCCH-Config
  (*sib2)->radioResourceConfigCommon.bcch_Config.modificationPeriodCoeff
    = configuration->bcch_modificationPeriodCoeff[CC_id];

  // PCCH-Config
  (*sib2)->radioResourceConfigCommon.pcch_Config.defaultPagingCycle
    = configuration->pcch_defaultPagingCycle[CC_id];
  (*sib2)->radioResourceConfigCommon.pcch_Config.nB
    = configuration->pcch_nB[CC_id];

  // PRACH-Config
  (*sib2)->radioResourceConfigCommon.prach_Config.rootSequenceIndex
    = configuration->prach_root[CC_id];
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.prach_ConfigIndex
    = configuration->prach_config_index[CC_id];
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.highSpeedFlag
    = configuration->prach_high_speed[CC_id];
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.zeroCorrelationZoneConfig
    = configuration->prach_zero_correlation[CC_id];
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.prach_FreqOffset
    = configuration->prach_freq_offset[CC_id];

  // PDSCH-Config
  (*sib2)->radioResourceConfigCommon.pdsch_ConfigCommon.referenceSignalPower
    = configuration->pdsch_referenceSignalPower[CC_id];
  (*sib2)->radioResourceConfigCommon.pdsch_ConfigCommon.p_b
    = configuration->pdsch_p_b[CC_id];

  // PUSCH-Config
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.n_SB
    = configuration->pusch_n_SB[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.hoppingMode
    = configuration->pusch_hoppingMode[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.pusch_HoppingOffset
    = configuration->pusch_hoppingOffset[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.enable64QAM
    = configuration->pusch_enable64QAM[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupHoppingEnabled
    = configuration->pusch_groupHoppingEnabled[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH
    = configuration->pusch_groupAssignment[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled
    = configuration->pusch_sequenceHoppingEnabled[CC_id];
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.cyclicShift
    = configuration->pusch_nDMRS1[CC_id];

  // PUCCH-Config

  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.deltaPUCCH_Shift
    = configuration->pucch_delta_shift[CC_id];
  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.nRB_CQI
    = configuration->pucch_nRB_CQI[CC_id];
  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.nCS_AN
    = configuration->pucch_nCS_AN[CC_id];
#ifndef Rel10
  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.n1PUCCH_AN
    = configuration->pucch_n1_AN[CC_id];
#endif

  // SRS Config
  if (configuration->srs_enable[CC_id]) {
    (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.present
      = SoundingRS_UL_ConfigCommon_PR_setup;
    (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.setup.srs_BandwidthConfig
      = configuration->srs_BandwidthConfig[CC_id];
    (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.setup.srs_SubframeConfig
      = configuration->srs_SubframeConfig[CC_id];
    (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.setup.ackNackSRS_SimultaneousTransmission
      = configuration->srs_ackNackST[CC_id];

    if (configuration->srs_MaxUpPts[CC_id]) {
      (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.setup.srs_MaxUpPts
        = CALLOC(1,sizeof(long));
      *(*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.setup.srs_MaxUpPts=1;
    } else {
      (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.setup.srs_MaxUpPts = NULL;
    }
  } else {
    (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.present=SoundingRS_UL_ConfigCommon_PR_release;
    (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.release=0;
  }

  // uplinkPowerControlCommon

  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.p0_NominalPUSCH
    = configuration->pusch_p0_Nominal[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.p0_NominalPUCCH
    = configuration->pucch_p0_Nominal[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.alpha
    = configuration->pusch_alpha[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format1
    = configuration->pucch_deltaF_Format1[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format1b
    = configuration->pucch_deltaF_Format1b[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2
    = configuration->pucch_deltaF_Format2[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2a
    = configuration->pucch_deltaF_Format2a[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2b
    = configuration->pucch_deltaF_Format2b[CC_id];
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaPreambleMsg3
    = configuration->msg3_delta_Preamble[CC_id];
  (*sib2)->radioResourceConfigCommon.ul_CyclicPrefixLength
    = configuration->ul_CyclicPrefixLength[CC_id];

  // UE Timers and Constants

  (*sib2)->ue_TimersAndConstants.t300
    = configuration->ue_TimersAndConstants_t300[CC_id];
  (*sib2)->ue_TimersAndConstants.t301
    = configuration->ue_TimersAndConstants_t301[CC_id];
  (*sib2)->ue_TimersAndConstants.t310
    = configuration->ue_TimersAndConstants_t310[CC_id];
  (*sib2)->ue_TimersAndConstants.n310
    = configuration->ue_TimersAndConstants_n310[CC_id];
  (*sib2)->ue_TimersAndConstants.t311
    = configuration->ue_TimersAndConstants_t311[CC_id];
  (*sib2)->ue_TimersAndConstants.n311
    = configuration->ue_TimersAndConstants_n311[CC_id];

#else
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.numberOfRA_Preambles=RACH_ConfigCommon__preambleInfo__numberOfRA_Preambles_n64;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.preambleInfo.preamblesGroupAConfig = NULL;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.powerRampingParameters.powerRampingStep=RACH_ConfigCommon__powerRampingParameters__powerRampingStep_dB2;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.powerRampingParameters.preambleInitialReceivedTargetPower=
    RACH_ConfigCommon__powerRampingParameters__preambleInitialReceivedTargetPower_dBm_100;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.ra_SupervisionInfo.preambleTransMax=RACH_ConfigCommon__ra_SupervisionInfo__preambleTransMax_n10;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.ra_SupervisionInfo.ra_ResponseWindowSize=RACH_ConfigCommon__ra_SupervisionInfo__ra_ResponseWindowSize_sf10;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.ra_SupervisionInfo.mac_ContentionResolutionTimer=
    RACH_ConfigCommon__ra_SupervisionInfo__mac_ContentionResolutionTimer_sf48;
  (*sib2)->radioResourceConfigCommon.rach_ConfigCommon.maxHARQ_Msg3Tx = 4;

  // BCCH-Config
  (*sib2)->radioResourceConfigCommon.bcch_Config.modificationPeriodCoeff=BCCH_Config__modificationPeriodCoeff_n2;

  // PCCH-Config
  (*sib2)->radioResourceConfigCommon.pcch_Config.defaultPagingCycle = PCCH_Config__defaultPagingCycle_rf128;
  (*sib2)->radioResourceConfigCommon.pcch_Config.nB=PCCH_Config__nB_oneT;

  // PRACH-Config
  (*sib2)->radioResourceConfigCommon.prach_Config.rootSequenceIndex=Mod_id;//0;//384;
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.prach_ConfigIndex = 0;//3;
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.highSpeedFlag = 0;
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.zeroCorrelationZoneConfig = 1;//12;
  (*sib2)->radioResourceConfigCommon.prach_Config.prach_ConfigInfo.prach_FreqOffset = 2;

  // PDSCH-Config
  (*sib2)->radioResourceConfigCommon.pdsch_ConfigCommon.referenceSignalPower=0;  // corresponds to 24.7 dBm 5 MHz/ 27.7 10 MHz/ 30.7 20 MHz

  if (frame_parms->mode1_flag==1) {
    (*sib2)->radioResourceConfigCommon.pdsch_ConfigCommon.p_b=0;
  } else {
    (*sib2)->radioResourceConfigCommon.pdsch_ConfigCommon.p_b=1;

  }

  // PUSCH-Config
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.n_SB=1;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.hoppingMode=PUSCH_ConfigCommon__pusch_ConfigBasic__hoppingMode_interSubFrame;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.pusch_HoppingOffset=0;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.pusch_ConfigBasic.enable64QAM=0;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupHoppingEnabled=1;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.groupAssignmentPUSCH=0;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.sequenceHoppingEnabled=0;
  (*sib2)->radioResourceConfigCommon.pusch_ConfigCommon.ul_ReferenceSignalsPUSCH.cyclicShift=0;

  // PUCCH-Config

  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.deltaPUCCH_Shift=PUCCH_ConfigCommon__deltaPUCCH_Shift_ds1;
  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.nRB_CQI = 1;
  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.nCS_AN = 0;
  (*sib2)->radioResourceConfigCommon.pucch_ConfigCommon.n1PUCCH_AN = 32;


  (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.present=SoundingRS_UL_ConfigCommon_PR_release;
  (*sib2)->radioResourceConfigCommon.soundingRS_UL_ConfigCommon.choice.release=0;

  // uplinkPowerControlCommon

  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.p0_NominalPUSCH = -108;
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.p0_NominalPUCCH = -108;
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.alpha=UplinkPowerControlCommon__alpha_al1;
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format1=DeltaFList_PUCCH__deltaF_PUCCH_Format1_deltaF2;
  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format1b=DeltaFList_PUCCH__deltaF_PUCCH_Format1b_deltaF3;

  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2=DeltaFList_PUCCH__deltaF_PUCCH_Format2_deltaF0;

  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2a=DeltaFList_PUCCH__deltaF_PUCCH_Format2a_deltaF0;

  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaFList_PUCCH.deltaF_PUCCH_Format2b=DeltaFList_PUCCH__deltaF_PUCCH_Format2b_deltaF0;

  (*sib2)->radioResourceConfigCommon.uplinkPowerControlCommon.deltaPreambleMsg3 = 6;

  (*sib2)->radioResourceConfigCommon.ul_CyclicPrefixLength=UL_CyclicPrefixLength_len1;

  (*sib2)->ue_TimersAndConstants.t300=UE_TimersAndConstants__t300_ms1000;

  (*sib2)->ue_TimersAndConstants.t301=UE_TimersAndConstants__t301_ms1000;

  (*sib2)->ue_TimersAndConstants.t310=UE_TimersAndConstants__t310_ms1000;

  (*sib2)->ue_TimersAndConstants.n310=UE_TimersAndConstants__n310_n20;

  (*sib2)->ue_TimersAndConstants.t311=UE_TimersAndConstants__t311_ms10000;

  (*sib2)->ue_TimersAndConstants.n311=UE_TimersAndConstants__n311_n1;

#endif

  (*sib2)->freqInfo.additionalSpectrumEmission = 1;
  (*sib2)->freqInfo.ul_CarrierFreq = NULL;
  (*sib2)->freqInfo.ul_Bandwidth = NULL;
  //  (*sib2)->mbsfn_SubframeConfigList = NULL;

#ifdef Rel10

  if (MBMS_flag > 0) {
    LOG_I(RRC,"Adding MBSFN subframe Configuration 1 to SIB2\n");
    MBSFN_SubframeConfig_t *sib2_mbsfn_SubframeConfig1;
    (*sib2)->mbsfn_SubframeConfigList = CALLOC(1,sizeof(struct MBSFN_SubframeConfigList));
    MBSFNSubframeConfigList = (*sib2)->mbsfn_SubframeConfigList;

    sib2_mbsfn_SubframeConfig1= CALLOC(1,sizeof(*sib2_mbsfn_SubframeConfig1));
    memset((void*)sib2_mbsfn_SubframeConfig1,0,sizeof(*sib2_mbsfn_SubframeConfig1));

    sib2_mbsfn_SubframeConfig1->radioframeAllocationPeriod= MBSFN_SubframeConfig__radioframeAllocationPeriod_n4;
    sib2_mbsfn_SubframeConfig1->radioframeAllocationOffset= 1;
    sib2_mbsfn_SubframeConfig1->subframeAllocation.present= MBSFN_SubframeConfig__subframeAllocation_PR_oneFrame;
    sib2_mbsfn_SubframeConfig1->subframeAllocation.choice.oneFrame.buf= MALLOC(1);
    sib2_mbsfn_SubframeConfig1->subframeAllocation.choice.oneFrame.size= 1;
    sib2_mbsfn_SubframeConfig1->subframeAllocation.choice.oneFrame.bits_unused= 2;

    if (frame_parms->frame_type == TDD) {
      sib2_mbsfn_SubframeConfig1->subframeAllocation.choice.oneFrame.buf[0]=0x08<<2;// shift 2 cuz 2last bits are unused.
    } else { /// 111000
      sib2_mbsfn_SubframeConfig1->subframeAllocation.choice.oneFrame.buf[0]=0x38<<2;
    }

    ASN_SEQUENCE_ADD(&MBSFNSubframeConfigList->list,sib2_mbsfn_SubframeConfig1);

    if (MBMS_flag == 4 ) {
      LOG_I(RRC,"Adding MBSFN subframe Configuration 2 to SIB2\n");
      MBSFN_SubframeConfig_t *sib2_mbsfn_SubframeConfig2;
      sib2_mbsfn_SubframeConfig2= CALLOC(1,sizeof(*sib2_mbsfn_SubframeConfig2));
      memset((void*)sib2_mbsfn_SubframeConfig2,0,sizeof(*sib2_mbsfn_SubframeConfig2));

      sib2_mbsfn_SubframeConfig2->radioframeAllocationPeriod= MBSFN_SubframeConfig__radioframeAllocationPeriod_n4;
      sib2_mbsfn_SubframeConfig2->radioframeAllocationOffset= 1;
      sib2_mbsfn_SubframeConfig2->subframeAllocation.present= MBSFN_SubframeConfig__subframeAllocation_PR_oneFrame;
      sib2_mbsfn_SubframeConfig2->subframeAllocation.choice.oneFrame.buf= MALLOC(1);
      sib2_mbsfn_SubframeConfig2->subframeAllocation.choice.oneFrame.size= 1;
      sib2_mbsfn_SubframeConfig2->subframeAllocation.choice.oneFrame.bits_unused= 2;

      if (frame_parms->frame_type == TDD) {
        sib2_mbsfn_SubframeConfig2->subframeAllocation.choice.oneFrame.buf[0]=0x08<<2;// shift 2 cuz 2last bits are unused.
      } else { ///000111
        sib2_mbsfn_SubframeConfig2->subframeAllocation.choice.oneFrame.buf[0]=0x07<<2;
      }

      ASN_SEQUENCE_ADD(&MBSFNSubframeConfigList->list,sib2_mbsfn_SubframeConfig2);
    }
  }

#else // no MBMS transmission
  (*sib2)->mbsfn_SubframeConfigList = NULL;
#endif

  (*sib2)->timeAlignmentTimerCommon=TimeAlignmentTimer_infinity;//TimeAlignmentTimer_sf5120;

  /// (*SIB3)
#ifdef Rel10