FreeCalypso > hg > fc-magnetite
view src/g23m-gsm/rr/rr_em.c @ 364:44795dbadbae
FCHG: bug in CV process caused the control loop to be skipped
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Sat, 30 Dec 2017 06:10:48 +0000 |
parents | 27a4235405c6 |
children |
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/* +----------------------------------------------------------------------------- | Project : | Modul : +----------------------------------------------------------------------------- | Copyright 2002 Texas Instruments Berlin, AG | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments Berlin, AG | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments Berlin, AG. +----------------------------------------------------------------------------- | Purpose : This Module defines the engineering mode (EM) device driver for the | G23 protocol stack. This driver is used to control all engineering | mode related functions. +----------------------------------------------------------------------------- */ #ifndef RR_EM_C #define RR_EM_C #define ENTITY_RR /*==== INCLUDES ===================================================*/ #include <string.h> #include <stdlib.h> #include <stddef.h> /* offsetof */ #include <stdio.h> /* sprintf */ #include "typedefs.h" #include "pcm.h" #include "pconst.cdg" #include "mconst.cdg" #include "message.h" #include "ccdapi.h" #include "vsi.h" #include "custom.h" #include "gsm.h" #include "prim.h" #include "cnf_rr.h" #include "tok.h" #include "rr.h" #include "rr_em.h" /*==== EXPORT =====================================================*/ /*==== VARIABLES ==================================================*/ #ifdef FF_EM_MODE /* These variables are used between entities. Even this is not a clean solution it is a straigth forward way to reduce the overhead to a minimum. A clean solution would be based on an only usage of primitives which would stress the os with no aditional advantage!! */ /* these are accessed by ACI */ GLOBAL UBYTE em_rr_sem_buffer [EM_RR_SEM_SIZE]; /*lint -esym(552,em_rr_sem_buffer) -esym(765,em_rr_sem_buffer ) */ GLOBAL UBYTE em_rr_sem_index; /*lint -esym(765,em_rr_sem_index)*/ GLOBAL UBYTE em_act_dlt = 0; /*lint -esym(765,em_act_dlt) | used by ALR */ GLOBAL UBYTE em_act_rlt = 0; /*lint -esym(765,em_act_rlt) | used by ALR */ static USHORT ma [MAX_MA_CHANNELS]; /* MA list after starting time */ static USHORT ma2[MAX_MA_CHANNELS]; /* MA list before starting time if available */ static UBYTE v_start=0; /* starting time valid */ static UBYTE maio2=0; static T_HANDLE sem_EM_RR; static UBYTE em_rr_trace_occured; /* Event tracing flags for EM */ GLOBAL BOOL rr_v[EM_MAX_RR_EVENTS]; GLOBAL USHORT em_assign_fail_rr_cause; GLOBAL USHORT em_handover_fail_rr_cause; LOCAL void em_rr_sem_clear (void); LOCAL void rr_em_first_event_check(void); #endif /* FF_EM_MODE */ /*==== FUNCTIONS ==================================================*/ #ifdef FF_EM_MODE /* +------------------------------------------------------------------------------ | Function : dat_em_get_hchn +------------------------------------------------------------------------------ | Description : This function stores the hopping channels after change occured. | | Parameters : channel_array - channel mode 1 | channel2_array - channel mode 2 | start - valid flag for channel mode2 | maio_2 - MAIO for before time configuration | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_get_hchn (USHORT* channel_array, USHORT* channel2_array, UBYTE start,UBYTE maio_2) { TRACE_FUNCTION ("dat_em_get_hchn()"); memset(ma, 0, 65); memset(ma2, 0, 65); memcpy(ma, channel_array, 65); v_start = start; if (v_start) { maio2 = maio_2; memcpy(ma2, channel2_array, 65); } } /* +------------------------------------------------------------------------------ | Function : em_init_get_hchn +------------------------------------------------------------------------------ | Description : initiates the hopping list. This is necessary, because a request | of the hopping list immideatly after switch on causes a reset. | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void em_init_get_hchn () { TRACE_FUNCTION ("em_init_get_hchn()"); ma[0] = NOT_PRESENT_16BIT; ma2[0] = NOT_PRESENT_16BIT; } /* +------------------------------------------------------------------------------ | Function : em_get_first_codec +------------------------------------------------------------------------------ | Description : Returns the highest bit rate AMR codec mode | | Parameters : acs - Active codec set | | Return : void +------------------------------------------------------------------------------ */ GLOBAL UBYTE em_get_first_codec(UBYTE acs) { UBYTE i; /* Find Highest bit rate codec mode from ACS */ for(i=0;i<8;i++) { if((0x80>>i) & acs ) break; } /* First codec( Highest bit rate codec mode) */ return (EM_AMR_MODE_12_2-i); } /* +------------------------------------------------------------------------------ | Function : dat_em_sc_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_SC_INFO_REQ. | | Parameters : Primitive from EM - T_EM_SC_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_sc_info_req (T_EM_SC_INFO_REQ *em_sc_info_req) { GET_INSTANCE_DATA; PALLOC(em_sc_info_cnf, EM_SC_INFO_CNF); memset (em_sc_info_cnf, 0, sizeof (T_EM_SC_INFO_CNF)); PFREE(em_sc_info_req); TRACE_FUNCTION ("dat_em_sc_info_req()"); em_sc_info_cnf->vocoder = EM_VOC_NA; switch (GET_STATE (STATE_ATT)) { case ATT_IDLE: if (rr_data->nc_data[SC_INDEX].bcch_status EQ DECODED) { em_sc_info_cnf->arfcn = rr_data->nc_data[SC_INDEX].arfcn; em_sc_info_cnf->c1 = rr_data->nc_data[SC_INDEX].c1; em_sc_info_cnf->c2 = rr_data->nc_data[SC_INDEX].c2; em_sc_info_cnf->rxlev = rr_data->nc_data[SC_INDEX].rxlev; em_sc_info_cnf->bsic = rr_data->nc_data[SC_INDEX].bsic; em_sc_info_cnf->dsc = em_act_dlt; em_sc_info_cnf->txlev = rr_data->sc_data.cd.cell_options.pow_ctrl; em_sc_info_cnf->tn = rr_data->sc_data.chan_desc.tn; em_sc_info_cnf->lac = rr_data->nc_data[SC_INDEX].lai.lac; em_sc_info_cnf->cba = rr_data->nc_data[SC_INDEX].rach.cell_bar_access; em_sc_info_cnf->cbq = rr_data->nc_data[SC_INDEX].c2_par.cbq; em_sc_info_cnf->cell_id = rr_data->nc_data[SC_INDEX].cell_id; em_sc_info_cnf->cell_type_ind = EM_CELL_GSM; #ifdef GPRS if(rr_data->nc_data[SC_INDEX].rac NEQ NOT_PRESENT_8BIT) em_sc_info_cnf->cell_type_ind = EM_CELL_GPRS; #endif } else if (rr_data->nc_data[SC_INDEX].bcch_status EQ NON_DECODED) { em_sc_info_cnf->arfcn = rr_data->nc_data[SC_INDEX].arfcn; em_sc_info_cnf->rxlev = rr_data->nc_data[SC_INDEX].rxlev; em_sc_info_cnf->bsic = rr_data->nc_data[SC_INDEX].bsic; } break; case ATT_DEDICATED: if (!rr_data->ms_data.measurement_report.valid) break; em_sc_info_cnf->arfcn = rr_data->ms_data.measurement_report.arfcn; em_sc_info_cnf->bsic = rr_data->nc_data[SC_INDEX].bsic; em_sc_info_cnf->txlev = rr_data->sc_data.cd.cell_options.pow_ctrl; em_sc_info_cnf->tn = rr_data->sc_data.chan_desc.tn; em_sc_info_cnf->lac = rr_data->nc_data[SC_INDEX].lai.lac; em_sc_info_cnf->cell_id = rr_data->nc_data[SC_INDEX].cell_id; em_sc_info_cnf->rxlev_f = rr_data->ms_data.measurement_report.rx_lev_full; em_sc_info_cnf->rxlev_s = rr_data->ms_data.measurement_report.rx_lev_sub; em_sc_info_cnf->rlt = em_act_rlt; em_sc_info_cnf->tav = rr_data->sc_data.new_ta; em_sc_info_cnf->rxqual_f = rr_data->ms_data.measurement_report.rx_qual_full; em_sc_info_cnf->rxqual_s = rr_data->ms_data.measurement_report.rx_qual_sub; em_sc_info_cnf->vocoder = rr_data->sc_data.ch_mode; if (rr_data->nc_data[SC_INDEX].bcch_status EQ DECODED) { em_sc_info_cnf->cell_type_ind = EM_CELL_GSM; #ifdef GPRS if(rr_data->nc_data[SC_INDEX].rac NEQ NOT_PRESENT_8BIT) em_sc_info_cnf->cell_type_ind = EM_CELL_GPRS; #endif } break; default: break; }/*switch*/ PSENDX(MMI, em_sc_info_cnf); } /*dat_em_sc_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_nc_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_NC_INFO_REQ. | | Parameters : Primitive from EM - T_EM_NC_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_nc_info_req (T_EM_NC_INFO_REQ *em_nc_info_req) { GET_INSTANCE_DATA; UBYTE index = 0; UBYTE index2 = 0; PALLOC(em_nc_info_cnf, EM_NC_INFO_CNF); memset (em_nc_info_cnf, 0, sizeof (T_EM_NC_INFO_CNF)); memset (em_nc_info_cnf->rac, 0xff, EM_MAX_NUM_NC); PFREE(em_nc_info_req); TRACE_FUNCTION ("dat_em_nc_info_req()"); switch (GET_STATE (STATE_ATT)) { case ATT_IDLE: for (index = 0 , index2 = 0 ; index < EM_MAX_NUM_NC ; index++) { if (rr_data->nc_data[index].bcch_status EQ DECODED) { em_nc_info_cnf->arfcn_nc[index2] = rr_data->nc_data[index].arfcn; em_nc_info_cnf->c1_nc[index2] = rr_data->nc_data[index].c1; em_nc_info_cnf->c2_nc[index2] = rr_data->nc_data[index].c2; em_nc_info_cnf->rxlev_nc[index2] = rr_data->nc_data[index].rxlev; em_nc_info_cnf->bsic_nc[index2] = rr_data->nc_data[index].bsic; em_nc_info_cnf->cell_id_nc[index2] = rr_data->nc_data[index].cell_id; em_nc_info_cnf->lac_nc[index2] = rr_data->nc_data[index].lai.lac; em_nc_info_cnf->frame_offset[index2] = rr_data->ms_data.measurement_report.ncells.frame_offset[index]; em_nc_info_cnf->time_alignmt[index2] = rr_data->ms_data.measurement_report.ncells.time_alignmt[index]; em_nc_info_cnf->cba_nc[index2] = rr_data->nc_data[index].rach.cell_bar_access; em_nc_info_cnf->cbq_nc[index2] = rr_data->nc_data[index].c2_par.cbq; em_nc_info_cnf->cell_type_ind[index2] = EM_CELL_GSM; #ifdef GPRS em_nc_info_cnf->rac[index2] = rr_data->nc_data[index].rac; /* rac in nc_data is set only when v_gprs_ind is present in SI3/SI4 rest octets. Since v_gprs_ind is not stored,rac is used to check gprs support in the cell */ if(em_nc_info_cnf->rac[index2] NEQ NOT_PRESENT_8BIT) em_nc_info_cnf->cell_type_ind[index2] = EM_CELL_GPRS; #endif em_nc_info_cnf->cell_resel_offset[index2] = rr_data->nc_data[index].c2_par.cell_reselect_offset; em_nc_info_cnf->temp_offset[index2] = rr_data->nc_data[index].c2_par.temp_offset; em_nc_info_cnf->rxlev_acc_min[index2] = rr_data->nc_data[index].select_para.rxlev_access_min; index2++; } /* if decoded */ else if (rr_data->nc_data[index].bcch_status EQ NON_DECODED) { em_nc_info_cnf->arfcn_nc[index2] = rr_data->nc_data[index].arfcn; em_nc_info_cnf->rxlev_nc[index2] = rr_data->nc_data[index].rxlev; em_nc_info_cnf->bsic_nc[index2] = rr_data->nc_data[index].bsic; index2++; } /* if non decoded */ } /* for */ em_nc_info_cnf->no_ncells = rr_data->ms_data.measurement_report.ncells.no_of_ncells; break; case ATT_DEDICATED: { if (!rr_data->ms_data.measurement_report.valid) break; em_nc_info_cnf->no_ncells = rr_data->ms_data.measurement_report.ncells.no_of_ncells; for (index = 0; index< rr_data->ms_data.measurement_report.ncells.no_of_ncells; index++) { /*in the measurement report the cells are ordered by fieldstrength*/ em_nc_info_cnf->arfcn_nc[index] = rr_data->ms_data.measurement_report.ncells.arfcn[index]; em_nc_info_cnf->rxlev_nc[index] = rr_data->ms_data.measurement_report.ncells.rx_lev[index]; em_nc_info_cnf->bsic_nc[index] = rr_data->ms_data.measurement_report.ncells.bsic[index]; em_nc_info_cnf->frame_offset[index]= rr_data->ms_data.measurement_report.ncells.frame_offset[index]; em_nc_info_cnf->time_alignmt[index]= rr_data->ms_data.measurement_report.ncells.time_alignmt[index]; } /*for*/ }/*case*/ break; default: break; }/*switch*/ PSENDX(MMI, em_nc_info_cnf); }/*dat_em_nc_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_loc_pag_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_LOC_PAG_INFO_REQ. | | Parameters : Primitive from EM - T_EM_LOC_PAG_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_loc_pag_info_req (T_EM_LOC_PAG_INFO_REQ *em_loc_pag_info_req) { GET_INSTANCE_DATA; PALLOC(em_loc_pag_info_cnf, EM_LOC_PAG_INFO_CNF); memset (em_loc_pag_info_cnf, 0, sizeof (T_EM_LOC_PAG_INFO_CNF)); PFREE(em_loc_pag_info_req); TRACE_FUNCTION ("dat_em_loc_pag_info_req()"); if (rr_data->nc_data[SC_INDEX].bcch_status EQ DECODED) { memcpy(em_loc_pag_info_cnf->mcc, rr_data->nc_data[SC_INDEX].lai.mcc, SIZE_MCC); /*check for MNC with 2 digits*/ /* Fixed for Issue 21468 */ if (rr_data->nc_data[SC_INDEX].lai.mnc[2] NEQ 0xF) /*defines a 3 digit NMC*/ { memcpy(em_loc_pag_info_cnf->mnc, rr_data->nc_data[SC_INDEX].lai.mnc, SIZE_MNC); } else /*2 digit -> leave the first value empty*/ { em_loc_pag_info_cnf->mnc[1] = rr_data->nc_data[SC_INDEX].lai.mnc[0]; em_loc_pag_info_cnf->mnc[2] = rr_data->nc_data[SC_INDEX].lai.mnc[1]; } em_loc_pag_info_cnf->bs_pa_mfrms = rr_data->nc_data[SC_INDEX].control_descr.bs_pa_mfrms; em_loc_pag_info_cnf->t3212 = rr_data->nc_data[SC_INDEX].control_descr.t3212; } if (rr_data->ms_data.tmsi_available EQ TRUE) em_loc_pag_info_cnf->tmsi = rr_data->ms_data.tmsi_binary; PSENDX(MMI, em_loc_pag_info_cnf); }/*dat_em_loc_pag_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_plmn_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_PLMN_INFO_REQ. | | Parameters : Primitive from EM - T_EM_PLMN_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_plmn_info_req (T_EM_PLMN_INFO_REQ *em_plmn_info_req) { GET_INSTANCE_DATA; PALLOC(em_plmn_info_cnf, EM_PLMN_INFO_CNF); memset (em_plmn_info_cnf, 0, sizeof (T_EM_PLMN_INFO_CNF)); PFREE(em_plmn_info_req); TRACE_FUNCTION ("dat_em_plmn_info_req()"); em_plmn_info_cnf->no_creq_max = rr_data->nc_data[SC_INDEX].rach.max_retrans; em_plmn_info_cnf->reest_flag = rr_data->nc_data[SC_INDEX].rach.re; em_plmn_info_cnf->txpwr_max = rr_data->nc_data[SC_INDEX].select_para.ms_txpwr_max_cch; em_plmn_info_cnf->rxlev_min = rr_data->nc_data[SC_INDEX].select_para.rxlev_access_min; em_plmn_info_cnf->rel_cause = 0xff; /* these info will be parsed by aci */ PSENDX(MMI, em_plmn_info_cnf); }/*dat_em_plmn_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_cip_hop_dtx_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_CIP_HOP_DTX_INFO_REQ. | | Parameters : Primitive from EM - T_EM_CIP_HOP_DTX_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_cip_hop_dtx_info_req (T_EM_CIP_HOP_DTX_INFO_REQ *em_cip_hop_dtx_info_req) { GET_INSTANCE_DATA; UBYTE i; PALLOC(em_cip_hop_dtx_info_cnf, EM_CIP_HOP_DTX_INFO_CNF); memset (em_cip_hop_dtx_info_cnf, 0, sizeof (T_EM_CIP_HOP_DTX_INFO_CNF)); PFREE(em_cip_hop_dtx_info_req); TRACE_FUNCTION ("dat_em_cip_hop_dtx_info_req()"); /* Intialize to 0xffff. No hopping channels */ em_cip_hop_dtx_info_cnf->hop_chn.ma[0] = NOT_PRESENT_16BIT; em_cip_hop_dtx_info_cnf->hop_chn2.ma[0] = NOT_PRESENT_16BIT; if((GET_STATE(STATE_ATT) EQ ATT_DEDICATED) AND (GET_STATE(STATE_DAT) EQ DAT_DEDICATED)) { /* cipher status */ em_cip_hop_dtx_info_cnf->ciph_stat = rr_data->sc_data.ciph_on; /* Hopping status */ em_cip_hop_dtx_info_cnf->hop = rr_data->sc_data.chan_desc.hop; if (rr_data->sc_data.chan_desc.hop EQ H_NO) { /* Hopping is not configured */ em_cip_hop_dtx_info_cnf->arfcn = rr_data->sc_data.chan_desc.arfcn; } else { /* hopping sequence no */ em_cip_hop_dtx_info_cnf->hsn = rr_data->sc_data.chan_desc.hsn; } if(em_cip_hop_dtx_info_cnf->hop NEQ H_NO) { /* MAIO */ em_cip_hop_dtx_info_cnf->hop_chn.maio = rr_data->sc_data.chan_desc.maio; i=0; while((i<MAX_MA_CHANNELS) AND (ma[i] NEQ NOT_PRESENT_16BIT)) { em_cip_hop_dtx_info_cnf->hop_chn.ma[i] = ma[i]; i++; } /* Number of hopping channels */ em_cip_hop_dtx_info_cnf->hop_chn.nr_arfcns = i; if(i < MAX_MA_CHANNELS) { em_cip_hop_dtx_info_cnf->hop_chn.ma[i] = NOT_PRESENT_16BIT; } /* starting time status */ em_cip_hop_dtx_info_cnf->v_start = v_start; /* Hopping list after time */ if (v_start) { /* MAIO */ em_cip_hop_dtx_info_cnf->hop_chn2.maio = maio2; i=0; while((i<MAX_MA_CHANNELS) AND (ma2[i] NEQ NOT_PRESENT_16BIT)) { em_cip_hop_dtx_info_cnf->hop_chn2.ma[i] = ma2[i]; i++; } /* Number of hopping channels */ em_cip_hop_dtx_info_cnf->hop_chn2.nr_arfcns = i; if(i < MAX_MA_CHANNELS) { em_cip_hop_dtx_info_cnf->hop_chn2.ma[i] = NOT_PRESENT_16BIT; } } /* v_start */ } /* hop NEQ H_NO */ } /* dedicated state */ /* DTX status */ em_cip_hop_dtx_info_cnf->dtx_stat = rr_data->sc_data.cd.dtx; PSENDX(MMI, em_cip_hop_dtx_info_cnf); }/*dat_em_cip_hop_dtx_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_mobdata_power_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_POWER_INFO_REQ. | | Parameters : Primitive from EM - T_EM_POWER_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_mobdata_power_info_req (T_EM_POWER_INFO_REQ *em_power_info_req) { GET_INSTANCE_DATA; PALLOC(em_power_info_cnf, EM_POWER_INFO_CNF); PFREE(em_power_info_req); TRACE_FUNCTION ("dat_em_mobdata_power_info_req()"); memset (em_power_info_cnf, 0, sizeof (T_EM_POWER_INFO_CNF)); memcpy(&em_power_info_cnf->classm2, &rr_data->ms_data.classmark2, sizeof (T_classm2)); memcpy(&em_power_info_cnf->classm3, &rr_data->ms_data.classmark3, sizeof (T_classm3)); PSENDX(MMI, em_power_info_cnf); }/*dat_em_mobdata_power_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_mobdata_id_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_IDENTITY_INFO_REQ. | | Parameters : Primitive from EM - T_EM_IDENTITY_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_mobdata_id_info_req (T_EM_IDENTITY_INFO_REQ *em_identity_info_req) { GET_INSTANCE_DATA; PALLOC(em_identity_info_cnf, EM_IDENTITY_INFO_CNF); memset (em_identity_info_cnf, 0, sizeof (T_EM_IDENTITY_INFO_CNF)); PFREE(em_identity_info_req); TRACE_FUNCTION ("dat_em_mobdata_id_info_req()"); /* * The values for IMEI and IMEISV are identical up to the last 4bits. The 'ident_type' distinguish * IMEI and IMEISV where ident_type = 3 is synonymously with IMEISV. In case only IMEI is needed, * em_mm_mobdata_id_info_req->em_imei.ident_dig[16] should not considered. */ em_identity_info_cnf->em_imeisv.ident_type = rr_data->ms_data.imei.ident_type; em_identity_info_cnf->em_imeisv.v_ident_dig = rr_data->ms_data.imei.v_ident_dig; em_identity_info_cnf->em_imeisv.c_ident_dig = rr_data->ms_data.imei.c_ident_dig; em_identity_info_cnf->em_imeisv.odd_even = rr_data->ms_data.imei.odd_even; memcpy (em_identity_info_cnf->em_imeisv.ident_dig, rr_data->ms_data.imei.ident_dig, 16); if (rr_data->ms_data.imsi_available) /* SIM available */ { em_identity_info_cnf->em_imsi.ident_type = rr_data->ms_data.imsi.ident_type; em_identity_info_cnf->em_imsi.v_ident_dig = rr_data->ms_data.imsi.v_ident_dig; em_identity_info_cnf->em_imsi.c_ident_dig = rr_data->ms_data.imsi.c_ident_dig; em_identity_info_cnf->em_imsi.odd_even = rr_data->ms_data.imsi.odd_even; memcpy (em_identity_info_cnf->em_imsi.ident_dig, rr_data->ms_data.imsi.ident_dig, 16); } if (rr_data->ms_data.tmsi_available EQ TRUE) em_identity_info_cnf->tmsi = rr_data->ms_data.tmsi_binary; PSENDX(MMI, em_identity_info_cnf); } /*dat_em_mobdata_id_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_mobdata_version_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_SW_VERSION_INFO_REQ. | | Parameters : Primitive from EM - T_EM_SW_VERSION_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_mobdata_version_info_req (T_EM_SW_VERSION_INFO_REQ *em_sw_version_info_req) { PALLOC(em_sw_version_info_cnf, EM_SW_VERSION_INFO_CNF); PFREE(em_sw_version_info_req); TRACE_FUNCTION ("dat_em_mobdata_version_info_req()"); memset (em_sw_version_info_cnf, 0, sizeof (T_EM_SW_VERSION_INFO_CNF)); em_sw_version_info_cnf->v_mmi = 0xFF; em_sw_version_info_cnf->v_sim = 0xFF; em_sw_version_info_cnf->v_cc = 0xFF; em_sw_version_info_cnf->v_ss = 0xFF; em_sw_version_info_cnf->v_sms = 0xFF; em_sw_version_info_cnf->v_mm = 0xFF; em_sw_version_info_cnf->v_rr = 0xFF; em_sw_version_info_cnf->v_dl = 0xFF; em_sw_version_info_cnf->v_l1 = 0xFF; PSENDX(MMI, em_sw_version_info_cnf); }/*dat_em_mobdata_version_info_req*/ /* +------------------------------------------------------------------------------ | Function : dat_em_amr_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_AMR_INFO_REQ. | | Parameters : Primitive from EM - T_EM_AMR_INFO_REQ | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_amr_info_req (T_EM_AMR_INFO_REQ *em_amr_info_req) { GET_INSTANCE_DATA; UBYTE i=0; PALLOC(em_amr_info_cnf, EM_AMR_INFO_CNF); memset (em_amr_info_cnf, 0, sizeof (T_EM_AMR_INFO_CNF)); PFREE(em_amr_info_req); TRACE_FUNCTION ("dat_em_amr_info_req()"); /* AMR information is valid only in dedicated state, when chan mode is AMR */ if((GET_STATE(STATE_ATT) EQ ATT_DEDICATED) AND (GET_STATE(STATE_DAT) EQ DAT_DEDICATED)) { if(rr_data->sc_data.ch_mode EQ CM_AMR) { /* AMR vocoder type */ em_amr_info_cnf->amr_vocoder = rr_data->sc_data.chan_desc.chan_type; /* Initial codec mode indicator */ em_amr_info_cnf->amr_icmi = rr_data->sc_data.amr_conf.icmi; /* Initial codec mode. Valid if icmi = 1(Start mode signalled) */ em_amr_info_cnf->amr_icm = rr_data->sc_data.amr_conf.st_mode; /* Active codec set */ em_amr_info_cnf->amr_acs = rr_data->sc_data.amr_conf.set_amr; /* First codec( Highest bit rate codec mode) */ em_amr_info_cnf->amr_first_codec = em_get_first_codec(rr_data->sc_data.amr_conf.set_amr); if(rr_data->sc_data.amr_conf.v_cod_prop) { /* Number of codec modes */ em_amr_info_cnf->amr_nr_modes = rr_data->sc_data.amr_conf.c_cod_prop + 1; /* Threshold and Hysteresis properties between codec modes */ for(i=0;i<rr_data->sc_data.amr_conf.c_cod_prop;i++) { memcpy(&em_amr_info_cnf->amr_cod_prop[i],&rr_data->sc_data.amr_conf.cod_prop[i], sizeof(T_amr_cod_prop)); } } else { /* Number of codec modes */ em_amr_info_cnf->amr_nr_modes = 1; } } /* CM_AMR */ } /* ATT DEDICATED */ PSENDX(MMI, em_amr_info_cnf); } /*dat_em_amr_info_req*/ /* +------------------------------------------------------------------------------ | Function : em_init_rr_event_trace +------------------------------------------------------------------------------ | Description : Initialize the event tracing flags for RR | | Parameters : void | | Return : void | +------------------------------------------------------------------------------ */ GLOBAL void em_init_rr_event_trace(void) { UBYTE i; TRACE_FUNCTION ("em_init_rr_event_trace()"); for (i=0; i< EM_MAX_RR_EVENTS; i++) rr_v[i] = 0; } /* +------------------------------------------------------------------------------ | Function : rr_em_rr_event_req +------------------------------------------------------------------------------ | Description : Set the event tracing flags according the bitmask | | Parameters : Primitive - Bitmask(T_EM_RR_EVENT_REQ) | | Return : void | +------------------------------------------------------------------------------ */ GLOBAL void rr_em_rr_event_req (T_EM_RR_EVENT_REQ *em_rr_event_req) { UBYTE i; TRACE_FUNCTION ("rr_em_rr_event_req()"); /* * The event tracing flags are set according the bitmask. rr_v[i] are * the flags belonging to the event number described in 8443.601 */ for(i=1; i<33; i++) rr_v[i] = ((em_rr_event_req->bitmask_rr_l & (0x01<<(i-1))) > 0) ? TRUE : FALSE; for(i=33; i<(EM_MAX_RR_EVENTS); i++) rr_v[i] = ((em_rr_event_req->bitmask_rr_h & (0x01<<(i-1))) > 0) ? TRUE : FALSE; /* A new event trace is generated therefor the flag is set to 0. */ em_rr_trace_occured = 0; PFREE(em_rr_event_req); } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_2 +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define EVT_LEN_OFFSET 2 /* Event Number and Length value bytes */ #define BUFFER_2_LENGTH 2 GLOBAL UBYTE em_write_buffer_2 (UBYTE event_no) { UBYTE em_rr_event_buffer[BUFFER_2_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_2()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write] = 0x00; /* Value length - 0 equals no data */ return (em_rr_sem (BUFFER_2_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_3 +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_3_LENGTH 3 GLOBAL UBYTE em_write_buffer_3 (UBYTE event_no, UBYTE value) { UBYTE em_rr_event_buffer[BUFFER_3_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_3()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_3_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write] = value; /* Data to be stored */ return (em_rr_sem (BUFFER_3_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_3a +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value (USHORT) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_3A_LENGTH 4 GLOBAL UBYTE em_write_buffer_3a (UBYTE event_no, USHORT value) { UBYTE em_rr_event_buffer[BUFFER_3A_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_3a()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_3A_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = (UBYTE)(value >> 8); /* Data to be stored - MSB first */ em_rr_event_buffer[em_rr_buffer_write++] = (UBYTE)(value ); /* LSB second */ return (em_rr_sem (BUFFER_3A_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_4 +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, length of data and value1 and value2 | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_4_LENGTH 4 GLOBAL UBYTE em_write_buffer_4 (UBYTE event_no, UBYTE value1, UBYTE value2) { UBYTE em_rr_event_buffer[BUFFER_4_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_4()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_4_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value1; /* Value 1 */ em_rr_event_buffer[em_rr_buffer_write++] = value2; /* Value 2 */ return (em_rr_sem (BUFFER_4_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_4a +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value, data cs (USHORT) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_4A_LENGTH 5 GLOBAL UBYTE em_write_buffer_4a (UBYTE event_no, UBYTE value, USHORT cs) { UBYTE em_rr_event_buffer[BUFFER_4A_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_4a()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_4A_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value; /* first data info */ em_rr_event_buffer[em_rr_buffer_write++] = (UBYTE)(cs >> 8); /* Data to be stored - MSB first */ em_rr_event_buffer[em_rr_buffer_write++] = (UBYTE)(cs); /* LSB second */ return (em_rr_sem (BUFFER_4A_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_4b +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value, data plmn (T_plmn) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_4B_LENGTH 9 GLOBAL UBYTE em_write_buffer_4b (UBYTE event_no, UBYTE value, T_plmn plmn) { UBYTE em_rr_event_buffer[BUFFER_4B_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_4b()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); memset(em_rr_event_buffer, 0, BUFFER_4B_LENGTH); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_4B_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value; if(plmn.v_plmn) { memcpy(&em_rr_event_buffer[em_rr_buffer_write], plmn.mcc, SIZE_MCC); em_rr_buffer_write += SIZE_MCC; memcpy(&em_rr_event_buffer[em_rr_buffer_write], plmn.mnc, SIZE_MNC); } return (em_rr_sem (BUFFER_4B_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_4c +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value1, data plmn (T_plmn) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_4C_LENGTH ((MAX_PLMN*(SIZE_MCC+SIZE_MNC))+EVT_LEN_OFFSET) GLOBAL UBYTE em_write_buffer_4c (UBYTE event_no, UBYTE value1, T_plmn plmn[MAX_PLMN]) { UBYTE em_rr_event_buffer[BUFFER_4C_LENGTH]; UBYTE em_rr_buffer_write = 0; UBYTE length = 0; UBYTE i; TRACE_FUNCTION ("rr_em_write_buffer_4c()"); /* Ensure value1 is within specified boundaries */ if( value1 > MAX_PLMN ) { value1 = MAX_PLMN; } /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); memset(em_rr_event_buffer, 0, BUFFER_4C_LENGTH); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = 1+value1*(SIZE_MCC + SIZE_MNC); /* Value length - 0 equals no value */ for (i=0; i<value1; i++) { if(plmn[i].v_plmn) { memcpy(em_rr_event_buffer + em_rr_buffer_write, plmn[i].mcc, SIZE_MCC); em_rr_buffer_write += SIZE_MCC; memcpy(em_rr_event_buffer + em_rr_buffer_write, plmn[i].mnc, SIZE_MNC); em_rr_buffer_write += SIZE_MNC; } } length = (EVT_LEN_OFFSET + value1*(SIZE_MCC + SIZE_MNC)); return (em_rr_sem (length, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_5 +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value1, data value2, data cs (USHORT) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_5_LENGTH 5 GLOBAL UBYTE em_write_buffer_5 (UBYTE event_no, UBYTE value1, UBYTE value2, UBYTE value3) { UBYTE em_rr_event_buffer[BUFFER_5_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_5()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_5_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value1; /* first data info */ em_rr_event_buffer[em_rr_buffer_write++] = value2; /* second data info */ em_rr_event_buffer[em_rr_buffer_write++] = value3; /* Data */ return (em_rr_sem (BUFFER_5_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_5c +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value, data plmn (T_plmn) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_5C_LENGTH 10 GLOBAL UBYTE em_write_buffer_5c (UBYTE event_no, UBYTE value1, UBYTE value2, T_plmn plmn) { UBYTE em_rr_event_buffer[BUFFER_5C_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_5c()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); memset(em_rr_event_buffer, 0, BUFFER_5C_LENGTH); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_5C_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value1; em_rr_event_buffer[em_rr_buffer_write++] = value2; if(plmn.v_plmn) { memcpy(em_rr_event_buffer + em_rr_buffer_write, plmn.mcc, SIZE_MCC); em_rr_buffer_write += SIZE_MCC; memcpy(em_rr_event_buffer + em_rr_buffer_write, plmn.mnc, SIZE_MNC); } return (em_rr_sem (BUFFER_5C_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_8 +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value1, data value2, data cs (USHORT) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_8_LENGTH 8 GLOBAL UBYTE em_write_buffer_8 (UBYTE event_no, UBYTE value1, UBYTE value2, UBYTE value3, UBYTE value4, UBYTE value5, UBYTE value6) { UBYTE em_rr_event_buffer[BUFFER_8_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_8()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_8_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value1; /* first data info */ em_rr_event_buffer[em_rr_buffer_write++] = value2; /* second data info */ em_rr_event_buffer[em_rr_buffer_write++] = value3; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value4; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value5; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value6; /* data */ return (em_rr_sem (BUFFER_8_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : em_write_buffer_9 +------------------------------------------------------------------------------ | Description : Perform buffer check and store corresponding data in it. | | Parameters : Event number, data value1, data value2, data cs (USHORT) | | Return : TRUE/FALSE | +------------------------------------------------------------------------------ */ #define BUFFER_9_LENGTH 9 GLOBAL UBYTE em_write_buffer_9 (UBYTE event_no, UBYTE value1, UBYTE value2, UBYTE value3, UBYTE value4, UBYTE value5, UBYTE value6, UBYTE value7) { UBYTE em_rr_event_buffer[BUFFER_9_LENGTH]; UBYTE em_rr_buffer_write = 0; TRACE_FUNCTION ("rr_em_write_buffer_9()"); /* ACI is informed about the first event trace, used for later data processing. */ rr_em_first_event_check(); em_rr_event_buffer[em_rr_buffer_write++] = event_no; /* Event number */ em_rr_event_buffer[em_rr_buffer_write++] = BUFFER_9_LENGTH-EVT_LEN_OFFSET; /* Value length - 0 equals no value */ em_rr_event_buffer[em_rr_buffer_write++] = value1; /* first data info */ em_rr_event_buffer[em_rr_buffer_write++] = value2; /* second data info */ em_rr_event_buffer[em_rr_buffer_write++] = value3; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value4; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value5; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value6; /* data */ em_rr_event_buffer[em_rr_buffer_write++] = value7; /* data */ return (em_rr_sem (BUFFER_9_LENGTH, em_rr_event_buffer)); /* Data is stored inside buffer, reset flag */ } /* +------------------------------------------------------------------------------ | Function : rr_semaphore_err +------------------------------------------------------------------------------ | Description : Semaphor error | | | Parameters : void | | Return : void | +------------------------------------------------------------------------------ */ static void rr_semaphore_err (void) { static UCHAR out = 0; if (!out) { out = 1; /* Implements Measure#32: Row 224 */ TRACE_EVENT ("semaphore error"); } } /* +------------------------------------------------------------------------------ | Function : rr_enter_critical_section +------------------------------------------------------------------------------ | Description : | Attempt to access critical section by taking control | of the semaphore | | Parameters : void | | Return : int | +------------------------------------------------------------------------------ */ static int rr_enter_critical_section (T_HANDLE sem) { if (vsi_s_get (VSI_CALLER sem) NEQ VSI_OK) { SYST_TRACE ( "** Enter Critical Sec:semaphore NOT cleared **"); rr_semaphore_err(); return -1; } else { return 0; } } /* +------------------------------------------------------------------------------ | Function : rr_leave_critical_section +------------------------------------------------------------------------------ | Description : | Relinquish control of semaphore and release access to | critical section | | Parameters : void | | Return : int | +------------------------------------------------------------------------------ */ static int rr_leave_critical_section (T_HANDLE sem) { if (vsi_s_release (VSI_CALLER sem) NEQ VSI_OK) { SYST_TRACE ( "** Leave Critical Sec:semaphore NOT cleared **"); rr_semaphore_err(); return -1; } else { return 0; } } /* +------------------------------------------------------------------------------ | Function : em_rr_sem_init +------------------------------------------------------------------------------ | Description : | Initialise Semaphore | | Parameters : void | | Return : int | +------------------------------------------------------------------------------ */ GLOBAL void em_rr_sem_init (void) { sem_EM_RR = vsi_s_open (VSI_CALLER "EM_RR_SEM",1); if (sem_EM_RR NEQ VSI_ERROR) em_rr_sem_clear (); else SYST_TRACE ("RR:can´t open semaphore \"EM_RR_SEM\""); } /* +------------------------------------------------------------------------------ | Function : em_rr_sem_exit +------------------------------------------------------------------------------ | Description : | Close the semaphore | | Parameters : void | | Return : void | +------------------------------------------------------------------------------ */ GLOBAL void em_rr_sem_exit (void) { if (sem_EM_RR NEQ VSI_ERROR) vsi_s_close (VSI_CALLER sem_EM_RR); } /* +------------------------------------------------------------------------------ | Function : em_rr_sem_clear +------------------------------------------------------------------------------ | Description : | Clear semaphore | | Parameters : void | | Return : void | +------------------------------------------------------------------------------ */ LOCAL void em_rr_sem_clear (void) { if (rr_enter_critical_section(sem_EM_RR)) { return; } em_rr_sem_index = 0; if(rr_leave_critical_section(sem_EM_RR)) { return; } SYST_TRACE ( "RR:em_rr_sem_index cleared"); } /* +------------------------------------------------------------------------------ | Function : em_rr_sem_reset +------------------------------------------------------------------------------ | Description : | Reset the semaphore | | Parameters : void | | Return : UBYTE | +------------------------------------------------------------------------------ */ /*lint -esym(714,em_rr_sem_reset) | Symbol not referenced | used by ACI */ /*lint -esym(765,em_rr_sem_reset) | external could be made static | used by ACI */ GLOBAL void em_rr_sem_reset (void) { em_rr_sem_index = 0; if(rr_leave_critical_section(sem_EM_RR)) { return; } SYST_TRACE ( "RR:em_rr_sem_index reset OK"); } /* +------------------------------------------------------------------------------ | Function : em_rr_sem_read +------------------------------------------------------------------------------ | Description : | Read state of the semaphore. The rr semaphor will be read by | the engineering mode via aci. | | Parameters : void | | Return : UBYTE | +------------------------------------------------------------------------------ */ /*lint -esym(714,em_rr_sem_read) | Symbol not referenced | used by ACI */ /*lint -esym(765,em_rr_sem_read) | external could be made static | used by ACI */ GLOBAL void em_rr_sem_read (void) { TRACE_FUNCTION ("em_rr_sem_read()"); { USHORT semCount; if (vsi_s_status (VSI_CALLER sem_EM_RR, &semCount) NEQ VSI_OK) { SYST_TRACE ( "** RR:sem status error **"); rr_semaphore_err(); return; } if (semCount EQ 0) { vsi_o_ttrace(VSI_CALLER TC_EVENT, "semCount = %d", semCount); SYST_TRACE ( "semCount EQ 0"); return; } } rr_enter_critical_section(sem_EM_RR); } /* +------------------------------------------------------------------------------ | Function : em_rr_sem +------------------------------------------------------------------------------ | Description : | | | Parameters : void | | Return : TRUE/FALSE - TRUE keeps the event flag valid, | FALSE indicates a successful flag handle | +------------------------------------------------------------------------------ */ /*lint -esym(714,em_rr_sem) | Symbol not referenced | used by ACI */ /*lint -esym(765,em_rr_sem) | external could be made static | used by ACI */ GLOBAL UBYTE em_rr_sem (UBYTE length, UBYTE *data) { UBYTE i; TRACE_FUNCTION ("em_rr_sem()"); { USHORT semCount; if (vsi_s_status (VSI_CALLER sem_EM_RR, &semCount) NEQ VSI_OK) { rr_semaphore_err(); return FALSE; } if (semCount EQ 0) { vsi_o_ttrace(VSI_CALLER TC_EVENT, "semCount = %d", semCount); SYST_TRACE ( "semCount EQ 0"); return FALSE; } } /* * buffer overflow protection */ if (( em_rr_sem_index + length) > EM_RR_SEM_SIZE ) { TRACE_FUNCTION ("rr buffer overflow"); return FALSE; } if(rr_enter_critical_section(sem_EM_RR)) return FALSE; for (i=0; i<length; i++) em_rr_sem_buffer[em_rr_sem_index++] = *(data++); if(rr_leave_critical_section(sem_EM_RR)) { SYST_TRACE ( "** Unable to clear semaphore **"); return FALSE; } return TRUE; /* indicates that flag was handled */ } /* endfunc em_rr_sem */ /* +------------------------------------------------------------------------------ | Function : rr_em_first_event_check() +------------------------------------------------------------------------------ | Description : Checks if first EM-Event ocured | | Parameters : None | | Return : None | +------------------------------------------------------------------------------ */ /* ACI is informed about the first event trace, used for later data processing. */ LOCAL void rr_em_first_event_check(void) { TRACE_FUNCTION("rr_em_first_event_check()"); if(em_rr_trace_occured EQ 0) { PALLOC(em_notification, EM_DATA_IND); em_notification->entity = EM_RR; PSENDX(MMI, em_notification); em_rr_trace_occured++; } } /* +------------------------------------------------------------------------------ | Function : rr_em_pco_trace_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_PCO_TRACE_REQ. | | Parameters : UBYTE pco_bitmap | | Return : void | | Purpose : with this primitive the requested EM Data is traced in the PCO. +------------------------------------------------------------------------------ */ GLOBAL void rr_em_pco_trace_req (T_EM_PCO_TRACE_REQ *em_pco_trace_req) { GET_INSTANCE_DATA; UBYTE em_cell_type = EM_CELL_NA; TRACE_FUNCTION("rr_em_pco_trace_req()"); /*check for SC data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_SC_INFO) { switch (GET_STATE (STATE_ATT)) { case ATT_IDLE: if (rr_data->nc_data[SC_INDEX].bcch_status EQ DECODED) { em_cell_type = EM_CELL_GSM; #ifdef GPRS if(rr_data->nc_data[SC_INDEX].rac NEQ NOT_PRESENT_8BIT) em_cell_type = EM_CELL_GPRS; #endif TRACE_EVENT_EM_P8("EM_SC_INFO_REQ_IDLE_DECODED: arfcn:%d c1:%d c2:%d rxlev:%d bsic:%d cell_id:%d dsc:%d cell_type:%d", rr_data->nc_data[SC_INDEX].arfcn, rr_data->nc_data[SC_INDEX].c1, rr_data->nc_data[SC_INDEX].c2, rr_data->nc_data[SC_INDEX].rxlev, rr_data->nc_data[SC_INDEX].bsic, rr_data->nc_data[SC_INDEX].cell_id, em_act_dlt, em_cell_type); TRACE_EVENT_EM_P5("EM_SC_INFO_REQ_IDLE_DECODED: txlev:%d tn:%d lac:%d cba:%d cbq:%d", rr_data->sc_data.cd.cell_options.pow_ctrl, rr_data->sc_data.chan_desc.tn, rr_data->nc_data[SC_INDEX].lai.lac, rr_data->nc_data[SC_INDEX].rach.cell_bar_access, rr_data->nc_data[SC_INDEX].c2_par.cbq); } else if (rr_data->nc_data[SC_INDEX].bcch_status EQ NON_DECODED) { TRACE_EVENT_EM_P4("EM_SC_INFO_REQ_IDLE_NON_DECODED: cell_type:%d arfcn:%d rxlev:%d bsic:%d", em_cell_type, rr_data->nc_data[SC_INDEX].arfcn, rr_data->nc_data[SC_INDEX].rxlev, rr_data->nc_data[SC_INDEX].bsic); } break; case ATT_DEDICATED: if (!rr_data->ms_data.measurement_report.valid) break; em_cell_type = EM_CELL_GSM; #ifdef GPRS if(rr_data->nc_data[SC_INDEX].rac NEQ NOT_PRESENT_8BIT) em_cell_type = EM_CELL_GPRS; #endif TRACE_EVENT_EM_P1("EM_SC_INFO_REQ_DEDICATED: cell_type:%d", em_cell_type); TRACE_EVENT_EM_P6("EM_SC_INFO_REQ_DEDICATED: arfcn:%d bsic:%d cell_id:%d txlev:%d tn:%d rxlev_f:%d", rr_data->ms_data.measurement_report.arfcn, rr_data->nc_data[SC_INDEX].bsic, rr_data->nc_data[SC_INDEX].cell_id, rr_data->sc_data.cd.cell_options.pow_ctrl, rr_data->sc_data.chan_desc.tn, rr_data->ms_data.measurement_report.rx_lev_full); TRACE_EVENT_EM_P6("EM_SC_INFO_REQ_DEDICATED: rxlev_s:%d rlt:%d ta:%d rxqual_f:%d rxqual_s:%d vocoder:%d", rr_data->ms_data.measurement_report.rx_lev_sub, em_act_rlt, rr_data->sc_data.new_ta, rr_data->ms_data.measurement_report.rx_qual_full, rr_data->ms_data.measurement_report.rx_qual_sub, rr_data->sc_data.ch_mode); break; default: break; }/*switch - state*/ }/*if - SC data*/ /*check NC data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_NC_INFO) { UBYTE index = 0; UBYTE rac = 0xff; switch (GET_STATE (STATE_ATT)) { case ATT_IDLE: TRACE_EVENT_EM_P1("EM_NC_INFO_REQ_IDLE: num_nc:%d", /*number of neighbour cells*/ rr_data->ms_data.measurement_report.ncells.no_of_ncells); for (index = 0; index < EM_MAX_NUM_NC ; index++) /*report cells ordered by index in NC list*/ { em_cell_type = EM_CELL_NA; if (rr_data->nc_data[index].bcch_status EQ DECODED) { em_cell_type = EM_CELL_GSM; rac = 0xff; #ifdef GPRS rac = rr_data->nc_data[index].rac; if(rr_data->nc_data[index].rac NEQ NOT_PRESENT_8BIT) em_cell_type = EM_CELL_GPRS; #endif TRACE_EVENT_EM_P8("EM_NC_INFO_REQ_IDLE_DECODED: cell_type:%d rac:%d index:%d arfcn:%d c1:%d c2:%d rxlev:%d bsic:%d", em_cell_type, rac, index, rr_data->nc_data[index].arfcn, rr_data->nc_data[index].c1, rr_data->nc_data[index].c2, rr_data->nc_data[index].rxlev, rr_data->nc_data[index].bsic); TRACE_EVENT_EM_P6("EM_NC_INFO_REQ_IDLE_DECODED: cid:%d lac:%d f_o:%ld t_a:%ld cba:%d cbq:%d", rr_data->nc_data[index].cell_id, rr_data->nc_data[index].lai.lac, rr_data->ms_data.measurement_report.ncells.frame_offset[index], rr_data->ms_data.measurement_report.ncells.time_alignmt[index], rr_data->nc_data[index].rach.cell_bar_access, rr_data->nc_data[index].c2_par.cbq); TRACE_EVENT_EM_P3("EM_NC_INFO_REQ_IDLE_DECODED: cell_resel_off:%d temp_off:%d rxlev_acc_min:%ld", rr_data->nc_data[index].c2_par.cell_reselect_offset, rr_data->nc_data[index].c2_par.temp_offset, rr_data->nc_data[index].select_para.rxlev_access_min); } /* if decoded */ else if (rr_data->nc_data[index].bcch_status EQ NON_DECODED) { TRACE_EVENT_EM_P4("EM_NC_INFO_REQ_IDLE_NON_DECODED: cell_type:%d arfcn:%d rxlev:%d bsic:%d", em_cell_type, rr_data->nc_data[index].arfcn, rr_data->nc_data[index].rxlev, rr_data->nc_data[index].bsic); } /* if non decoded */ } /* for */ break; case ATT_DEDICATED: { if (!rr_data->ms_data.measurement_report.valid) break; TRACE_EVENT_EM_P1("EM_NC_INFO_REQ_DEDICATED: num_nc:%d", rr_data->ms_data.measurement_report.ncells.no_of_ncells); for (index = 0; index< rr_data->ms_data.measurement_report.ncells.no_of_ncells; index++) { /*in the measurement report the cells are ordered by fieldstrength - non valid measurements are at the end*/ TRACE_EVENT_EM_P6("EM_NC_INFO_REQ_DEDICATED: index:%d arfcn:%d rx_lev:%d bsic:%d f_o:%ld t_a:%ld", index, rr_data->ms_data.measurement_report.ncells.arfcn[index], rr_data->ms_data.measurement_report.ncells.rx_lev[index], rr_data->ms_data.measurement_report.ncells.bsic[index], rr_data->ms_data.measurement_report.ncells.frame_offset[index], rr_data->ms_data.measurement_report.ncells.time_alignmt[index]); }/*for*/ }/*case*/ break; default: break; }/*switch - state*/ }/*if - NC data*/ /*check Location and Paging data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_LOC_PAG_INFO) { if (rr_data->nc_data[SC_INDEX].bcch_status EQ DECODED) { TRACE_EVENT_EM_P8("EM_LOC_PAG_INFO_REQ_DECODED: mcc:%d %d %d mnc:%d %d %d bs_pa_mfrms:%d t3212:%d", rr_data->nc_data[SC_INDEX].lai.mcc[0], rr_data->nc_data[SC_INDEX].lai.mcc[1], rr_data->nc_data[SC_INDEX].lai.mcc[2], /*2 digits vs. 3 digits*/ rr_data->nc_data[SC_INDEX].lai.mnc[2] NEQ 0xF ? rr_data->nc_data[SC_INDEX].lai.mnc[0] : 0 , rr_data->nc_data[SC_INDEX].lai.mnc[2] NEQ 0xF ? rr_data->nc_data[SC_INDEX].lai.mnc[1] : rr_data->nc_data[SC_INDEX].lai.mnc[0], rr_data->nc_data[SC_INDEX].lai.mnc[2] NEQ 0xF ? rr_data->nc_data[SC_INDEX].lai.mnc[2] : rr_data->nc_data[SC_INDEX].lai.mnc[1], rr_data->nc_data[SC_INDEX].control_descr.bs_pa_mfrms, rr_data->nc_data[SC_INDEX].control_descr.t3212); } if (rr_data->ms_data.tmsi_available EQ TRUE) TRACE_EVENT_EM_P1("EM_LOC_PAG_INFO_REQ_TMSI: %d", rr_data->ms_data.tmsi_binary); }/*if - Location and Paging data*/ /*check PLMN parameters*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_PLMN_INFO) { TRACE_EVENT_EM_P4("EM_PLMN_INFO_REQ: no_creq_max:%d re_flag:%d TXPOW_max:%d RXLEV_acc_min:%d", rr_data->nc_data[SC_INDEX].rach.max_retrans, rr_data->nc_data[SC_INDEX].rach.re, rr_data->nc_data[SC_INDEX].select_para.ms_txpwr_max_cch, rr_data->nc_data[SC_INDEX].select_para.rxlev_access_min); }/* if - PLMN parameters*/ /*check Ciphering Hopping DTX data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_CIPH_HOP_DTX_INFO) { UBYTE i,offset; /* Implements Measure#32: Row 242 */ char *basestr="EM_CIP_HOP_DTX_INFO_REQ_FREQ"; /*to store the trace output*/ char hop_freq_list[MAX_SPRINTF_STRING_LEN]; /*lint !e813 , info about length*/ if((GET_STATE(STATE_ATT) EQ ATT_DEDICATED) AND (GET_STATE(STATE_DAT) EQ DAT_DEDICATED)) { TRACE_EVENT_EM_P6("EM_CIP_HOP_DTX_INFO_REQ_DEDICATED: ciph:%d dtx:%d v_start:%d hop:%d hsn:%d arfcn:%d", rr_data->sc_data.ciph_on, rr_data->sc_data.cd.dtx, v_start, rr_data->sc_data.chan_desc.hop, rr_data->sc_data.chan_desc.hop NEQ H_NO ? rr_data->sc_data.chan_desc.hsn : NOT_PRESENT_16BIT, rr_data->sc_data.chan_desc.arfcn); if(rr_data->sc_data.chan_desc.hop NEQ H_NO) { /* Implements Measure#32: Row 242 */ offset = sprintf(hop_freq_list, "%s1: ", basestr); for (i = 0; (i < MAX_MA_CHANNELS) AND (ma[i] NEQ NOT_PRESENT_16BIT); i++) { offset += sprintf(hop_freq_list+offset, "%u ", ma[i]); /* * 4 spaces for freq + 1 blank space + 1 space for '\0' */ if(offset > MAX_SPRINTF_STRING_LEN - 6) { TRACE_EVENT_EM (hop_freq_list); /* Implements Measure#32: Row 245 */ offset = sprintf(hop_freq_list, "%s1_CONT: ", basestr); } } TRACE_EVENT_EM (hop_freq_list); TRACE_EVENT_EM_P2("EM_CIP_HOP_DTX_INFO_REQ_FREQ1: nr_arfcns:%d, maio:%d", i,rr_data->sc_data.chan_desc.maio); } /* If hopping valid */ if (v_start) { /* Implements Measure#32: Row 247 */ offset = sprintf(hop_freq_list, "%s2: ", basestr);/*before starting time*/ for (i = 0; (i < MAX_MA_CHANNELS) AND (ma2[i] NEQ NOT_PRESENT_16BIT); i++) { offset += sprintf(hop_freq_list+offset, "%u ", ma2[i]); if(offset > MAX_SPRINTF_STRING_LEN - 6) { TRACE_EVENT_EM (hop_freq_list); /* Implements Measure#32: Row 248 */ offset = sprintf(hop_freq_list, "%s2_CONT: ", basestr); } } TRACE_EVENT_EM (hop_freq_list); TRACE_EVENT_EM_P2("EM_CIP_HOP_DTX_INFO_REQ_FREQ2: nr_arfcns:%d, maio:%d",i, maio2); }/*if - starting time valid*/ } /* ATT dedicated state */ else { TRACE_EVENT_EM_P1("EM_CIP_HOP_DTX_INFO_REQ_IDLE: dtx:%d", rr_data->sc_data.cd.dtx); } /* ATT idle state */ }/*if - ciphering, hopping, dtx*/ /*check Power (Classmark) data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_POWER_INFO) {/*here the em_power_info_cnf struckture is used, because I couldn't find classmark definition*/ PALLOC(em_power_info_cnf, EM_POWER_INFO_CNF); memset (em_power_info_cnf, 0, sizeof (T_EM_POWER_INFO_CNF)); memcpy(&em_power_info_cnf->classm2, &rr_data->ms_data.classmark2, sizeof (T_classm2)); memcpy(&em_power_info_cnf->classm3, &rr_data->ms_data.classmark3, sizeof (T_classm3)); TRACE_EVENT_EM_P6("EM_POWER_INFO_REQ_CLASSMARK_2: rev_lev:%d es_ind:%d a5_1:%d rf_pow_cap:%d ps_cap:%d ss_screen:%d", em_power_info_cnf->classm2.rev_lev, em_power_info_cnf->classm2.es_ind, em_power_info_cnf->classm2.a5_1, em_power_info_cnf->classm2.rf_pow_cap, em_power_info_cnf->classm2.ps_cap, em_power_info_cnf->classm2.ss_screen); TRACE_EVENT_EM_P6("EM_POWER_INFO_REQ_CLASSMARK_2: sm_cap:%d freq_cap:%d class_3:%d cmsp:%d a5_3:%d a5_2:%d", em_power_info_cnf->classm2.sm_cap, em_power_info_cnf->classm2.freq_cap, em_power_info_cnf->classm2.class_3, em_power_info_cnf->classm2.cmsp, em_power_info_cnf->classm2.a5_3, em_power_info_cnf->classm2.a5_2); TRACE_EVENT_EM_P6("EM_POWER_INFO_REQ_CLASSMARK_3: mb_sub:%d a5_7:%d a5_6:%d a5_5:%d a5_4:%d v_radio_cap_2:%d", em_power_info_cnf->classm3.mb_sub, em_power_info_cnf->classm3.a5_7, em_power_info_cnf->classm3.a5_6, em_power_info_cnf->classm3.a5_5, em_power_info_cnf->classm3.a5_4, em_power_info_cnf->classm3.v_radio_cap_2); TRACE_EVENT_EM_P6("EM_POWER_INFO_REQ_CLASSMARK_3: ra_cap_2:%d v_ra_cap_1:%d ra_cap_1:%d v_r_sup:%d r_sup:%d v_m_s_class:%d", em_power_info_cnf->classm3.radio_cap_2, em_power_info_cnf->classm3.v_radio_cap_1, em_power_info_cnf->classm3.radio_cap_1, em_power_info_cnf->classm3.v_r_support, em_power_info_cnf->classm3.r_support, em_power_info_cnf->classm3.v_m_s_class); TRACE_EVENT_EM_P6("EM_POWER_INFO_REQ_CLASSMARK_3: m_s_class:%d ucs2_treat:%d ext_meas_cap:%d v_meas_cap:%d sw_time:%d sws_time:%d", em_power_info_cnf->classm3.m_s_class, em_power_info_cnf->classm3.ucs2_treat, em_power_info_cnf->classm3.ext_meas_cap, em_power_info_cnf->classm3.v_meas_cap, em_power_info_cnf->classm3.meas_cap.sw_time, em_power_info_cnf->classm3.meas_cap.sws_time); PFREE(em_power_info_cnf); }/* if - Power (Classmark) data*/ /*check Identity data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_IDENTITY_INFO) { TRACE_EVENT_EM_P4("EM_IDENTITY_INFO_REQ_IMEI: id_type:%d v_id:%d c_id:%d odd_even:%d", rr_data->ms_data.imei.ident_type, rr_data->ms_data.imei.v_ident_dig, rr_data->ms_data.imei.c_ident_dig, rr_data->ms_data.imei.odd_even); TRACE_EVENT_EM_P8("EM_IDENTITY_INFO_REQ: imei_1: %d %d %d %d %d %d %d %d", rr_data->ms_data.imei.ident_dig[0], rr_data->ms_data.imei.ident_dig[1], rr_data->ms_data.imei.ident_dig[2], rr_data->ms_data.imei.ident_dig[3], rr_data->ms_data.imei.ident_dig[4], rr_data->ms_data.imei.ident_dig[5], rr_data->ms_data.imei.ident_dig[6], rr_data->ms_data.imei.ident_dig[7]); TRACE_EVENT_EM_P8("EM_IDENTITY_INFO_REQ: imei_2: %d %d %d %d %d %d %d %d", rr_data->ms_data.imei.ident_dig[8], rr_data->ms_data.imei.ident_dig[9], rr_data->ms_data.imei.ident_dig[10], rr_data->ms_data.imei.ident_dig[11], rr_data->ms_data.imei.ident_dig[12], rr_data->ms_data.imei.ident_dig[13], rr_data->ms_data.imei.ident_dig[14], rr_data->ms_data.imei.ident_dig[15]); if (rr_data->ms_data.imsi_available) /* SIM available */ { TRACE_EVENT_EM_P4("EM_IDENTITY_INFO_REQ_IMSI: id_type:%d v_id:%d c_id:%d odd_even:%d", rr_data->ms_data.imsi.ident_type, rr_data->ms_data.imsi.v_ident_dig, rr_data->ms_data.imsi.c_ident_dig, rr_data->ms_data.imsi.odd_even); TRACE_EVENT_EM_P8("EM_IDENTITY_INFO_REQ: imsi_1: %d %d %d %d %d %d %d %d", rr_data->ms_data.imsi.ident_dig[0], rr_data->ms_data.imsi.ident_dig[1], rr_data->ms_data.imsi.ident_dig[2], rr_data->ms_data.imsi.ident_dig[3], rr_data->ms_data.imsi.ident_dig[4], rr_data->ms_data.imsi.ident_dig[5], rr_data->ms_data.imsi.ident_dig[6], rr_data->ms_data.imsi.ident_dig[7]); TRACE_EVENT_EM_P8("EM_IDENTITY_INFO_REQ: imsi_2: %d %d %d %d %d %d %d %d", rr_data->ms_data.imsi.ident_dig[8], rr_data->ms_data.imsi.ident_dig[9], rr_data->ms_data.imsi.ident_dig[10], rr_data->ms_data.imsi.ident_dig[11], rr_data->ms_data.imsi.ident_dig[12], rr_data->ms_data.imsi.ident_dig[13], rr_data->ms_data.imsi.ident_dig[14], rr_data->ms_data.imsi.ident_dig[15]); }/*if - SIM available*/ if (rr_data->ms_data.tmsi_available EQ TRUE) TRACE_EVENT_EM_P1("EM_IDENTITY_INFO_REQ: tmsi_bin: %ld", rr_data->ms_data.tmsi_binary); }/*if - Identity data*/ /*check AMR configuration data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_AMR_INFO) { if((GET_STATE(STATE_ATT) EQ ATT_DEDICATED) AND (GET_STATE(STATE_DAT) EQ DAT_DEDICATED)) { if(rr_data->sc_data.ch_mode EQ CM_AMR) { UBYTE amr_index,amr_nr_modes = 1; TRACE_EVENT_EM_P5("EM_AMR_INFO_REQ_DEDICATED: vocoder:%d icmi:%d icm:%d acs:%d first_codec:%d", rr_data->sc_data.chan_desc.chan_type, rr_data->sc_data.amr_conf.icmi, rr_data->sc_data.amr_conf.st_mode, rr_data->sc_data.amr_conf.set_amr, em_get_first_codec(rr_data->sc_data.amr_conf.set_amr)); if(rr_data->sc_data.amr_conf.v_cod_prop) { /* Number of codec modes */ amr_nr_modes = rr_data->sc_data.amr_conf.c_cod_prop + 1; TRACE_EVENT_EM_P1("EM_AMR_INFO_REQ_DEDICATED: amr_num_modes:%d", amr_nr_modes); /* Threshold and Hysteresis properties between codec modes */ for(amr_index=0;amr_index<amr_nr_modes;amr_index++) { TRACE_EVENT_EM_P2("EM_AMR_COD_PROP: thr:%d hyst:%d", rr_data->sc_data.amr_conf.cod_prop[amr_index].codec_thr, rr_data->sc_data.amr_conf.cod_prop[amr_index].codec_hyst); } } /* codec properties */ } /* AMR configured */ else { TRACE_EVENT_EM("EM_AMR_INFO_REQ_DEDICATED: AMR not configured"); } /* AMR not configured in dedicated state */ } /* ATT dedicated state */ else { TRACE_EVENT_EM("EM_AMR_INFO_REQ_IDLE: Not Applicable"); } /* ATT idle state */ } /* EM_PCO_AMR_INFO */ #if !defined (WIN32) /*check SW Version data*/ if(em_pco_trace_req->pco_bitmap & EM_PCO_SW_VERSION_INFO) { TRACE_EVENT_EM_P1("EM_SW_SIM: %s",sim_version()); TRACE_EVENT_EM_P1("EM_SW_SMS: %s",sms_version()); TRACE_EVENT_EM_P1("EM_SW_SS: %s",ss_version()) ; TRACE_EVENT_EM_P1("EM_SW_CC: %s",cc_version()) ; TRACE_EVENT_EM_P1("EM_SW_MM: %s",mm_version()) ; TRACE_EVENT_EM_P1("EM_SW_RR: %s",rr_version()) ; TRACE_EVENT_EM_P1("EM_SW_DL: %s",dl_version()) ; TRACE_EVENT_EM_P1("EM_SW_L1: %s",l1_version()) ; }/*if - SW Version data*/ #endif PFREE(em_pco_trace_req); }/*rr_em_pco_trace_req*/ /* ------------------ Microtec Cooperation Functions ----------*/ #ifdef GPRS /* changes for later: Include extra compile switch for fmm */ /* +------------------------------------------------------------------------------ | Function : dat_em_fmm_sc_info_req +------------------------------------------------------------------------------ | Description : This function provides the data for microtec fmm - Program | | Parameters : Primitive from EM - T_EM_FMM_SC_INFO_REQ | | Return : void +------------------------------------------------------------------------------ This function sends the latest stored data of the SC. It is only interesting during a GPRS connection (PTM). Therefor the ATT_STATE is ATT_IDLE (or RE_SELECTION). */ GLOBAL void dat_em_fmm_sc_info_req (T_EM_FMM_SC_INFO_REQ *em_fmm_sc_info_req) { /*GET_INSTANCE_DATA;*/ PFREE(em_fmm_sc_info_req); TRACE_FUNCTION ("dat_fmm_em_sc_info_req()"); #ifdef FF_WAP { PALLOC(em_fmm_sc_info_cnf, EM_FMM_SC_INFO_CNF); memset (em_fmm_sc_info_cnf, 0, sizeof (T_EM_FMM_SC_INFO_CNF)); switch (GET_STATE (STATE_ATT)) { case ATT_IDLE: if (rr_data->nc_data[SC_INDEX].bcch_status EQ DECODED) { em_fmm_sc_info_cnf->arfcn = rr_data->nc_data[SC_INDEX].arfcn; em_fmm_sc_info_cnf->c1 = rr_data->nc_data[SC_INDEX].c1; em_fmm_sc_info_cnf->c2 = rr_data->nc_data[SC_INDEX].c2; em_fmm_sc_info_cnf->rac = rr_data->nc_data[SC_INDEX].rac; em_fmm_sc_info_cnf->hyst = rr_data->nc_data[SC_INDEX].select_para.cell_resel_hyst; em_fmm_sc_info_cnf->c32 = rr_data->nc_data[SC_INDEX].c32; /*c32_used abfragen ?*/ em_fmm_sc_info_cnf->gprs_prio_class = rr_data->nc_data[SC_INDEX].cr_par.priority_class; } else if (rr_data->nc_data[SC_INDEX].bcch_status EQ NON_DECODED) { em_fmm_sc_info_cnf->arfcn = rr_data->nc_data[SC_INDEX].arfcn; } break; case ATT_CS3: break; /* Cell reselection - if needed can be included later*/ default: break; } /*switch*/ /* TRACE_EVENT_P7("arfcn:%d c1:%d c2:%d rac:%d hyst:%d c32:%d prio:%d" , em_fmm_sc_info_cnf->arfcn,\ em_fmm_sc_info_cnf->c1 , em_fmm_sc_info_cnf->c2 , em_fmm_sc_info_cnf->rac , em_fmm_sc_info_cnf->hyst,\ em_fmm_sc_info_cnf->c32, em_fmm_sc_info_cnf->gprs_prio_class);*/ PSENDX( WAP, em_fmm_sc_info_cnf); } #endif /*FF_WAP*/ } /* +------------------------------------------------------------------------------ | Function : dat_em_fmm_nc_info_req +------------------------------------------------------------------------------ | Description : Process the primitive EM_FMM_NC_INFO_REQ. | | Parameters : Primitive from EM - T_EM_FMM_NC_INFO_REQ | | Return : void +------------------------------------------------------------------------------ This function sends the latest stored data of the NC. It is only interesting during a GPRS connection (PTM). Therefor the ATT_STATE is ATT_IDLE or RE_SELECTION. So the measurement report results should also be available in the nc_data. */ GLOBAL void dat_em_fmm_nc_info_req (T_EM_FMM_NC_INFO_REQ *em_fmm_nc_info_req) { /*GET_INSTANCE_DATA;*/ PFREE(em_fmm_nc_info_req); TRACE_FUNCTION ("dat_em_fmm_nc_info_req()"); #ifdef FF_WAP { UBYTE index = 0, index2 = 0; PALLOC(em_fmm_nc_info_cnf, EM_FMM_NC_INFO_CNF); memset (em_fmm_nc_info_cnf, 0, sizeof (T_EM_FMM_NC_INFO_CNF)); switch (GET_STATE (STATE_ATT)) { case ATT_IDLE: em_fmm_nc_info_cnf->no_ncells = rr_data->ms_data.measurement_report.ncells.no_of_ncells; for (index = index2 = 0; index< EM_MAX_NUM_NC; index++) { if (rr_data->nc_data[index].bcch_status EQ DECODED) { em_fmm_nc_info_cnf->arfcn_nc[index2] = rr_data->nc_data[index].arfcn; em_fmm_nc_info_cnf->c2_nc[index2] = rr_data->nc_data[index].c2; em_fmm_nc_info_cnf->rac_nc[index2] = rr_data->nc_data[index].rac; em_fmm_nc_info_cnf->c31_nc[index2] = rr_data->nc_data[index].c31; em_fmm_nc_info_cnf->c32_nc[index2] = rr_data->nc_data[index].c32; em_fmm_nc_info_cnf->gprs_prio_class_nc[index2] = rr_data->nc_data[index].cr_par.priority_class; index2++; } /* if decoded */ else if (rr_data->nc_data[index].bcch_status EQ NON_DECODED) { em_fmm_nc_info_cnf->arfcn_nc[index] = rr_data->nc_data[index].arfcn; } /* if non decoded */ } /* for */ break; default: break; }/*switch*/ /* for (index = 0 ; index < EM_MAX_NUM_NC ; index++) TRACE_EVENT_P6("arfcn:%d c2:%d rac:%d c31:%d c32:%d prio:%d", em_fmm_nc_info_cnf->arfcn_nc[index],\ em_fmm_nc_info_cnf->c2_nc[index], em_fmm_nc_info_cnf->rac_nc[index],\ em_fmm_nc_info_cnf->c31_nc[index], em_fmm_nc_info_cnf->c32_nc[index],\ em_fmm_nc_info_cnf->gprs_prio_class_nc[index]);*/ PSENDX( WAP, em_fmm_nc_info_cnf); } #endif /*FF_WAP*/ } /* +------------------------------------------------------------------------------ | Function : dat_em_fmm_reselection_start_ind +------------------------------------------------------------------------------ | Description : Indicates the start of an cell reselection to FMM | | Parameters : void | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_fmm_reselection_start_ind (void) { /*GET_INSTANCE_DATA;*/ TRACE_FUNCTION("dat_em_fmm_reselection_start_ind()"); #ifdef FF_WAP { PALLOC(em_fmm_reselection_start_ind, EM_FMM_RESELECTION_START_IND); memset (em_fmm_reselection_start_ind, 0, sizeof (T_EM_FMM_RESELECTION_START_IND)); em_fmm_reselection_start_ind->arfcn = rr_data->nc_data[rr_data->reselect_index].arfcn; em_fmm_reselection_start_ind->rac = rr_data->nc_data[rr_data->reselect_index].rac; em_fmm_reselection_start_ind->res_type = rr_data->sc_data.selection_type; /* TRACE_EVENT_P3("em_fmm_reselection_start_ind %d,%d,%d",em_fmm_reselection_start_ind->arfcn, em_fmm_reselection_start_ind->rac,em_fmm_reselection_start_ind->res_type );*/ PSENDX(WAP, em_fmm_reselection_start_ind); } #endif /*FF_WAP */ } /* +------------------------------------------------------------------------------ | Function : dat_em_fmm_reselection_end_ind +------------------------------------------------------------------------------ | Description : Indicates the end of an cell reselection to FMM | | Parameters : void | | Return : void +------------------------------------------------------------------------------ */ GLOBAL void dat_em_fmm_reselection_end_ind (void) { /*GET_INSTANCE_DATA;*/ TRACE_FUNCTION("dat_em_fmm_reselection_end_ind()"); #ifdef FF_WAP { PALLOC(em_fmm_resel_end_ind, EM_FMM_RESELECTION_END_IND); memset (em_fmm_resel_end_ind, 0, sizeof (T_EM_FMM_RESELECTION_END_IND)); em_fmm_resel_end_ind->arfcn = rr_data->nc_data[SC_INDEX].arfcn; em_fmm_resel_end_ind->rac = rr_data->nc_data[SC_INDEX].rac; /* TRACE_EVENT_P2("em_fmm_reselection_end_ind %d,%d",em_fmm_resel_end_ind->arfcn, em_fmm_resel_end_ind->rac);*/ PSENDX(WAP, em_fmm_resel_end_ind); } #endif /*FF_WAP*/ } #endif /* GPRS */ #endif /* FF_EM_MODE */ #endif /* RR_EM_C */