diff src/g23m-gsm/rr/rr_csf.c @ 1:d393cd9bb723

src/g23m-*: initial import from Magnetite
author Mychaela Falconia <falcon@freecalypso.org>
date Sun, 15 Jul 2018 04:40:46 +0000
parents
children
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--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/src/g23m-gsm/rr/rr_csf.c	Sun Jul 15 04:40:46 2018 +0000
@@ -0,0 +1,2935 @@
+/*
++-----------------------------------------------------------------------------
+|  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 custom specific functions
+|             for the component RR of the mobile station
++-----------------------------------------------------------------------------
+*/
+
+#ifndef RR_CSF_C
+#define RR_CSF_C
+
+#define ENTITY_RR
+#define SAP_ACI
+
+/*==== INCLUDES ===================================================*/
+
+#include <string.h>
+#include <stdlib.h>
+#include <stddef.h>    /* offsetof */
+#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 "cl_imei.h"   /* IMEI common library */
+#if defined(_SIMULATION_FFS_)
+#include "ffs/ffs.h"
+#include "ffs_coat.h"
+#endif /* _SIMULATION_FFS_ */
+
+/*==== EXPORT =====================================================*/
+
+/*==== PRIVAT =====================================================*/
+#if defined(_SIMULATION_FFS_)
+LOCAL BOOL rr_csf_handle_ffs_read_result(T_FFS_SIZE status_read);
+LOCAL BOOL rr_csf_handle_ffs_write_result(T_FFS_RET status_write);
+LOCAL void rr_csf_check_ffs_dirs( void );
+LOCAL void rr_csf_create_ffs_dirs(const char *dir_name);
+#endif /* _SIMULATION_FFS_ */
+
+
+
+/*==== VARIABLES ==================================================*/
+/* Cell selection improvements LLD section 4.1.1.1 */
+#if defined(_SIMULATION_)
+T_LIST  win_black_list[MAX_REGIONS];  /* Simulates FFS for "Black List" */
+T_CS_WHITE_LIST win_white_list;       /* Simulates FFS for "White List  */
+
+/*Simulates FFS for lower rxlevel thresholds*/
+UBYTE win_lower_rxlev_thr[MAX_NUM_BANDS] = { LOWER_RXLEV_THRESHOLD_850, LOWER_RXLEV_THRESHOLD, \
+    LOWER_RXLEV_THRESHOLD, LOWER_RXLEV_THRESHOLD, LOWER_RXLEV_THRESHOLD };
+ /*Simulates FFS for medium rxlevel thresholds*/
+UBYTE win_medium_rxlev_thr[MAX_NUM_BANDS] = { MEDIUM_RXLEV_THRESHOLD, MEDIUM_RXLEV_THRESHOLD, \
+    MEDIUM_RXLEV_THRESHOLD, MEDIUM_RXLEV_THRESHOLD, MEDIUM_RXLEV_THRESHOLD };
+/*Simulates FFS for upper rxlevel thresholds*/
+UBYTE win_upper_rxlev_thr[MAX_NUM_BANDS] = { UPPER_RXLEV_THRESHOLD, UPPER_RXLEV_THRESHOLD, \
+    UPPER_RXLEV_THRESHOLD, UPPER_RXLEV_THRESHOLD, UPPER_RXLEV_THRESHOLD }; 
+  /* Initialize the simulated rxlevel thresholds here itself */
+#endif
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_read_imei           |
++--------------------------------------------------------------------+
+
+  PURPOSE : The function reads the International mobile identity number
+            from the non-volantile memory into an internal data structure.
+
+*/
+
+GLOBAL void rr_csf_read_imei (T_mob_ident *imei)
+{
+  UBYTE buf[CL_IMEI_SIZE];
+
+  TRACE_FUNCTION ("rr_csf_read_imei()");
+
+  imei->v_ident_dig  = TRUE;
+  imei->v_tmsi_1     = FALSE;
+  imei->ident_type   = 3;     /* set to TYPE_IMEISV */
+  imei->c_ident_dig  = 16;
+  imei->odd_even     = 0;
+
+  /* Get IMEISV from IMEI common library */
+  cl_get_imeisv(CL_IMEI_SIZE, buf, CL_IMEI_GET_SECURE_IMEI);
+
+  /* copy digits */
+  imei->ident_dig[0] = (buf [0] >> 4) & 0x0F; /* TAC 8 byte */
+  imei->ident_dig[1] =  buf [0] & 0x0F;
+  imei->ident_dig[2] = (buf [1] >> 4) & 0x0F;
+  imei->ident_dig[3] =  buf [1] & 0x0F;
+  imei->ident_dig[4] = (buf [2] >> 4) & 0x0F;
+  imei->ident_dig[5] =  buf [2] & 0x0F;
+  imei->ident_dig[6] = (buf [3] >> 4) & 0x0F;
+  imei->ident_dig[7] =  buf [3] & 0x0F;
+  imei->ident_dig[8] = (buf [4] >> 4) & 0x0F; /* SNR 6 byte */
+  imei->ident_dig[9] =  buf [4] & 0x0F;
+  imei->ident_dig[10]= (buf [5] >> 4) & 0x0F;
+  imei->ident_dig[11]=  buf [5] & 0x0F;
+  imei->ident_dig[12]= (buf [6] >> 4) & 0x0F;
+  imei->ident_dig[13]=  buf [6] & 0x0F;
+  imei->ident_dig[14]= (buf [7] >> 4) & 0x0F; /* SV 2 byte */
+  imei->ident_dig[15]=  buf [7] & 0x0F;
+  
+  TRACE_EVENT_P8("RR INFO IMEI: TAC %1x%1x%1x%1x%1x%1x%1x%1x",
+                  imei->ident_dig[0], imei->ident_dig[1], imei->ident_dig[2],
+                  imei->ident_dig[3], imei->ident_dig[4], imei->ident_dig[5],
+                  imei->ident_dig[6], imei->ident_dig[7]);
+  TRACE_EVENT_P6("RR INFO IMEI: SNR %1x%1x%1x%1x%1x%1x",
+                  imei->ident_dig[8],  imei->ident_dig[9], imei->ident_dig[10],
+                  imei->ident_dig[11], imei->ident_dig[12], imei->ident_dig[13]);
+  TRACE_EVENT_P2("RR INFO IMEI: SV  %1x%1x", imei->ident_dig[14],
+                                             imei->ident_dig[15]);
+}
+
+#if !defined(NTRACE)
+GLOBAL void rr_csf_trace_power (void)
+{
+  GET_INSTANCE_DATA;
+  UBYTE setbands = rr_data->ms_data.rf_cap.setbands;
+  UBYTE bands = rr_data->ms_data.rf_cap.bands;
+  UBYTE stdbands;
+
+  if (setbands EQ 0)
+  {
+    setbands = bands; /* auto detection, use all supported bands */
+  }
+  else
+    setbands &= bands;/* bands set, use only supported bands */
+
+  /* bands which might be supported with current std */
+  stdbands = std_bands[std-1];
+
+  TRACE_EVENT_P5 ("std=%d(%02x), (set)bands=%02x(%02x)->%02x",
+    std, stdbands, rr_data->ms_data.rf_cap.setbands,
+    rr_data->ms_data.rf_cap.bands, setbands);
+  TRACE_EVENT_P6 ("%sGSM 900: power class=%u %s,%s%s%s",
+    (bands&0x08)?"E":" ",
+    rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_900].pow_class,
+    (bands&0x09)?"rfcap":"     ",
+    (stdbands&0x09)?"std":"   ",
+    (setbands&0x09)?",supported":"",
+    ((setbands&0x09) AND (setbands&0x09) EQ 0x01)?" (only GSM)":"");
+  TRACE_EVENT_P4 ("DCS 1800: power class=%u %s,%s%s",
+    rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class,
+    (bands&0x02)?"rfcap":"     ",
+    (stdbands&0x02)?"std":"   ",
+    (setbands&0x02)?",supported":"");
+  TRACE_EVENT_P4 ("PCS 1900: power class=%u %s,%s%s",
+    rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class,
+    (bands&0x04)?"rfcap":"     ",
+    (stdbands&0x04)?"std":"   ",
+    (setbands&0x04)?",supported":"");
+  TRACE_EVENT_P4 ("GSM  850: power class=%u %s,%s%s",
+    rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_850].pow_class,
+    (bands&0x10)?"rfcap":"     ",
+    (stdbands&0x10)?"std":"   ",
+    (setbands&0x10)?",supported":"");
+  TRACE_EVENT_P4 ("GSM  400: power class=%u %s,%s%s",
+    rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_400].pow_class,
+    (bands&0x60)?"rfcap":"     ",
+    (stdbands&0x60)?"std":"   ",
+    (setbands&0x60)?",supported":"");
+  TRACE_EVENT_P1 ("GPRS multislot class =%u",
+    rr_data->ms_data.rf_cap.rf_ms.gprs_ms_class);
+}
+#endif  /* !NTRACE */
+
+#if defined(_SIMULATION_) && !defined(NTRACE)
+#define TRACE_STRUCT(struct_member) TRACE_EVENT_P1("0x%02x " #struct_member , *((unsigned int*)&struct_member))
+
+LOCAL void rr_csf_trace_class1 (T_mob_class_1* cm1)
+{
+  TRACE_STRUCT (cm1->rev_lev);
+  TRACE_STRUCT (cm1->es_ind);
+  TRACE_STRUCT (cm1->a5_1);
+  TRACE_STRUCT (cm1->rf_pow_cap);
+}
+
+LOCAL void rr_csf_trace_class2 (T_mob_class_2* cm2)
+{
+  TRACE_STRUCT (cm2->rev_lev);
+  TRACE_STRUCT (cm2->es_ind);
+  TRACE_STRUCT (cm2->a5_1);
+  TRACE_STRUCT (cm2->rf_pow_cap);
+  TRACE_STRUCT (cm2->ps);
+  TRACE_STRUCT (cm2->ss_screen);
+  TRACE_STRUCT (cm2->mt_pp_sms);
+  TRACE_STRUCT (cm2->vbs);
+  TRACE_STRUCT (cm2->vgcs);
+  TRACE_STRUCT (cm2->egsm);
+  TRACE_STRUCT (cm2->class3);
+  TRACE_STRUCT (cm2->lcsva);
+  TRACE_STRUCT (cm2->ucs2_treat);
+  TRACE_STRUCT (cm2->solsa);
+  TRACE_STRUCT (cm2->cmsp);
+  TRACE_STRUCT (cm2->a5_3);
+  TRACE_STRUCT (cm2->a5_2);
+}
+
+LOCAL void rr_csf_trace_class3 (T_mob_class_3* cm3)
+{
+  TRACE_STRUCT (cm3->mb_value);
+  TRACE_STRUCT (cm3->a5_7);
+  TRACE_STRUCT (cm3->a5_6);
+  TRACE_STRUCT (cm3->a5_5);
+  TRACE_STRUCT (cm3->a5_4);
+  if (cm3->v_radio_cap_2)
+  {
+    TRACE_STRUCT (cm3->radio_cap_2);
+  }
+  if (cm3->v_radio_cap_1)
+  {
+    TRACE_STRUCT (cm3->radio_cap_1);
+  }
+  if (cm3->v_rgsm_class)
+  {
+    TRACE_STRUCT (cm3->rgsm_class);
+  }
+  if (cm3->v_ms_class)
+  {
+    TRACE_STRUCT (cm3->ms_class);
+  }
+
+  TRACE_STRUCT (cm3->ucs2_treat);
+  TRACE_STRUCT (cm3->ext_meas);
+  if (cm3->v_measurement)
+  {
+    TRACE_STRUCT (cm3->measurement);
+  }
+  if (cm3->v_pos_method)
+  {
+    TRACE_STRUCT (cm3->pos_method);
+  }
+  if (cm3->v_edge_ms_class)
+  {
+    TRACE_STRUCT (cm3->edge_ms_class);
+  }
+  if (cm3->v_egde_struct)
+  {
+    TRACE_STRUCT (cm3->egde_struct.mod);
+    if (cm3->egde_struct.v_egde_pow1)
+    {
+      TRACE_STRUCT (cm3->egde_struct.egde_pow1);
+    }
+    if (cm3->egde_struct.v_egde_pow2)
+    {
+      TRACE_STRUCT (cm3->egde_struct.egde_pow2);
+    }
+  }
+#ifdef REL99
+  if (cm3->v_gsm400_struct)
+  {
+    TRACE_STRUCT (cm3->gsm400_struct.gsm400_supp);
+    TRACE_STRUCT (cm3->gsm400_struct.gsm400_cap);
+  }
+#endif
+  if (cm3->v_gsm850_cap)
+  {
+    TRACE_STRUCT (cm3->gsm850_cap);
+  }
+  if (cm3->v_pcs1900_cap)
+  {
+    TRACE_STRUCT (cm3->pcs1900_cap);
+  }
+#ifdef REL99
+  TRACE_STRUCT (cm3->umts_fdd);
+  TRACE_STRUCT (cm3->umts_tdd);
+  TRACE_STRUCT (cm3->cdma2000);
+#endif
+  if (cm3->v_dtm_ms)
+  {
+    TRACE_STRUCT (cm3->dtm_ms.dtm_g_ms_class);
+    TRACE_STRUCT (cm3->dtm_ms.mac_support);
+    if (cm3->dtm_ms.v_dtm_e_ms_class)
+    {
+      TRACE_STRUCT (cm3->dtm_ms.dtm_e_ms_class);
+    }
+  }
+  if (cm3->v_single_band)
+  {
+    TRACE_STRUCT (cm3->single_band);
+  }
+}
+#endif  /* _SIMULATION_ && !NTRACE */
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_ms_cap              |
++--------------------------------------------------------------------+
+
+  PURPOSE : Read the mobile station capabilities from a non-volantile
+            memory into an internal data structure.
+
+*/
+#if !defined(NTRACE)
+#define  RFCAP_TEST
+#endif /* !NTRACE */
+
+GLOBAL void rr_csf_ms_cap (void)
+{
+  GET_INSTANCE_DATA;
+  drv_Return_Type   pcm_ret;
+  UBYTE             version;
+
+  TRACE_FUNCTION ("rr_csf_ms_cap()");
+
+  pcm_ret = pcm_ReadFile ((UBYTE *)EF_MSCAP_ID, SIZE_EF_MSCAP,
+                          (UBYTE *)&rr_data->mscap, &version);
+  if(pcm_ret NEQ PCM_OK )
+  {
+    TRACE_ERROR( "MS RF capability (EF_MSCAP_ID) -> PCM read error" );
+  }
+#if defined(RFCAP_TEST)
+  else
+  {
+    TRACE_ARRAY ((UBYTE*)&rr_data->mscap, SIZE_EF_MSCAP, "EF_MSCAP_ID");
+  }
+#endif  /* RFCAP_TEST */
+}
+
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_read_rf_cap              |
++--------------------------------------------------------------------+
+
+  PURPOSE : Read the mobile station capabilities from a non-volantile
+            memory into an internal data structure.
+
+*/
+GLOBAL void rr_csf_read_rfcap (void)
+{
+  GET_INSTANCE_DATA;
+#define FldSetEx(f,n,v) (f|=((((ULONG)f)&(~((ULONG)n##m)))|(((ULONG)v)<<n##s)))
+
+  EF_RFCAP          rfcap_stream;
+  BYTE              ccd_ret;
+  UBYTE             version;
+#if !defined(_SIMULATION_)
+  unsigned int      ffs_ret;
+#else
+  drv_Return_Type   pcm_ret;
+#endif /* _TMS470 */
+  UBYTE  gprs_ms, cmsp;
+
+  TRACE_FUNCTION ("rr_csf_read_rfcap()");
+
+  /* save configured GPRS multislot class */
+  gprs_ms = rr_data->ms_data.rf_cap.rf_ms.gprs_ms_class;
+  /* save configured CMSP bit */
+  cmsp = rr_data->ms_data.rf_cap.cmsp;
+
+#if !defined(_SIMULATION_)
+  ffs_ret = FFS_fread("/gsm/com/rfcap", (UBYTE *)&rfcap_stream, sizeof(EF_RFCAP));
+  if (ffs_ret EQ sizeof(EF_RFCAP))
+    version = TRUE;
+  else
+    version = FALSE;
+#else
+  pcm_ret = pcm_ReadFile ((UBYTE *)EF_RFCAP_ID, SIZE_EF_RFCAP,
+                          (UBYTE *)&rfcap_stream, &version);
+  if(pcm_ret EQ PCM_OK )
+    version = TRUE;
+  else
+    version = FALSE;
+#endif
+#define RFCAP_DEFAULT /* G23M/RR-ENH-9401 */
+#if !defined(RFCAP_DEFAULT)
+  if (!version)
+  {
+    TRACE_ERROR ("MS RF capability (rfcap) -> FFS read error. Reset will follow ...");
+    /*
+     * the following delay is made on the target for reasons highlighted with
+     * issue 7510: some customers do during their production the download of the
+     * configuration to the flash whilst the target ist running; another reason is
+     * that the target is not accessable (e.g. via PTCM) during resets; thus
+     * the delay is present to allow that writing of config data is not disturbed
+     * by the reset
+     */
+#if !defined(_SIMULATION_)
+    TRACE_ERROR ("... in some seconds; download config data to flash please!");
+    vsi_t_sleep(VSI_CALLER DELAY_RESET_NO_CONFIG_DATA);
+#endif
+    assert (FALSE);
+  }
+#else /* !RFCAP_DEFAULT */
+  if (!version)
+  {
+/* Implements Measure#32: Row 150 */
+
+    /* error output via trace interface */
+    TRACE_ERROR( "MS RF capability (RFCAP) -> FFS/PCM read error: use default values instead");
+
+#ifdef TI_PS_CUSTOM_RFCAP_DEFAULT
+    /* Update with the Custom defined default RF capabilities */
+    memcpy(&rfcap_stream, custom_rfcap_default, SIZE_EF_RFCAP);
+    TRACE_EVENT_P2("Using Custom RFCAP values: Set_bands=%d, Freq_bands=%d", rfcap_stream.setbands, rfcap_stream.bands);
+    #ifndef FF_L23_A5_3
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_3, NO);
+    #endif
+#else
+
+    memset (&rfcap_stream, 0, SIZE_EF_RFCAP);
+
+    /* default frequency bands */
+    rfcap_stream.setbands = BAND_AUTO;
+    rfcap_stream.bands = BAND_GSM_900|BAND_E_GSM|BAND_DCS_1800|BAND_PCS_1900|BAND_GSM_850;
+
+    /* power classes */
+    FldSetEx (rfcap_stream.power1, rfCap_900,  POWER_CLASS_4);
+    FldSetEx (rfcap_stream.power1, rfCap_1800, POWER_CLASS_1);
+    FldSetEx (rfcap_stream.power2, rfCap_1900, POWER_CLASS_1);
+    FldSetEx (rfcap_stream.power2, rfCap_850,  POWER_CLASS_4);
+
+    /* multi slot classes */
+    FldSetEx (rfcap_stream.msGPRS, rfCap_MSC, MSLOT_CLASS_10);
+
+    /* classmark 2 capabilities */
+    FldSetEx (rfcap_stream.capability1, rfCap_esind, YES);
+    FldSetEx (rfcap_stream.capability2, rfCap_vgcs, NOT_SUPPORTED);
+    FldSetEx (rfcap_stream.capability2, rfCap_vbs, NOT_SUPPORTED);
+    FldSetEx (rfcap_stream.capability1, rfCap_ppsms, SUPPORTED);
+    FldSetEx (rfcap_stream.capability2, rfCap_ssc, SS_SCREEN_PHASE_2);
+    FldSetEx (rfcap_stream.capability1, rfCap_ps, NOT_SUPPORTED);
+    FldSetEx (rfcap_stream.capability1, rfCap_cmsp, SUPPORTED);
+    FldSetEx (rfcap_stream.capability1, rfCap_solsa, NOT_SUPPORTED);
+    FldSetEx (rfcap_stream.capability2, rfCap_usc2, SUPPORTED);
+    FldSetEx (rfcap_stream.capability1, rfCap_lcsva, NOT_SUPPORTED);
+
+    /* classmark 3 capabilities */
+    FldSetEx (rfcap_stream.capability2, rfCap_extmeas, NOT_SUPPORTED);
+    FldSetEx (rfcap_stream.capability2, rfCap_meas, NO);
+    FldSetEx (rfcap_stream.switchmeasure, rfCap_smst, SM_1);
+    FldSetEx (rfcap_stream.switchmeasure, rfCap_smt, SM_1);
+
+    /* encryption algorithm */
+    /*
+     * note inverse logic for the A5/1 encryption algorithm between
+     * classmark 1 and 2 on the one hand and radio access capability
+     * on the other hand
+     */
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_1, YES);
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_2, NO);
+    #ifdef FF_L23_A5_3
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_3, YES);
+    #else
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_3, NO);
+    #endif
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_4, NO);
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_5, NO);
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_6, NO);
+    FldSetEx (rfcap_stream.encryption, rfCap_A5_7, NO);
+#endif /* TI_PS_CUSTOM_RFCAP_DEFAULT */
+  }
+#endif /* !RFCAP_DEFAULT */
+
+  /* E-GSM includes P-GSM */
+  if (FldGet (rfcap_stream.bands, rf_EGSM))
+  {
+    FldSetEx (rfcap_stream.bands, rf_900, SUPPORTED);
+  }
+
+#if defined(RFCAP_TEST)
+  TRACE_ARRAY ((UBYTE*)&rfcap_stream, SIZE_EF_RFCAP, "rfcap_stream");
+#endif  /* RFCAP_TEST */
+
+  {/* decode stream into c struct */
+    #define DECODE_TMP  MS_RF_CAPABILITY
+    typedef struct
+    {
+      U32                       dummy; /*<  0:  4>                   */
+      T_sdu                     sdu;   /*<  4: ? > Service Data Unit */
+    } T_DECODE_TMP;
+    T_MS_RF_CAPABILITY *ms_rf_cap;
+    USHORT  off;
+    PALLOC_SDU (encode, DECODE_TMP, (SIZE_EF_RFCAP + 1 ) * BITS_PER_BYTE);
+    MALLOC (ms_rf_cap, sizeof (T_MS_RF_CAPABILITY));
+
+    /* The dummy field is needed to make the structure compatible for *
+     * the CCD. We need to initialise it to keep LINT happy */
+    encode->dummy = 0x00;
+
+    off = (USHORT)(encode->sdu.o_buf / BITS_PER_BYTE);
+    memcpy ( &encode->sdu.buf[off+1], &rfcap_stream, SIZE_EF_RFCAP);
+    encode->sdu.buf[off] = MS_RF_CAPABILITY;
+
+    memset (ms_rf_cap, 0, sizeof (T_MS_RF_CAPABILITY));
+    ccd_ret = ccd_decodeMsg(CCDENT_RR_COM, DOWNLINK,
+                            (T_MSGBUF *)&encode->sdu, (UBYTE *)ms_rf_cap,
+                            0xFF);
+    rr_data->ms_data.rf_cap = ms_rf_cap->rf_cap; /* Struct copy */
+    MFREE (ms_rf_cap);
+    PFREE (encode);
+  }
+
+  /* restore configured GPRS multislot class */
+  if (rr_data->ms_data.multislot_class_configured)
+  {
+    rr_data->ms_data.rf_cap.rf_ms.gprs_ms_class = gprs_ms;
+    TRACE_EVENT_P1 ("'gprs_ms_class' configured to a value of %d (overwrite of rfcap)", gprs_ms);
+  }
+
+  /* restore configured CMSP bit */
+  if (rr_data->ms_data.cmsp_configured)
+  {
+    rr_data->ms_data.rf_cap.cmsp = cmsp;
+    TRACE_EVENT_P1 ("'cmsp' configured to a value of %d (overwrite of rfcap)", cmsp);
+  }
+
+
+
+#if defined(RFCAP_TEST)
+  if (ccd_ret NEQ ccdOK)
+  {
+    /*
+     * CCD has detected an error
+     */
+    UBYTE first_err;
+    USHORT parlist [6];
+/* Implements Measure#32: Row 152...165 */
+
+    TRACE_EVENT_P1 ("ccd_decodeMsg(): %02x", ccd_ret);
+    /*
+     * get the first error
+     */
+    first_err = ccd_getFirstError (CCDENT_RR, parlist);
+
+    /*
+     * Error Handling
+     */
+    do
+    {
+/* Implements Measure#32: Row 152...165 */
+      switch (first_err)
+      {
+        case ERR_NO_MORE_ERROR:
+          TRACE_EVENT_P1("%u the end of the error list is reached", first_err);
+          break;
+        case ERR_INVALID_CALC:
+          TRACE_EVENT_P1("%u calculation of the element repeat value failed", first_err);
+          break;
+        case ERR_PATTERN_MISMATCH:
+          TRACE_EVENT_P1("%u a bit pattern was not expected", first_err);
+          break;
+        case ERR_COMPREH_REQUIRED:
+          TRACE_EVENT_P1("%u check for comprehension required failed", first_err);
+          break;
+        case ERR_IE_NOT_EXPECTED:
+          TRACE_EVENT_P1("%u an information element was not expected", first_err);
+          break;
+        case ERR_IE_SEQUENCE:
+          TRACE_EVENT_P1("%u wrong sequence of information elements", first_err);
+          break;
+        case ERR_MAX_IE_EXCEED:
+          TRACE_EVENT_P1("%u maximum amount of repeatable information elements has exceeded", first_err);
+          break;
+        case ERR_MAX_REPEAT:
+          TRACE_EVENT_P1("%u a repeatable element occurs too often in the message", first_err);
+          break;
+        case ERR_MAND_ELEM_MISS:
+          TRACE_EVENT_P1("%u a mandatory information element is missing", first_err);
+          break;
+        case ERR_INVALID_MID:
+          TRACE_EVENT_P1("%u the message ID is not correct", first_err);
+          break;
+        case ERR_INVALID_TYPE:
+          TRACE_EVENT_P1("%u the information element is not a spare padding", first_err);
+          break;
+        case ERR_EOC_TAG_MISSING:
+          TRACE_EVENT_P1("%u indefinite length is specified for the ASN.1-BER but the end tag is missing", first_err);
+          break;
+        case ERR_INTERNAL_ERROR:
+          TRACE_EVENT_P1("%u an internal CCD error occured ", first_err);
+          break;
+        default:
+          TRACE_EVENT_P1("%u unknown error", first_err);
+          break;
+      }
+      first_err = ccd_getNextError (CCDENT_RR, parlist);
+    }while (first_err);
+
+  }
+
+#if 0
+  if (ccd_ret < ccdError)
+  {
+    rr_csf_trace_power ();
+  }
+#endif  /* 0|1 */
+#endif /* RFCAP_TEST */
+}
+
+GLOBAL void rr_csf_get_freq_bands (UBYTE *pfreq_bands)
+{
+  GET_INSTANCE_DATA;
+  T_rf_cap *rfc = &rr_data->ms_data.rf_cap;
+
+#if defined(_SIMULATION_)
+  rr_csf_check_rfcap (FALSE);
+#endif  /* _SIMULATION_ */
+
+  if (rfc->setbands EQ BAND_AUTO)
+    *pfreq_bands = rfc->bands;
+  else
+    *pfreq_bands = rfc->setbands &  rfc->bands;
+#if !defined(NTRACE)
+  rr_csf_trace_power ();
+#endif  /* !NTRACE */
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_get_classmark1      |
++--------------------------------------------------------------------+
+
+  PURPOSE : fills c structure of the mobile station classmark 1
+            information element; returns 0 if OK.
+
+*/
+/*lint -esym(765,rr_csf_get_classmark1) | used by MM*/
+/*lint -esym(714,rr_csf_get_classmark1) | used by MM */
+GLOBAL UBYTE rr_csf_get_classmark1 (T_mob_class_1 *mob_class_1)
+{
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_get_classmark1()");
+
+#if defined(_SIMULATION_)
+  rr_csf_check_rfcap (FALSE);
+#endif  /* _SIMULATION_ */
+
+  *mob_class_1 = rr_data->ms_data.classmark1;
+
+#if defined(_SIMULATION_) && !defined(NTRACE)
+  rr_csf_trace_class1 (mob_class_1);
+#endif  /* _SIMULATION_ && !NTRACE */
+  return 0;/* no error */
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_get_classmark2      |
++--------------------------------------------------------------------+
+
+  PURPOSE : fills c structure of the mobile station classmark 2
+            information element; returns 0 if OK.
+
+*/
+/*lint -esym(765,rr_csf_get_classmark2) | used by CC,MM */
+/*lint -esym(714,rr_csf_get_classmark2) | used by CC,MM */
+GLOBAL UBYTE rr_csf_get_classmark2 (T_mob_class_2 *mob_class_2)
+{
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_get_classmark2()");
+
+#if defined(_SIMULATION_)
+  rr_csf_check_rfcap (FALSE);
+#endif  /* _SIMULATION_ */
+
+  *mob_class_2 = rr_data->ms_data.classmark2;
+
+#if defined(_SIMULATION_) && !defined(NTRACE)
+  rr_csf_trace_class2 (mob_class_2);
+#endif  /* _SIMULATION_ && !NTRACE */
+  return 0;/* no error */
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_get_classmark3      |
++--------------------------------------------------------------------+
+
+  PURPOSE : fills c structure of the mobile station classmark 3
+            information element; returns 0 if OK.
+
+*/
+#if 0
+GLOBAL UBYTE rr_csf_get_classmark3 (T_mob_class_3 *mob_class_3)
+{
+  TRACE_FUNCTION ("rr_csf_get_classmark3()");
+
+#if defined(_SIMULATION_)
+  rr_csf_check_rfcap (FALSE);
+#endif  /* _SIMULATION_ */
+
+  *mob_class_3 = rr_data->ms_data.classmark3;
+
+#if defined(_SIMULATION_) && !defined(NTRACE)
+  rr_csf_trace_class3 (mob_class_3);
+#endif  /* _SIMULATION_ && !NTRACE */
+  return 0;/* no error */
+}
+#endif
+
+#ifdef GPRS
+/* fills c structure of the mobile station radio access capability information element; returns 0 if OK */
+/*lint -esym(765,rr_csf_get_radio_access_capability) | used by GMM,GRR */
+/*lint -esym(714,rr_csf_get_radio_access_capability) | used by GMM,GRR */
+GLOBAL UBYTE rr_csf_get_radio_access_capability (T_ra_cap *ra_cap)
+{
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_get_radio_access_capability()");
+
+#if defined(_SIMULATION_)
+  rr_csf_check_rfcap (FALSE);
+#endif  /* _SIMULATION_ */
+
+  *ra_cap = rr_data->ms_data.ra_cap;
+  return 0;
+}
+#endif
+
+/* get pointer to mobile station RF capability c structure; returns NULL on error */
+/*lint -esym(765,rr_csf_get_rf_capability) | used by GRR */
+/*lint -esym(714,rr_csf_get_rf_capability) | used by GRR */
+GLOBAL T_rf_cap*  rr_csf_get_rf_capability (void)
+{
+  GET_INSTANCE_DATA;
+#if defined(_SIMULATION_)
+  rr_csf_check_rfcap (FALSE);
+#endif  /* _SIMULATION_ */
+
+  return &rr_data->ms_data.rf_cap;
+}
+
+GLOBAL void rr_csf_check_rfcap (UBYTE init)
+{
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_check_rfcap()");
+
+  if (init OR (rr_data->ms_data.rf_cap.bands EQ 0))
+  {
+    rr_csf_read_rfcap ();
+    rr_csf_fit_capability ();
+  }
+}
+
+
+#ifndef REL99
+
+#define RAC_RELEASE97
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_fit_capability      |
++--------------------------------------------------------------------+
+
+  PURPOSE : fit classmark 2 and 3 and radio access capabilities
+            depend on the value of 'std' and the readed values of
+            /gsm/com/rfcap file according to R99 specifications
+*/
+
+GLOBAL UBYTE rr_csf_fit_capability (void)
+{
+  GET_INSTANCE_DATA;
+  USHORT serving_cell;
+  T_rf_cap      *rfc = &rr_data->ms_data.rf_cap;
+#ifdef GPRS
+  T_ra_cap      *rac = &rr_data->ms_data.ra_cap;
+#endif
+  T_mob_class_1 *cm1 = &rr_data->ms_data.classmark1;
+  T_mob_class_2 *cm2 = &rr_data->ms_data.classmark2;
+  T_mob_class_3 *cm3 = &rr_data->ms_data.classmark3;
+
+  TRACE_FUNCTION ("rr_csf_fit_capability()");
+
+  if (rr_data->nc_data[SC_INDEX].bcch_status NEQ EMPTY)
+    serving_cell = rr_data->nc_data[SC_INDEX].arfcn;
+  else
+    serving_cell = (USHORT)-1;
+
+  memset (cm2, 0, sizeof(T_mob_class_2));
+  memset (cm3, 0, sizeof(T_mob_class_3));
+#ifdef GPRS
+  memset (rac, 0, sizeof(T_ra_cap));
+#endif
+
+  cm1->rev_lev = cm2->rev_lev = REV_LEV_PHASE_2;  /* PHASE_1 | PHASE_2 | R99_SUPPORT */
+#ifdef GPRS
+#if !defined(RAC_RELEASE97)
+  rac->acc_cap.rev99 = REV_LEV_PHASE_1;           /* PHASE_1 | RELEASE99 */
+#endif  /* !RAC_RELEASE97 */
+#endif
+  cm1->es_ind     = cm2->es_ind = rfc->es_ind;
+  cm2->ps         = rfc->ps;
+  cm2->ss_screen  = rfc->ss_screen;
+  cm2->mt_pp_sms  = rfc->mt_pp_sms;
+  cm2->vbs        = rfc->vbs;
+  cm2->vgcs       = rfc->vgcs;
+  cm2->class3     = SUPPORTED;             /* options indicated in classmark 3 */
+  cm2->lcsva      = rfc->lcsva;
+  cm2->ucs2_treat = cm3->ucs2_treat = rfc->ucs2_treat;
+  cm2->solsa      = rfc->solsa;
+  cm2->cmsp       = rfc->cmsp;
+
+  /*
+   * note inverse logic for the A5/1 encryption algorithm between
+   * classmark 1 and 2 on the one hand and radio access capability
+   * on the other hand
+   */
+  cm1->a5_1 = cm2->a5_1 = !rfc->a5_bits.a5_1;
+  cm2->a5_2 = rfc->a5_bits.a5_2;
+  cm2->a5_3 = rfc->a5_bits.a5_3;
+
+  cm3->a5_4 = rfc->a5_bits.a5_4;
+  cm3->a5_5 = rfc->a5_bits.a5_5;
+  cm3->a5_6 = rfc->a5_bits.a5_6;
+  cm3->a5_7 = rfc->a5_bits.a5_7;
+
+#ifdef GPRS
+  rac->acc_cap.es_ind = rfc->es_ind;
+  rac->acc_cap.ps = rfc->ps;
+  rac->acc_cap.vbs = rfc->vbs;
+  rac->acc_cap.vgcs = rfc->vgcs;
+  rac->acc_cap.v_a5_bits = SUPPORTED;
+  rac->acc_cap.a5_bits = rfc->a5_bits;
+#if !defined(RAC_RELEASE97)
+  rac->acc_cap.compact = rfc->compact;
+#endif  /* !RAC_RELEASE97 */
+
+  /* single- or multiband */
+  rac->flag_ra_cap2 = rac->v_ra_cap2 = NO;
+
+#endif
+
+  switch (std)
+  {
+    case STD_900:
+      cm3->mb_value = MB_GSM900;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_P;
+#endif
+      break;
+    case STD_EGSM:
+      cm2->egsm = SUPPORTED;
+      cm3->mb_value = MB_EGSM;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_E;
+#endif
+      break;
+    case STD_1800:
+      cm3->mb_value = MB_DCS1800;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_1800;
+#endif
+      break;
+    case STD_DUAL:
+      cm3->mb_value = MB_DUAL;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_P;
+      rac->flag_ra_cap2 = rac->v_ra_cap2 = YES;
+      rac->ra_cap2.acc_tech_typ = ACC_GSM_1800;
+      rac->ra_cap2.acc_cap = rac->acc_cap;
+      rac->ra_cap2.acc_cap.v_a5_bits = NOT_SUPPORTED;
+      rac->ra_cap2.acc_cap.v_ms_struct = NOT_SUPPORTED;
+#if !defined(RAC_RELEASE97)
+      rac->ra_cap2.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif  /* !RAC_RELEASE97 */
+#endif
+      break;
+    case STD_DUAL_EGSM:
+      /* note: incase of 1800 band, the FC bit shall be set to 0 */ 
+      if((rr_data->ms_data.rr_service EQ FULL_SERVICE) AND 
+         (!INRANGE(LOW_CHANNEL_1800,rr_data->nc_data[SC_INDEX].arfcn,HIGH_CHANNEL_1800)))
+      cm2->egsm = SUPPORTED;
+      cm3->mb_value = MB_DUAL_EXT;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_E;
+      rac->flag_ra_cap2 = rac->v_ra_cap2 = YES;
+      rac->ra_cap2.acc_tech_typ = ACC_GSM_1800;
+      rac->ra_cap2.acc_cap = rac->acc_cap;
+      rac->ra_cap2.acc_cap.v_a5_bits = NOT_SUPPORTED;
+      rac->ra_cap2.acc_cap.v_ms_struct = NOT_SUPPORTED;
+#if !defined(RAC_RELEASE97)
+      rac->ra_cap2.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif  /* !RAC_RELEASE97 */
+#endif
+     break;
+
+    case STD_1900:
+    case STD_850:
+    case STD_DUAL_US:
+      /* no break; go through */
+    default:
+      cm3->mb_value = MB_NO_EUROPEAN_BAND;
+      break;
+  }
+
+  /* power classes */
+  if (rfc->bands & 0x80)
+  {
+    TRACE_ERROR("R-GSM not supported by PS software");
+    /* note: cm3->v_rgsm_class (and cm3->rgsm_class) are hard coded to 0 */
+  }
+  if (rfc->bands & 0x60)
+  {
+    TRACE_ERROR("GSM 400 not supported by PS software");
+    /* note: cm3->v_gsm400_struct (and cm3->gsm400_struct) are hard coded to 0 */
+  }
+  switch (std)
+  {
+    case STD_900:
+    case STD_EGSM:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+      cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      rac->acc_cap.pow_class = cm3->radio_cap_1;
+#endif
+      break;
+
+    case STD_1800:
+      /* single band => only radio_cap_1 */
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class;
+      cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      rac->acc_cap.pow_class = cm3->radio_cap_1;
+#endif
+      break;
+
+    case STD_DUAL:
+    case STD_DUAL_EGSM:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+      cm3->v_radio_cap_2 = TRUE;
+      cm3->radio_cap_2 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class;
+      /* note: in case the sc is´nt set, it is out of range */
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+        cm2->rf_pow_cap = cm3->radio_cap_2 - 1;
+      else
+        cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      rac->acc_cap.pow_class = cm3->radio_cap_1;
+      rac->ra_cap2.acc_cap.pow_class = cm3->radio_cap_2;
+#endif
+      break;
+
+    case STD_1900:
+      cm3->v_pcs1900_cap = SUPPORTED;
+      cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class;
+      cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_1900;
+      rac->acc_cap.pow_class = cm3->pcs1900_cap;
+#endif
+      break;
+
+    case STD_850:
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_850;
+      rac->acc_cap.pow_class = cm3->gsm850_cap;
+#endif
+      break;
+
+    case STD_DUAL_US:
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      cm3->v_pcs1900_cap = SUPPORTED;
+      cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class;
+      /* note: in case the sc is´nt set, it is out of range */
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+        cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+      else
+        cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+#ifdef GPRS
+      rac->acc_tech_typ = ACC_GSM_850;
+      rac->acc_cap.pow_class = cm3->gsm850_cap;
+      rac->flag_ra_cap2 = rac->v_ra_cap2 = YES;
+      rac->ra_cap2.acc_tech_typ = ACC_GSM_1900;
+      rac->ra_cap2.acc_cap = rac->acc_cap;
+      rac->ra_cap2.acc_cap.v_a5_bits = NOT_SUPPORTED;
+      rac->ra_cap2.acc_cap.v_ms_struct = NOT_SUPPORTED;
+#if !defined(RAC_RELEASE97)
+      rac->ra_cap2.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif  /* !RAC_RELEASE97 */
+      rac->ra_cap2.acc_cap.pow_class = cm3->pcs1900_cap;
+#endif
+      break;
+
+    default:
+      break;
+  }
+  cm1->rf_pow_cap = cm2->rf_pow_cap;
+
+#if defined(_SIMULATION_) && defined(RFCAP_TEST)
+  rr_csf_trace_power ();
+#endif  /* RFCAP_TEST*/
+
+#if defined(FF_EGDE)
+  if (rfc->mod OR rfc->rf_power.egde_pow1 OR rfc->rf_power.egde_pow2)
+  {
+    cm3->v_egde_struct = SUPPORTED;
+    cm3->egde_struct.mod = rfc->mod;
+  }
+  switch (std)
+  {
+    case STD_900:
+    case STD_EGSM:
+    case STD_850:
+      if (rfc->rf_power.egde_pow1)
+      {
+        if (rfc->mod)
+        {
+          cm3->egde_struct.v_egde_pow1 = SUPPORTED;
+          cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1;
+        }
+#ifdef GPRS
+        rac->acc_cap.v_pow_8psk_cap = SUPPORTED;
+        rac->acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1;
+#endif
+      }
+      break;
+    case STD_1800:
+    case STD_1900:
+      if (rfc->rf_power.egde_pow2)
+      {
+        if (rfc->mod)
+        {
+          cm3->egde_struct.v_egde_pow2 = SUPPORTED;
+          cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2;
+        }
+#ifdef GPRS
+        rac->acc_cap.v_pow_8psk_cap = SUPPORTED;
+        rac->acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2;
+#endif
+      }
+      break;
+    case STD_DUAL:
+    case STD_DUAL_EGSM:
+    case STD_DUAL_US:
+      if (rfc->rf_power.egde_pow1)
+      {
+        if (rfc->mod)
+        {
+          cm3->egde_struct.v_egde_pow1 = SUPPORTED;
+          cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1;
+        }
+#ifdef GPRS
+        rac->acc_cap.v_pow_8psk_cap = SUPPORTED;
+        rac->acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1;
+#endif
+      }
+      if (rfc->rf_power.egde_pow2)
+      {
+        if (rfc->mod)
+        {
+          cm3->egde_struct.v_egde_pow2 = SUPPORTED;
+          cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2;
+        }
+#ifdef GPRS
+        rac->ra_cap2.acc_cap.v_pow_8psk_cap = SUPPORTED;
+        rac->ra_cap2.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2;
+#endif
+      }
+      break;
+    default:
+      break;
+  }
+#endif  /* FF_EGDE */
+
+  /* multi slot capabilities */
+  if (rfc->rf_ms.gsm_ms_class)
+  {
+    cm3->v_ms_class = SUPPORTED;
+    cm3->ms_class = rfc->rf_ms.gsm_ms_class;
+  }
+#if defined(FF_EGDE)
+  if (rfc->rf_ms.edge_ms_class)
+  {
+    cm3->v_edge_ms_class = SUPPORTED;
+    cm3->edge_ms_class = rfc->rf_ms.edge_ms_class;
+  }
+#endif  /* FF_EGDE */
+  if (rfc->rf_ms.dtm_g)
+  {
+#ifdef GPRS
+    rac->acc_cap.v_ms_struct = SUPPORTED;
+#endif
+    cm3->v_dtm_ms = SUPPORTED;
+    cm3->dtm_ms.mac_support =  rfc->mac_support;
+    cm3->dtm_ms.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class;
+#ifdef GPRS
+#if !defined(RAC_RELEASE97)
+    rac->acc_cap.ms_struct.v_dtm_struct = SUPPORTED;
+    rac->acc_cap.ms_struct.dtm_struct.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class;
+    rac->acc_cap.ms_struct.dtm_struct.mac_support = rfc->mac_support;
+#endif  /* !RAC_RELEASE97 */
+#endif
+
+#if defined(FF_EGDE)
+    if (rfc->rf_ms.dtm_e)
+    {
+      cm3->dtm_ms.v_dtm_e_ms_class = SUPPORTED;
+      cm3->dtm_ms.dtm_e_ms_class = rfc->rf_ms.dtm_e_ms_class;
+#ifdef GPRS
+#if !defined(RAC_RELEASE97)
+      rac->acc_cap.ms_struct.v_dtm_struct = SUPPORTED;
+      rac->acc_cap.ms_struct.dtm_struct.v_dtm_e_ms_class = SUPPORTED;
+      rac->acc_cap.ms_struct.dtm_struct.dtm_e_ms_class =  rfc->rf_ms.dtm_e_ms_class;
+#endif  /* !RAC_RELEASE97 */
+#endif
+    }
+#endif  /* FF_EGDE */
+  }
+
+#ifdef GPRS
+  if (rfc->rf_ms.hscsd_ms_class)
+  {
+    rac->acc_cap.v_ms_struct = SUPPORTED;
+    rac->acc_cap.ms_struct.v_hscsd_ms_class = SUPPORTED;
+    rac->acc_cap.ms_struct.hscsd_ms_class = rfc->rf_ms.hscsd_ms_class;
+  }
+
+
+  if (rfc->rf_ms.gprs_ms_class)
+  {
+    rac->acc_cap.v_ms_struct = SUPPORTED;
+    rac->acc_cap.ms_struct.v_gprs_struct = SUPPORTED;
+    rac->acc_cap.ms_struct.gprs_struct.gprs_ms_class = rfc->rf_ms.gprs_ms_class;
+    rac->acc_cap.ms_struct.gprs_struct.gprs_eda = rfc->gprs_eda;
+  }
+
+#endif
+  
+  cm3->ext_meas = rfc->ext_meas;
+
+  if (rfc->meas)
+  {
+#ifdef GPRS
+    rac->acc_cap.v_ms_struct = SUPPORTED;
+    rac->acc_cap.ms_struct.v_sms_sm_value = SUPPORTED;
+    rac->acc_cap.ms_struct.sms_sm_value.sms_val = rfc->sms_val;
+    rac->acc_cap.ms_struct.sms_sm_value.sm_val = rfc->sm_val;
+#endif
+
+    cm3->v_measurement = SUPPORTED;
+    cm3->measurement.sms_val = rfc->sms_val;
+    cm3->measurement.sm_val  = rfc->sm_val;
+  }
+
+#ifdef GPRS
+  if (rfc->rf_ms.ecsd_ms_class)
+  {
+    rac->acc_cap.v_ms_struct = SUPPORTED;
+#if !defined(RAC_RELEASE97)
+    rac->acc_cap.ms_struct.v_ecsd_ms_class = SUPPORTED;
+    rac->acc_cap.ms_struct.ecsd_ms_class = rfc->rf_ms.ecsd_ms_class;
+#endif  /* !RAC_RELEASE97 */
+  }
+#endif
+
+#ifdef GPRS
+  if (rfc->rf_ms.egprs_ms_class)
+  {
+    rac->acc_cap.v_ms_struct = SUPPORTED;
+#if !defined(RAC_RELEASE97)
+    rac->acc_cap.ms_struct.v_egprs_struct = SUPPORTED;
+    rac->acc_cap.ms_struct.egprs_struct.egprs_ms_class = rfc->rf_ms.egprs_ms_class;
+    rac->acc_cap.ms_struct.egprs_struct.egprs_eda = rfc->egprs_eda;
+#endif  /* !RAC_RELEASE97 */
+  }
+
+  if (rac->v_ra_cap2 AND rac->acc_cap.v_ms_struct)
+  {
+#if !defined(RAC_RELEASE97)
+    rac->ra_cap2.acc_cap.rev99 = PHASE_1;           /* PHASE_1 | RELEASE99 */
+    rac->ra_cap2.acc_cap.compact = rfc->compact;
+#endif  /* !RAC_RELEASE97 */
+    rac->ra_cap2.acc_cap.es_ind = rfc->es_ind;
+    rac->ra_cap2.acc_cap.ps = rfc->ps;
+    rac->ra_cap2.acc_cap.vbs = rfc->vbs;
+    rac->ra_cap2.acc_cap.vgcs = rfc->vgcs;
+    /*
+     * zero means that the same value for multislot parameters as given
+     * in an earlier access capabilities field within this IE apply
+     * also here.
+     */
+    rac->ra_cap2.acc_cap.v_ms_struct = FALSE;
+  }
+#endif
+
+#if defined FF_EOTD
+  if (rfc->assist_eotd OR rfc->based_eotd OR rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps)
+#else
+  if (rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps)
+#endif /* FF_EOTD */
+  {
+    cm3->v_pos_method = SUPPORTED;
+#if defined FF_EOTD
+    cm3->pos_method.assist_eotd = rfc->assist_eotd;
+    cm3->pos_method.based_eotd  = rfc->based_eotd;
+#endif /* FF_EOTD */
+    cm3->pos_method.assist_gps  = rfc->assist_gps;
+    cm3->pos_method.based_gps   = rfc->based_gps;
+    cm3->pos_method.conv_gps    = rfc->conv_gps;
+  }
+
+#if defined TI_PS_FF_REL99_AND_ABOVE
+  cm3->v_gsm700_cap = NOT_SUPPORTED;
+  cm3->umts_tdd_128 = NOT_SUPPORTED;
+  cm3->geran_feat_pack_1 = NOT_SUPPORTED;
+  cm3->v_ext_dtm_ms = NOT_SUPPORTED;
+  cm3->v_high_ms_cap = NOT_SUPPORTED;
+  cm3->geran_iu_mod_cap = NOT_SUPPORTED;
+  cm3->geran_feat_pack_2 = NOT_SUPPORTED;
+  cm3->gmsk_ms_pwr_prof = MS_PWR_PROF0;
+  cm3->psk8_ms_pwr_prof = MS_PWR_PROF0;
+  cm3->v_t_gsm400_struct = NOT_SUPPORTED;
+  cm3->v_t_gsm900_cap = NOT_SUPPORTED;
+#ifdef L1_SAIC
+  /* To support SAIC release 6 feature */
+  cm3->dl_adv_rx_per  = DL_ADVANC_RX_PERF_PHASE1_SUPPORT;
+#else
+  cm3->dl_adv_rx_per  = DL_ADVANC_RX_PERF_NOT_SUPPORT;
+#endif /* L1_SAIC */
+  cm3->dtm_enhance_cap = NOT_SUPPORTED;
+  cm3->v_dtm_high_ms = NOT_SUPPORTED;
+#ifdef FF_REPEATED_SACCH
+  cm3->rep_acch_cap = REP_SACCH_DL_FACCH;
+#else
+  cm3->rep_acch_cap = REP_DL_FACCH;
+#endif /* FF_REPEATED_SACCH */
+#endif /* TI_PS_FF_REL99_AND_ABOVE */
+
+#if defined(_SIMULATION_) && !defined(NTRACE)
+  rr_csf_trace_class1 (cm1);
+  rr_csf_trace_class2 (cm2);
+  rr_csf_trace_class3 (cm3);
+#endif  /* _SIMULATION_ && !NTRACE */
+  /*
+   * note: cm3->umts_fdd, cm3->umts_tdd, cm3->cdma2000, cm3->v_single_band and
+   * cm3->single_band are hard coded to 0 due to the lack of information about
+   * these features inside the T_rf_cap structure
+   */
+  return 0;
+}
+
+#else  /* Release 99 */
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_fit_capability      |
++--------------------------------------------------------------------+
+
+  PURPOSE : fit classmark 2 and 3 and radio access capabilities
+            depend on the value of 'std' and the readed values of
+            /gsm/com/rfcap file according to R99 specifications
+
+*/
+
+GLOBAL UBYTE rr_csf_fit_capability (void)
+{
+  GET_INSTANCE_DATA;
+  USHORT serving_cell;
+  T_rf_cap      *rfc = &rr_data->ms_data.rf_cap;
+#ifdef GPRS
+  T_ra_cap      *rac = &rr_data->ms_data.ra_cap;
+#ifdef TI_PS_FF_QUAD_BAND_SUPPORT
+  int i;
+#endif
+#endif
+  T_mob_class_1 *cm1 = &rr_data->ms_data.classmark1;
+  T_mob_class_2 *cm2 = &rr_data->ms_data.classmark2;
+  T_mob_class_3 *cm3 = &rr_data->ms_data.classmark3;
+
+  TRACE_FUNCTION ("rr_csf_fit_capability()");
+
+  if (rr_data->nc_data[SC_INDEX].bcch_status NEQ EMPTY)
+    serving_cell = rr_data->nc_data[SC_INDEX].arfcn;
+  else
+    serving_cell = (USHORT)-1;
+
+  memset (cm2, 0, sizeof(T_mob_class_2));
+  memset (cm3, 0, sizeof(T_mob_class_3));
+#ifdef GPRS
+  memset (rac, 0, sizeof(T_ra_cap));
+#endif
+
+
+  /* Set clasmark 1 fields */
+  cm1->rev_lev = REV_LEV_R99_SUPPORT; /* R99 mobile */
+  cm1->es_ind  = rfc->es_ind;
+  cm1->a5_1    = !rfc->a5_bits.a5_1;
+
+
+  /* Set classmark 2 fields */
+  cm2->rev_lev    = REV_LEV_R99_SUPPORT;
+  cm2->es_ind     = rfc->es_ind;
+  cm2->ps         = rfc->ps;
+  cm2->ss_screen  = rfc->ss_screen;
+  cm2->mt_pp_sms  = rfc->mt_pp_sms;
+  cm2->vbs        = rfc->vbs;
+  cm2->vgcs       = rfc->vgcs;
+  cm2->class3     = SUPPORTED;
+  cm2->lcsva      = rfc->lcsva;
+  cm2->ucs2_treat = rfc->ucs2_treat;
+  cm2->solsa      = rfc->solsa;
+  cm2->cmsp       = rfc->cmsp;
+  cm2->a5_1       = !rfc->a5_bits.a5_1;
+  cm2->a5_2       = rfc->a5_bits.a5_2;
+  cm2->a5_3       = rfc->a5_bits.a5_3;
+
+
+  /* Set classmark 3 fields */
+  cm3->a5_4               = rfc->a5_bits.a5_4;
+  cm3->a5_5               = rfc->a5_bits.a5_5;
+  cm3->a5_6               = rfc->a5_bits.a5_6;
+  cm3->a5_7               = rfc->a5_bits.a5_7;
+  cm3->ucs2_treat         = rfc->ucs2_treat;
+  cm3->ext_meas           = rfc->ext_meas;
+
+  /* Set multi slot capabilities */
+  if (rfc->rf_ms.gsm_ms_class)
+  {
+    cm3->v_ms_class = SUPPORTED;
+    cm3->ms_class   = rfc->rf_ms.gsm_ms_class;
+  }
+
+  /* Set MS measurement capability */
+  if (rfc->meas)
+  {
+    cm3->v_measurement       = SUPPORTED;
+    cm3->measurement.sms_val = rfc->sms_val;
+    cm3->measurement.sm_val  = rfc->sm_val;
+  }
+
+  /* Set MS positioning method */
+#if defined FF_EOTD
+  if (rfc->assist_eotd OR rfc->based_eotd OR rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps)
+#else
+  if (rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps)
+#endif /* FF_EOTD */
+  {
+    cm3->v_pos_method = SUPPORTED;
+#if defined FF_EOTD
+    cm3->pos_method.assist_eotd = rfc->assist_eotd;
+    cm3->pos_method.based_eotd  = rfc->based_eotd;
+#endif /* FF_EOTD */
+    cm3->pos_method.assist_gps  = rfc->assist_gps;
+    cm3->pos_method.based_gps   = rfc->based_gps;
+    cm3->pos_method.conv_gps    = rfc->conv_gps;
+  }
+
+
+#ifdef GPRS
+  /* Set Radio Access Capability info */
+  rac->ra_cap_values.v_acc_cap             = YES;
+  rac->ra_cap_values.acc_cap.v_a5_bits = SUPPORTED;
+
+  rac->ra_cap_values.acc_cap.rev99     = RELEASE99;
+  rac->ra_cap_values.acc_cap.es_ind    = rfc->es_ind;
+  rac->ra_cap_values.acc_cap.ps        = rfc->ps;
+  rac->ra_cap_values.acc_cap.vbs       = rfc->vbs;
+  rac->ra_cap_values.acc_cap.vgcs      = rfc->vgcs;
+  rac->ra_cap_values.acc_cap.a5_bits   = rfc->a5_bits;
+  rac->ra_cap_values.acc_cap.compact   = rfc->compact;
+
+  rac->ra_cap_values.acc_cap.v_ms_struct                = SUPPORTED;
+  rac->ra_cap_values.acc_cap.ms_struct.v_ecsd_ms_class  = NOT_SUPPORTED;/*CR 637 */
+  rac->ra_cap_values.acc_cap.ms_struct.v_hscsd_ms_class = NOT_SUPPORTED;/*CR 637 */
+  rac->ra_cap_values.acc_cap.ms_struct.v_sms_sm_value   = NOT_SUPPORTED;/*CR 637 */
+
+  rac->c_ra_cap_r = NO;
+  rac->v_ra_cap_r = NO;
+
+#endif
+
+#ifdef TI_PS_FF_QUAD_BAND_SUPPORT
+  /* Set the MS multiband capabilities */
+  switch (std)
+  {
+    case STD_900:
+      cm3->mb_value = MB_GSM900;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_P;
+#endif
+      break;
+    case STD_EGSM:
+      cm2->egsm = SUPPORTED;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+#endif
+      /* No break */
+    case STD_900_1900:
+    case STD_850_900_1900:
+      cm3->mb_value = MB_EGSM;
+      if ((!INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+        AND (!INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)))
+      {
+        cm2->egsm = SUPPORTED;
+      }
+      break;
+    case STD_1800:
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+#endif
+      /* NO break */
+    case STD_850_1800:
+      cm3->mb_value = MB_DCS1800;
+      break;
+    case STD_DUAL:
+      cm3->mb_value = MB_DUAL;
+#ifdef GPRS
+      rac->v_ra_cap_r = YES;
+      rac->c_ra_cap_r++;
+      rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES;
+
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_P;
+      }
+      else
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_P;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+      }
+
+      rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+    case STD_DUAL_EGSM:
+    case STD_850_900_1800:
+      /* note: incase of 1800 band, the FC bit shall be set to 0 */
+      if((!INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+        AND (!INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)))
+        cm2->egsm = SUPPORTED;
+      cm3->mb_value = MB_DUAL_EXT;
+
+#ifdef GPRS
+      rac->v_ra_cap_r = YES;
+      rac->c_ra_cap_r++;
+      rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES;
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E;
+      }
+      else
+      {
+        if(INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))
+        {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_850;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        }
+        else
+        {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        }
+      }
+
+      rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+     break;
+
+    case STD_1900:
+    case STD_850:
+    case STD_DUAL_US:
+      /* no break; go through */
+    default:
+      cm3->mb_value = MB_NO_EUROPEAN_BAND;
+      break;
+  }
+#else
+  /* Set the MS multiband capabilities */
+  switch (std)
+  {
+    case STD_900:
+      cm3->mb_value = MB_GSM900;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_P;
+#endif
+      break;
+    case STD_EGSM:
+      cm2->egsm = SUPPORTED;
+      cm3->mb_value = MB_EGSM;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+#endif
+      break;
+    case STD_1800:
+      cm3->mb_value = MB_DCS1800;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+#endif
+      break;
+    case STD_DUAL:
+      cm3->mb_value = MB_DUAL;
+#ifdef GPRS
+      rac->v_ra_cap_r = YES;
+      rac->c_ra_cap_r++;
+      rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES;
+      
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+	  {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_P;
+      }
+      else
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_P;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+      }
+
+      rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+    case STD_DUAL_EGSM:
+      /* note: incase of 1800 band, the FC bit shall be set to 0 */ 
+      if(!INRANGE(LOW_CHANNEL_1800,rr_data->nc_data[SC_INDEX].arfcn,HIGH_CHANNEL_1800))
+      cm2->egsm = SUPPORTED;
+      cm3->mb_value = MB_DUAL_EXT;
+
+#ifdef GPRS
+      rac->v_ra_cap_r = YES;
+	  rac->c_ra_cap_r++;
+      rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES;
+
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+      {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E;
+      }
+      else
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+      }
+
+      rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+     break;
+
+    case STD_1900:
+    case STD_850:
+    case STD_DUAL_US:
+      /* no break; go through */
+    default:
+      cm3->mb_value = MB_NO_EUROPEAN_BAND;
+      break;
+  }
+#endif
+
+  /* Set MS power classes info */
+  if (rfc->bands & 0x80)
+  {
+    TRACE_ERROR("R-GSM not supported by PS software");
+    /* note: cm3->v_rgsm_class (and cm3->rgsm_class) are hard coded to 0 */
+  }
+  if (rfc->bands & 0x60)
+  {
+    TRACE_ERROR("GSM 400 not supported by PS software");
+    /* note: cm3->v_gsm400_struct (and cm3->gsm400_struct) are hard coded to 0 */
+  }
+
+  switch (std)
+  {
+    case STD_900:
+    case STD_EGSM:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+      cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+#endif
+      break;
+
+    case STD_1800:
+      /* single band => only radio_cap_1 */
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class;
+      cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+#endif
+      break;
+
+    case STD_DUAL:
+    case STD_DUAL_EGSM:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+      cm3->v_radio_cap_2 = TRUE;
+      cm3->radio_cap_2 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class;
+      /* note: in case the sc is´nt set, it is out of range */
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+        cm2->rf_pow_cap = cm3->radio_cap_2 - 1;
+      else
+        cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      if (rac->ra_cap_values.acc_tech_typ EQ ACC_GSM_1800)
+      {
+        rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+      }
+      else
+      {
+        rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2;
+      }
+#endif
+      break;
+
+    case STD_1900:
+      cm3->v_pcs1900_cap = SUPPORTED;
+      cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class;
+      cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+      rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+#endif
+      break;
+
+    case STD_850:
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+#ifdef GPRS
+      rac->ra_cap_values.acc_tech_typ = ACC_GSM_850;
+      rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+#endif
+      break;
+
+    case STD_DUAL_US:
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      cm3->v_pcs1900_cap = SUPPORTED;
+      cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class;
+      
+	  /* note: in case the sc is´nt set, it is out of range */
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+        cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+      else
+        cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+
+#ifdef GPRS
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+      {
+        cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_850;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+      }
+      else
+      {
+        cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_850;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+      }
+	  rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+
+#ifdef TI_PS_FF_QUAD_BAND_SUPPORT
+    case STD_900_1900:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+      cm3->v_pcs1900_cap = SUPPORTED;
+      cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class;
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+        cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+      else
+        cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+      }
+      else
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+      }
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+
+    case STD_850_1800:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class;
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+        cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+      else
+        cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+#ifdef GPRS
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_850;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+      }
+      else
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_850;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+      }
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+
+    case STD_850_900_1900:
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      cm3->v_pcs1900_cap = SUPPORTED;
+      cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class;
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+     /* note: in case the sc is´nt set, it is out of range */
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+        cm2->rf_pow_cap = cm3->pcs1900_cap - 1;
+      else if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))
+        cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+      else
+        cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+
+#ifdef GPRS
+      if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900))
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_850;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+      }
+      else
+      {
+        if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))
+        {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_850;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+          rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+          rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+        }
+        else
+        {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900;
+          rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+          rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap;
+        }
+      }
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+    case STD_850_900_1800:
+      cm3->v_radio_cap_1 = TRUE;
+      cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class;
+      cm3->v_radio_cap_2 = TRUE;
+      cm3->radio_cap_2 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class;
+      cm3->v_gsm850_cap = SUPPORTED;
+      cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class;
+      /* note: in case the sc is´nt set, it is out of range */
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+        cm2->rf_pow_cap = cm3->radio_cap_2 - 1;
+      else if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))
+        cm2->rf_pow_cap = cm3->gsm850_cap - 1;
+      else
+        cm2->rf_pow_cap = cm3->radio_cap_1 - 1;
+#ifdef GPRS
+      if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800))
+      {
+        rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+        rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E;
+        rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2;
+        rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+      }
+      else
+      {
+        if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))
+        {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_850;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+          rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap;
+          rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2;
+        }
+        else
+        {
+          rac->ra_cap_values.acc_tech_typ = ACC_GSM_E;
+          rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800;
+          rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1;
+          rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2;
+        }
+      }
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits      = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct    = NOT_SUPPORTED;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+#endif
+      break;
+#endif
+
+    default:
+      break;
+  }
+
+  cm1->rf_pow_cap = cm2->rf_pow_cap;
+
+#if defined(_SIMULATION_) && defined(RFCAP_TEST)
+  rr_csf_trace_power ();
+#endif  /* RFCAP_TEST*/
+
+
+/*Set 8psk capability in uplink for EGPRS*/
+#if defined(FF_EGPRS)
+
+  /*Initialize with 8psk is not supported in uplink*/
+  cm3->v_egde_struct = NOT_SUPPORTED;
+  rac->ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+  rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED;
+
+  switch (std)
+  {
+    case STD_900:
+    case STD_EGSM:
+    case STD_850:
+      if (rfc->mod)
+      {
+        if (rfc->rf_power.egde_pow1)
+        {
+          cm3->v_egde_struct = TRUE;
+          cm3->egde_struct.mod = SUPPORTED;
+          cm3->egde_struct.v_egde_pow1 = TRUE;
+          cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1;
+          rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE;
+          rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1;
+          TRACE_EVENT_P1 ("1: 8PSK SUPPORTED (EGPRS) POWER CLASS E1 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap);
+        }
+      }
+      break;
+    case STD_1800:
+    case STD_1900:
+      if (rfc->mod)
+      {
+        if (rfc->rf_power.egde_pow2)
+        {
+          cm3->v_egde_struct = TRUE;
+          cm3->egde_struct.mod = SUPPORTED;
+          cm3->egde_struct.v_egde_pow2 = TRUE;
+          cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2;
+          rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE;
+          rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2;
+          TRACE_EVENT_P1 ("2: 8PSK SUPPORTED (EGPRS) POWER CLASS E2 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap);
+        }
+      }
+      break;
+    case STD_DUAL:
+    case STD_DUAL_EGSM:
+    case STD_DUAL_US:
+      if ((rac->ra_cap_values.acc_tech_typ EQ ACC_GSM_1800) OR (rac->ra_cap_values.acc_tech_typ EQ ACC_GSM_1900))
+      {
+        if (rfc->mod)
+        {
+          if (rfc->rf_power.egde_pow2)
+          {
+            /*8psk is supported in uplink in 1800/1900 BAND*/
+            cm3->v_egde_struct = TRUE;
+            cm3->egde_struct.mod = SUPPORTED;
+            cm3->egde_struct.v_egde_pow2 = TRUE;
+            cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2;
+            rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE;
+            rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2;
+            TRACE_EVENT_P1 ("3: 8PSK SUPPORTED (EGPRS) POWER CLASS E2 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap);
+          }
+          if (rfc->rf_power.egde_pow1)
+          {
+            /*Set 8psk capability for 850/900 BAND*/
+            cm3->v_egde_struct = TRUE;
+            cm3->egde_struct.mod = SUPPORTED;
+            cm3->egde_struct.v_egde_pow1 = TRUE;
+            cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1;
+            rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE;
+            rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1;
+            TRACE_EVENT_P1 ("4: 8PSK SUPPORTED (EGPRS) POWER CLASS E1 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap);
+          }
+        }
+      }
+      else
+      {
+        if (rfc->mod)
+        {
+          if (rfc->rf_power.egde_pow1)
+          {
+            /*8psk is supported in uplink in 1800/1900*/
+            cm3->v_egde_struct = TRUE;
+            cm3->egde_struct.mod = SUPPORTED;
+            cm3->egde_struct.v_egde_pow1 = TRUE;
+            cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1;
+            rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE;
+            rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1;
+            TRACE_EVENT_P1 ("5: 8PSK SUPPORTED (EGPRS) POWER CLASS E1 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap);
+          }
+          if (rfc->rf_power.egde_pow2)
+          {
+           /*Set 8psk capability for 850/900*/
+            cm3->v_egde_struct = TRUE;
+            cm3->egde_struct.mod = SUPPORTED;
+            cm3->egde_struct.v_egde_pow2 = TRUE;
+            cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2;
+            rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE;
+            rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2;
+            TRACE_EVENT_P1 ("6: 8PSK SUPPORTED (EGPRS) POWER CLASS E2 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap);
+          }
+        }
+      }
+      break;
+    default:
+      break;
+  }
+#endif  /* FF_EGPRS */
+
+  if (rfc->rf_ms.dtm_g)
+  {
+    cm3->v_dtm_ms = SUPPORTED;
+    cm3->dtm_ms.mac_support =  rfc->mac_support;
+    cm3->dtm_ms.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class;
+#ifdef GPRS
+    rac->ra_cap_values.acc_cap.ms_struct.v_dtm_struct = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class;
+    rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.mac_support = rfc->mac_support;
+#endif
+
+#if defined(FF_EGPRS)
+    if (rfc->rf_ms.dtm_e)
+    {
+      cm3->dtm_ms.v_dtm_e_ms_class = SUPPORTED;
+      cm3->dtm_ms.dtm_e_ms_class = rfc->rf_ms.dtm_e_ms_class;
+#ifdef GPRS
+      rac->ra_cap_values.acc_cap.ms_struct.v_dtm_struct = SUPPORTED;
+      rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.v_dtm_e_ms_class = SUPPORTED;
+      rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.dtm_e_ms_class =  rfc->rf_ms.dtm_e_ms_class;
+#endif
+    }
+#endif  /* FF_EGDE */
+  }
+
+#ifdef GPRS
+  
+#if 0  /* CR 637 */
+  if (rfc->rf_ms.hscsd_ms_class)
+  {
+    rac->ra_cap_values.acc_cap.v_ms_struct = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.v_hscsd_ms_class = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.hscsd_ms_class = rfc->rf_ms.hscsd_ms_class;
+  }
+#endif
+
+  if (rfc->rf_ms.gprs_ms_class)
+  {
+    rac->ra_cap_values.acc_cap.ms_struct.v_gprs_struct = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.gprs_struct.gprs_ms_class = rfc->rf_ms.gprs_ms_class;
+    rac->ra_cap_values.acc_cap.ms_struct.gprs_struct.gprs_eda = rfc->gprs_eda;
+  }
+
+
+  if (rfc->meas)
+  {
+    rac->ra_cap_values.acc_cap.ms_struct.v_sms_sm_value = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.sms_sm_value.sms_val = rfc->sms_val;
+    rac->ra_cap_values.acc_cap.ms_struct.sms_sm_value.sm_val = rfc->sm_val;
+  }
+
+#if 0 /* CR 637 */
+  if (rfc->rf_ms.ecsd_ms_class)
+  {
+    rac->ra_cap_values.acc_cap.v_ms_struct = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.v_ecsd_ms_class = SUPPORTED;
+    rac->ra_cap_values.acc_cap.ms_struct.ecsd_ms_class = rfc->rf_ms.ecsd_ms_class;
+  }
+#endif
+
+#if defined(FF_EGPRS)
+  if (rfc->rf_ms.egprs_ms_class)
+  {
+    cm3->v_edge_ms_class = TRUE;
+    cm3->edge_ms_class = rfc->rf_ms.egprs_ms_class;
+    rac->ra_cap_values.acc_cap.ms_struct.v_egprs_struct = TRUE;
+    rac->ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_ms_class = rfc->rf_ms.egprs_ms_class;
+    rac->ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_eda = rfc->egprs_eda;
+  }
+#endif
+
+  if ((rac->c_ra_cap_r > 0) AND rac->ra_cap_values.acc_cap.v_ms_struct)
+  {
+    rac->v_ra_cap_r = TRUE;
+    rac->ra_cap_r[0].ra_cap_values.acc_cap.rev99 = RELEASE99; 
+
+
+    rac->ra_cap_r[0].ra_cap_values.acc_cap.compact = rfc->compact;
+    rac->ra_cap_r[0].ra_cap_values.acc_cap.es_ind = rfc->es_ind;
+    rac->ra_cap_r[0].ra_cap_values.acc_cap.ps = rfc->ps;
+    rac->ra_cap_r[0].ra_cap_values.acc_cap.vbs = rfc->vbs;
+    rac->ra_cap_r[0].ra_cap_values.acc_cap.vgcs = rfc->vgcs;
+
+#if defined(FF_EGPRS)
+    if (rfc->rf_ms.egprs_ms_class)
+    {
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.ms_struct.v_egprs_struct = TRUE;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_ms_class = rfc->rf_ms.egprs_ms_class;
+      rac->ra_cap_r[0].ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_eda = rfc->egprs_eda;
+    }
+#endif
+
+  }
+#endif
+
+#if defined TI_PS_FF_REL99_AND_ABOVE
+  /* To support SAIC release 6 feature */
+  cm3->v_gsm700_cap = NOT_SUPPORTED;
+  cm3->umts_tdd_128 = NOT_SUPPORTED;
+  cm3->geran_feat_pack_1 = NOT_SUPPORTED;
+  cm3->v_ext_dtm_ms = NOT_SUPPORTED;
+  cm3->v_high_ms_cap = NOT_SUPPORTED;
+  cm3->geran_iu_mod_cap = NOT_SUPPORTED;
+  cm3->geran_feat_pack_2 = NOT_SUPPORTED;
+  cm3->gmsk_ms_pwr_prof = MS_PWR_PROF0;
+  cm3->psk8_ms_pwr_prof = MS_PWR_PROF0;
+  cm3->v_t_gsm400_struct = NOT_SUPPORTED;
+  cm3->v_t_gsm900_cap = NOT_SUPPORTED;
+  cm3->dtm_enhance_cap = NOT_SUPPORTED;
+  cm3->v_dtm_high_ms = NOT_SUPPORTED;
+#ifdef L1_SAIC
+  /* To support SAIC release 6 feature */
+  cm3->dl_adv_rx_per  = DL_ADVANC_RX_PERF_PHASE1_SUPPORT;
+#else
+  cm3->dl_adv_rx_per  = DL_ADVANC_RX_PERF_NOT_SUPPORT;
+#endif /* L1_SAIC */
+#ifdef FF_REPEATED_SACCH
+  cm3->rep_acch_cap = REP_SACCH_DL_FACCH;
+#else
+  cm3->rep_acch_cap = REP_DL_FACCH;
+#endif /* FF_REPEATED_SACCH */
+#endif /* TI_PS_FF_REL99_AND_ABOVE */
+
+#if defined(_SIMULATION_) && !defined(NTRACE)
+  rr_csf_trace_class1 (cm1);
+  rr_csf_trace_class2 (cm2);
+  rr_csf_trace_class3 (cm3);
+#endif  /* _SIMULATION_ && !NTRACE */
+  /*
+   * note: cm3->umts_fdd, cm3->umts_tdd, cm3->cdma2000, cm3->v_single_band and
+   * cm3->single_band are hard coded to 0 due to the lack of information about
+   * these features inside the T_rf_cap structure
+   */
+  return 0;
+}
+#endif
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : RX_Enable                  |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function enables reporting of RX level.
+
+*/
+static T_VOID_FUNC rx_driver_entry = NULL;
+static UBYTE       rx_act_value    = 0;
+static UBYTE       rx_act_qual     = RX_QUAL_UNAVAILABLE;
+#ifdef FF_PS_RSSI
+static UBYTE       rx_act_rxlev_access_min = RX_ACCE_UNAVAILABLE;
+#endif
+
+/*lint -esym(765,RX_Enable) | used by RX driver */
+/*lint -esym(714,RX_Enable) | used by RX driver */
+GLOBAL void RX_Enable (T_VOID_FUNC rx_indication)
+{
+  /*
+   *   store callback function
+   */
+  rx_driver_entry = rx_indication;
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : RX_SetValue                |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function stores a new fieldstrength value and
+            informs the RX driver if possible about a change.
+
+*/
+
+/*
+ * for reduce number of indications during dedicated mode
+ */
+static UBYTE rssi_dedi_counter = 0;
+
+/*
+ * Minimum RSSI difference for indication to MMI
+ */
+#define RSSI_MIN_DIFFERENCE  5
+#define RSSI_MIN_LEVEL       10
+
+
+#ifdef FF_PS_RSSI
+GLOBAL void RX_SetValue (UBYTE new_value, UBYTE new_qual, UBYTE new_access)
+#else
+GLOBAL void RX_SetValue (UBYTE new_value)
+#endif
+{
+  GET_INSTANCE_DATA;
+  UBYTE rssi_delta;
+
+#ifdef FF_PS_RSSI
+  rx_act_rxlev_access_min = new_access;
+#endif
+
+  if (rx_driver_entry EQ NULL)
+  {
+    rx_act_value  = new_value;
+#ifdef FF_PS_RSSI
+    rx_act_qual   = new_qual;
+#endif
+  }
+  else /*if a callback is installed*/
+  {
+
+    /*
+     * Compute delta compared to last MMI value
+     */
+    rssi_delta = ( new_value >= rx_act_value ?
+                   ( new_value - rx_act_value ) :
+                   ( rx_act_value - new_value )
+                 );
+      /*
+       * if difference greather than defined threshold
+       * rx_qual is available in dedicated state only
+       * Change in RX_QUAL
+       */
+    if ((rssi_delta >= RSSI_MIN_DIFFERENCE) OR (new_value < RSSI_MIN_LEVEL) 
+#ifdef FF_PS_RSSI
+        OR (new_qual NEQ  rx_act_qual)
+#endif
+      )
+    {
+
+      if ( GET_STATE (STATE_ATT) NEQ ATT_DEDICATED )
+      {
+        rx_act_value = new_value;
+#ifdef FF_PS_RSSI
+        rx_act_qual  = new_qual;
+#endif
+        (*rx_driver_entry)();
+      }
+      else
+      {
+        /*
+         * in dedicated mode take only each 16 the attempt
+         * equal 8 seconds
+         */
+        if (!((rssi_dedi_counter ++ ) & 0x0F ))
+        {
+          /*
+           * New RSSI to be forwarded
+           */
+          rx_act_value = new_value;
+#ifdef FF_PS_RSSI
+          rx_act_qual  = new_qual;
+#endif
+          (*rx_driver_entry)();
+        }
+      } 
+    }
+  }
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : RX_GetValue                |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function simulates a low level driver call to get
+            the actual fieldstrength.
+
+*/
+/*lint -esym(765,RX_GetValue) | used by RX driver */
+/*lint -esym(714,RX_GetValue) | used by RX driver */
+GLOBAL USHORT RX_GetValue (void)
+{
+  USHORT rx_level;
+
+  rx_level = (USHORT)rx_act_value;
+
+  return rx_level;
+}
+
+#ifdef FF_PS_RSSI
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : RX_GetRxLevAccessMin       |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function simulates a low level driver call to get
+            the minimum access level.
+
+*/
+GLOBAL UBYTE RX_GetRxLevAccessMin (void)
+{
+  return rx_act_rxlev_access_min;
+}
+#endif
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : RX_SetRxQual               |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function simulates a low level driver call to set
+            the actual RXQUAL value.
+
+*/
+/*lint -esym(765,RX_SetRxQual) | used by GRR */
+/*lint -esym(714,RX_SetRxQual) | used by GRR */
+GLOBAL void RX_SetRxQual (UBYTE new_rx_qual)
+{
+  rx_act_qual = new_rx_qual;
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : RX_GetRxQual               |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function simulates a low level driver call to get
+            the actual RXQUAL value.
+
+*/
+/*lint -esym(765,RX_GetRxQual) | used by RX driver */
+/*lint -esym(714,RX_GetRxQual) | used by RX driver */
+GLOBAL UBYTE RX_GetRxQual (void)
+{
+  return rx_act_qual;
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_get_found_channels      |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function is a little bit dirty solution to get
+            the BCCH channel numbers of a PLMN available list.
+
+*/
+#if 0
+GLOBAL USHORT * rr_get_found_channels (void)
+{
+  static USHORT found_channels[MAX_PLMN];
+  int i;
+  for (i=0; i<MAX_PLMN; i++)
+    found_channels[i] = rr_data->sc_data.found[i].arfcn;
+  return found_channels;
+}
+#endif
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_get_bcch_channel        |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function is a little bit dirty solution to get
+            the BCCH channel numbers of the current PLMN.
+
+*/
+#if 0
+GLOBAL USHORT rr_get_bcch_channel (void)
+{
+  return rr_data->nc_data[SC_INDEX].arfcn;
+}
+#endif
+
+/*
+ *  These functions (get_network_meas() & get_bcch_chan_list()) should only
+ *  temporary defined here.
+ */
+/*lint -esym(765,get_network_meas) | used by SIM  */
+/*lint -esym(714,get_network_meas) | used by SIM  */
+GLOBAL UBYTE get_network_meas (UBYTE * chan_list)
+{
+  GET_INSTANCE_DATA;
+#if defined (_SIMULATION_)
+  /*
+   * fixed values for the windows simulation
+   */
+  memset (chan_list, 0, 16);
+  chan_list [0] = 0x32;
+  chan_list [1] = 0x16;
+  chan_list [2] = 0x7E;
+  chan_list [3] = 0x52;
+  chan_list [4] = 0x37;
+  return 1;
+#else /* _SIMULATION_ */
+  switch (GET_STATE (STATE_ATT))
+  {
+    case ATT_IDLE:
+      memset (chan_list, 0, 16);
+      chan_list [0] =  rr_data->nc_data[SC_INDEX].rxlev;
+      return 1;
+    case ATT_DEDICATED:
+      memcpy (chan_list, dl_get_sacch_buffer(), 16);
+      return 1;
+    default:
+      return 0;
+  }
+#endif /* _SIMULATION_ */
+}
+
+#ifdef REL99
+/*
++--------------------------------------------------------------------+
+| PROJECT : GPRS EDGE          MODULE  : RR_CSF                      |
+| STATE   : code               ROUTINE : get_msc_release_version           |
++--------------------------------------------------------------------+
+
+  PURPOSE : use to get the MSC release version of the serving cell.
+*/
+
+GLOBAL void get_msc_release_version(UBYTE* mscr)
+{
+  GET_INSTANCE_DATA;
+  T_NC_DATA * rrd;
+  rrd = &rr_data->nc_data[SC_INDEX];
+  *mscr = rrd->mscr_flag;
+}
+#endif
+
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : get_bcch_chan_list      |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function returns the network measurement results
+            in the SIM TOOLKIT Format.
+
+*/
+#if defined (_SIMULATION_)
+/*
+ * predefined values for windows simulation
+ */
+static USHORT win_list[MAX_NEIGHBOURCELLS] = {  124, 512, 17, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF,
+                                                0xFFFF } ;
+#endif  /* _SIMULATION_ */
+/*lint -esym(765,get_bcch_chan_list) | used by SIM  */
+/*lint -esym(714,get_bcch_chan_list) | used by SIM  */
+GLOBAL UBYTE get_bcch_chan_list (stk_data_type * out_stk_data)
+{
+  GET_INSTANCE_DATA;
+  UBYTE i;
+  UBYTE value;
+#if defined (_SIMULATION_)
+  USHORT * ncell_list = win_list;
+#else  /* _SIMULATION_ */
+  USHORT * ncell_list = rr_data->act_ncell_list;
+#endif  /* _SIMULATION_ */
+
+#if !defined (_SIMULATION_)
+  switch (GET_STATE (STATE_ATT))
+  {
+    case ATT_IDLE:
+    case ATT_DEDICATED:
+#endif  /* !_SIMULATION_ */
+
+      /*
+       * clear output parameter
+       */
+      memset (out_stk_data->stk_parameter, 0, sizeof (out_stk_data->stk_parameter));
+      for (i=0;i<MAX_NEIGHBOURCELLS;i++)
+      {
+        if (ncell_list[i] EQ NOT_PRESENT_16BIT)
+        {
+          /*
+           * if no further channel is available
+           * calculate length in bytes
+           * number of channels a 10 bit
+           */
+          out_stk_data->stk_length = (i*10+7)/8;
+          return 1;
+        }
+        /*
+         * channel is available
+         * then use basic CCD function to add to bitstream
+         */
+        value = ncell_list[i] >> 8;
+        ccd_codeByte (out_stk_data->stk_parameter, (USHORT)(i*10),  2, value);
+        value = ncell_list[i] & 0xFF;
+        ccd_codeByte (out_stk_data->stk_parameter, (USHORT)(i*10+2), 8, value);
+      }
+      /*
+       * if no end indicator has been found
+       * and all parameters are channels
+       * calculate length in bytes
+       * number of channels a 10 bit.
+       */
+      out_stk_data->stk_length = (i*10+7)/8;
+      return 1;
+#if !defined (_SIMULATION_)
+    default:
+      return 0;
+  }
+#endif  /* _SIMULATION_ */
+}
+
+
+#if defined(_SIMULATION_FFS_)
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6103)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_ffs_init            |
++--------------------------------------------------------------------+
+
+  PURPOSE :
+
+*/
+
+LOCAL const char rr_white_list_name[] = "/gsm/l3/rr_white_list";
+LOCAL const char rr_black_list_name[] = "/gsm/l3/rr_black_list";
+LOCAL const char rr_lower_rxlev_thr_name[] = "/gsm/l3/rr_lower_rxlev_thr";
+LOCAL const char rr_medium_rxlev_thr_name[] = "/gsm/l3/rr_medium_rxlev_thr";
+LOCAL const char rr_upper_rxlev_thr_name[] = "/gsm/l3/rr_upper_rxlev_thr";
+LOCAL const char rr_shield_mcc_name[] = "/gsm/l3/shield";
+
+GLOBAL void rr_csf_ffs_init(void)
+{
+  TRACE_FUNCTION ("rr_csf_ffs_init()");
+
+  /* If MM has to create the directories for FFS, there is no point
+   * in carry on with the initialisation
+   */
+  rr_csf_check_ffs_dirs();
+
+  /* Read white list from FFS */
+  rr_csf_read_white_list();
+
+  /* Read Black List from FFS */
+  rr_csf_read_black_list();
+
+  /* Read RXlevel thresholds from FFS */
+  rr_csf_read_rxlev_thr();
+}
+
+
+/*
++------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                   |
+| STATE   : code                ROUTINE : rr_csf_write_white_list  |
++------------------------------------------------------------------+
+
+  PURPOSE : This function writes the White list information to FFS.
+            CSI-LLD - 4.1.2.2.4
+*/
+
+GLOBAL void rr_csf_write_white_list(T_CS_WHITE_LIST *white_list)
+{
+  TRACE_FUNCTION ("rr_csf_write_white_list()");
+  
+#if defined(_SIMULATION_)
+  memcpy(&win_white_list,white_list,sizeof(T_CS_WHITE_LIST));
+#else
+  rr_csf_check_ffs_dirs();
+  rr_csf_handle_ffs_write_result(ffs_file_write(rr_white_list_name,
+                                                white_list,
+                                                sizeof(T_CS_WHITE_LIST),
+                                                FFS_O_CREATE | FFS_O_RDWR));
+#endif
+ 
+  TRACE_EVENT("White List written to FFS");
+}
+
+/*
++-----------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                  |
+| STATE   : code                ROUTINE : rr_csf_read_white_list  |
++-----------------------------------------------------------------+
+
+  PURPOSE : This function read the White list information from FFS.
+            CSI-LLD - 4.1.2.2.5
+*/
+
+GLOBAL void rr_csf_read_white_list(void)
+{
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_read_white_list()");
+
+  TRACE_EVENT("Read White List from FFS");
+
+#if defined(_SIMULATION_)
+  memcpy(&rr_data->cs_data.white_list,&win_white_list,sizeof(T_CS_WHITE_LIST));
+#else
+  rr_csf_check_ffs_dirs();
+  if(!rr_csf_handle_ffs_read_result(ffs_file_read(rr_white_list_name,
+                                             &rr_data->cs_data.white_list,
+                                             sizeof(T_CS_WHITE_LIST))))
+  {
+    /* In case of read error, reset the White List */
+    cs_clear_white_list(CLR_WHITE_LIST_RAM);
+  }
+#endif
+}
+
+/*
++-----------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                        |
+| STATE   : code                ROUTINE : rr_csf_write_black_list       |
++-----------------------------------------------------------------------+
+
+  PURPOSE : This function wirtes "Black List" information to FFS. 
+            In case of windows simulation environment, "Black List" is 
+            stored to simulated FFS area. 
+            This function is called during switch off.
+            CSI-LLD section:4.1.1.5.3
+*/
+
+GLOBAL void rr_csf_write_black_list(T_LIST *black_list)
+{
+  TRACE_FUNCTION ("rr_csf_write_black_list()");
+
+#if defined(_SIMULATION_)
+  memcpy(&win_black_list[0],black_list,MAX_REGIONS*sizeof(T_LIST));
+#else
+  rr_csf_check_ffs_dirs();
+  rr_csf_handle_ffs_write_result(ffs_file_write (rr_black_list_name,
+                                                 black_list,
+                                                 MAX_REGIONS*sizeof(T_LIST),
+                                                 FFS_O_CREATE | FFS_O_RDWR));
+#endif
+
+  TRACE_EVENT("Black List written to FFS");
+}
+
+
+/*
++------------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                         |
+| STATE   : code                ROUTINE : rr_csf_read_black_list         |
++------------------------------------------------------------------------+
+
+  PURPOSE : This function copies  "Black List" information from FFS to RR
+            internal "Black List" data structures. In case of windows 
+            simulation environment, "Black List" is read from simulated FFS 
+            area. This function is called after power on
+            Cell Selection Improvements-LLD section:4.1.1.5.4
+*/
+
+GLOBAL void rr_csf_read_black_list(void)
+{
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_read_black_list()");
+
+  TRACE_EVENT("Read Black List from FFS");
+
+#if defined(_SIMULATION_)
+  memcpy(&rr_data->cs_data.black_list.list[0],&win_black_list[0],
+         MAX_REGIONS*sizeof(T_LIST));
+#else
+  rr_csf_check_ffs_dirs();
+  if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_black_list_name,
+                                               &rr_data->cs_data.black_list.list[0],
+                                               MAX_REGIONS*sizeof(T_LIST))))
+  {
+    /* In case of read error, reset the Black List */
+    cs_clear_black_list(CLR_BLACK_LIST_RAM);
+  }
+#endif
+} 
+
+/*
++-----------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                        |
+| STATE   : code                ROUTINE : rr_csf_write_rxlev_thr       |
++-----------------------------------------------------------------------+
+
+  PURPOSE : This function wirtes "RXLevel Threshold" information to FFS. 
+            In case of windows simulation environment, "RXLevel Threshold" is 
+            stored to simulated FFS area. 
+            This function is called during dynamic configuration.
+*/
+
+GLOBAL void rr_csf_write_rxlev_thr(UBYTE rxt, SHORT valno, char* val[MAX_NUM_BANDS])
+{
+  GET_INSTANCE_DATA;
+  UBYTE i, rxlev_thr_val; 
+  UBYTE *rxlev_thr = NULL;
+  #if defined(_SIMULATION_)
+  UBYTE *win_rxlev_thr = NULL;
+  #endif
+  const char *rxlev_thr_name, *rxlev_thr_string;
+  rxlev_thr_name = NULL;
+  rxlev_thr_string = NULL;
+  TRACE_FUNCTION ("rr_csf_write_rxlev_thr()");
+
+  switch(rxt)
+  {
+    case U_RXT: rxlev_thr_string = "Upper";
+                rxlev_thr = &rr_data->dyn_config.upper_rxlev_thr[0];
+                rxlev_thr_name = &rr_upper_rxlev_thr_name[0];
+#if defined(_SIMULATION_)
+                win_rxlev_thr = &win_upper_rxlev_thr[0];
+#endif
+                break;
+    case M_RXT: rxlev_thr_string = "Medium";
+                rxlev_thr = &rr_data->dyn_config.medium_rxlev_thr[0];
+                rxlev_thr_name = &rr_medium_rxlev_thr_name[0];
+#if defined(_SIMULATION_)
+                win_rxlev_thr = &win_medium_rxlev_thr[0];
+#endif
+                break;
+    case L_RXT: rxlev_thr_string = "Lower";
+                rxlev_thr = &rr_data->dyn_config.lower_rxlev_thr[0];
+                rxlev_thr_name = &rr_lower_rxlev_thr_name[0];
+#if defined(_SIMULATION_)
+                win_rxlev_thr = &win_lower_rxlev_thr[0];
+#endif
+                break;
+    default:
+      return;
+  }
+  
+  for( i=0 ; i<valno ; i++ )
+  {
+    rxlev_thr_val = atoi(val[i]);
+    if( rxlev_thr_val > 0 AND rxlev_thr_val <= 63 )
+    {
+        rxlev_thr[i] = rxlev_thr_val;
+    }
+    else
+    {
+        TRACE_ERROR ("[PEI_CONFIG]: RxLev Threshold(0-63)-Incorrect Range");
+    }
+  }
+#if defined(_SIMULATION_)
+    memcpy(win_rxlev_thr,rxlev_thr,MAX_NUM_BANDS*sizeof(UBYTE));
+#else
+    rr_csf_check_ffs_dirs();
+    rr_csf_handle_ffs_write_result(ffs_file_write(rxlev_thr_name,
+                                    rxlev_thr,
+                                    MAX_NUM_BANDS*sizeof(UBYTE),
+                                    FFS_O_CREATE | FFS_O_RDWR));
+#endif
+TRACE_EVENT_P6("%s RxLev Threshold written to FFS: GSM 850=%d, PGSM 900=%d, DCS 1800=%d, PCS 1900=%d, EGSM=%d",
+    rxlev_thr_string, rxlev_thr[B_GSM_850], rxlev_thr[B_GSM_900],
+    rxlev_thr[B_DCS_1800], rxlev_thr[B_PCS_1900], rxlev_thr[B_E_GSM] );
+
+}
+
+/*
++------------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                         |
+| STATE   : code                ROUTINE : rr_csf_read_rxlev_thr          |
++------------------------------------------------------------------------+
+
+  PURPOSE : This function copies  "RXLevel Threshold" information from FFS to RR
+            internal "RXLevel Threshold" arrays. In case of windows 
+            simulation environment, "RXLevel Threshold" is read from simulated FFS 
+            area. This function is called after power on
+*/
+
+GLOBAL void rr_csf_read_rxlev_thr(void)
+{
+
+  UBYTE x;
+  GET_INSTANCE_DATA;
+  TRACE_FUNCTION ("rr_csf_read_rxlev_thr()");
+
+  TRACE_EVENT("Read RXLevel thresholds from FFS");
+
+#if defined(_SIMULATION_)
+  memcpy(rr_data->dyn_config.lower_rxlev_thr,win_lower_rxlev_thr,
+         MAX_NUM_BANDS*sizeof(UBYTE));
+  memcpy(rr_data->dyn_config.medium_rxlev_thr,win_medium_rxlev_thr,
+         MAX_NUM_BANDS*sizeof(UBYTE));
+  memcpy(rr_data->dyn_config.upper_rxlev_thr,win_upper_rxlev_thr,
+         MAX_NUM_BANDS*sizeof(UBYTE));
+#else
+  rr_csf_check_ffs_dirs();
+  if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_lower_rxlev_thr_name,
+                                               rr_data->dyn_config.lower_rxlev_thr,
+                                               MAX_NUM_BANDS*sizeof(UBYTE))))
+  {
+    for( x=0 ; x<MAX_NUM_BANDS ; x++ )
+    {
+       rr_data->dyn_config.lower_rxlev_thr[x]  = LOWER_RXLEV_THRESHOLD;
+    }
+    rr_data->dyn_config.lower_rxlev_thr[B_GSM_850]  = LOWER_RXLEV_THRESHOLD_850;
+  }
+  if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_medium_rxlev_thr_name,
+                                               rr_data->dyn_config.medium_rxlev_thr,
+                                               MAX_NUM_BANDS*sizeof(UBYTE))))
+  {
+    for( x=0 ; x<MAX_NUM_BANDS ; x++ )
+    {
+            rr_data->dyn_config.medium_rxlev_thr[x]  = MEDIUM_RXLEV_THRESHOLD;
+    }
+  }
+  if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_upper_rxlev_thr_name,
+                                               rr_data->dyn_config.upper_rxlev_thr,
+                                               MAX_NUM_BANDS*sizeof(UBYTE))))
+  {
+    for( x=0 ; x<MAX_NUM_BANDS ; x++ )
+    {
+            rr_data->dyn_config.upper_rxlev_thr[x]  = UPPER_RXLEV_THRESHOLD;
+    }
+  }
+#endif
+} 
+
+/*
++-----------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                        |
+| STATE   : code                ROUTINE : rr_csf_write_mcc_shield_to_ffs|
++-----------------------------------------------------------------------+
+
+  PURPOSE : This function writes the mcc shield values to FFS
+*/
+
+GLOBAL void rr_csf_write_mcc_shield_to_ffs(void)
+{
+  GET_INSTANCE_DATA;
+  UBYTE count;
+  TRACE_FUNCTION ("rr_csf_write_mcc_shield_to_ffs()");
+
+  rr_csf_check_ffs_dirs();
+  rr_csf_handle_ffs_write_result(ffs_file_write (rr_shield_mcc_name,
+                                                 &rr_data->dyn_config.mcc_shield,
+                                                 sizeof(T_shield_mcc),
+                                                 FFS_O_CREATE | FFS_O_RDWR));
+  for(count=0;count<MAX_MCC_SHIELD;count++)
+  {
+    TRACE_EVENT_P5 ( "Shield MCC=%d%d%d enabled=[%d]index=[%d]",
+                      rr_data->dyn_config.mcc_shield.mcc[count][0],
+                      rr_data->dyn_config.mcc_shield.mcc[count][1],
+                      rr_data->dyn_config.mcc_shield.mcc[count][2],
+                      rr_data->dyn_config.mcc_shield.enabled,
+                      rr_data->dyn_config.mcc_shield.index);
+  }
+}
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)      MODULE  : RR_CSF                      |
+| STATE   : code               ROUTINE : rr_csf_mcc_present                  |
++--------------------------------------------------------------------+
+
+  PURPOSE : This function is used to find mcc already present or not
+*/
+
+GLOBAL UBYTE rr_csf_mcc_present(UBYTE* mcc_value)
+{
+  GET_INSTANCE_DATA;
+   U8 count = 0;
+   for(count = 0;count<MAX_MCC_SHIELD;count++)
+   {
+     if((memcmp(rr_data->dyn_config.mcc_shield.mcc[count],mcc_value,SIZE_MCC)EQ 0))
+     {
+       return TRUE;
+     }
+   }
+   return FALSE;
+}
+
+
+/*
++-----------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                        |
+| STATE   : code                ROUTINE : rr_csf_handle_ffs_read_result |
++-----------------------------------------------------------------------+
+
+  PURPOSE : This function checks the status from FFS and returns
+            TRUE if there is no error and FALSE if there is
+*/
+LOCAL BOOL rr_csf_handle_ffs_read_result(T_FFS_SIZE status_read)
+{
+  if(status_read>0)
+  {
+    TRACE_EVENT ("FFS Read OK");
+    return TRUE;
+  }
+  else
+  {
+    TRACE_EVENT_P1("FFS Read ERROR - %x", status_read);
+    return FALSE;
+  }
+}
+
+/*
++------------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                         |
+| STATE   : code                ROUTINE : rr_csf_handle_ffs_write_result |
++------------------------------------------------------------------------+
+
+  PURPOSE : This function checks the status from FFS and returns
+            TRUE if there is no error and FALSE if there is
+*/
+LOCAL BOOL rr_csf_handle_ffs_write_result(T_FFS_RET status_write)
+{
+  if(status_write >= EFFS_OK)
+  {
+    TRACE_EVENT("FFS Write OK");
+    if(status_write)
+      TRACE_EVENT_P1 ("Bytes written: %d",status_write);
+
+    return(TRUE);
+  }
+  else
+  {
+    TRACE_EVENT_P1 ("FFS Write Error - Status: %x",status_write);
+    return(FALSE);
+  }
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_check_ffs_dirs      |
++--------------------------------------------------------------------+
+
+  PURPOSE : This routine creates the /gsm/l3 directory for the last used
+            sc arfcn in the FFS. The return result indicates whether either
+            directories existed or not. There is no error handling.
+*/
+
+LOCAL void rr_csf_check_ffs_dirs( void )
+{
+  const char gsm_name[] = "/gsm";
+  const char gsm_l3_name[] = "/gsm/l3";
+
+  rr_csf_create_ffs_dirs(gsm_name);
+  rr_csf_create_ffs_dirs(gsm_l3_name);
+}
+
+/*
++--------------------------------------------------------------------+
+| PROJECT : GSM-PS (6147)       MODULE  : RR_CSF                     |
+| STATE   : code                ROUTINE : rr_csf_create_ffs_dirs     |
++--------------------------------------------------------------------+
+
+  PURPOSE : This routine calls the ffs_mkdir() routine to create a
+            specified directory. It returns whether the directory
+            existed or not prior to creation.
+*/
+LOCAL void rr_csf_create_ffs_dirs(const char *dir_name)
+{
+  T_FFS_RET status;
+
+  status=ffs_mkdir(dir_name);
+  switch(status)
+  {
+    case EFFS_EXISTS:
+    case EFFS_OK:
+      break;
+
+    default: /*Error*/
+      TRACE_EVENT_P1("Create Dir error - %x",status);
+      break;
+  }
+}
+#endif /* _SIMULATION_FFS_ */
+
+#endif