FreeCalypso > hg > freecalypso-citrine
comparison g23m-gsm/rr/rr_csf.c @ 0:75a11d740a02
initial import of gsm-fw from freecalypso-sw rev 1033:5ab737ac3ad7
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Thu, 09 Jun 2016 00:02:41 +0000 |
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-1:000000000000 | 0:75a11d740a02 |
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1 /* | |
2 +----------------------------------------------------------------------------- | |
3 | Project : | |
4 | Modul : | |
5 +----------------------------------------------------------------------------- | |
6 | Copyright 2002 Texas Instruments Berlin, AG | |
7 | All rights reserved. | |
8 | | |
9 | This file is confidential and a trade secret of Texas | |
10 | Instruments Berlin, AG | |
11 | The receipt of or possession of this file does not convey | |
12 | any rights to reproduce or disclose its contents or to | |
13 | manufacture, use, or sell anything it may describe, in | |
14 | whole, or in part, without the specific written consent of | |
15 | Texas Instruments Berlin, AG. | |
16 +----------------------------------------------------------------------------- | |
17 | Purpose : This module defines the custom specific functions | |
18 | for the component RR of the mobile station | |
19 +----------------------------------------------------------------------------- | |
20 */ | |
21 | |
22 #ifndef RR_CSF_C | |
23 #define RR_CSF_C | |
24 | |
25 #include "config.h" | |
26 #include "fixedconf.h" | |
27 #include "condat-features.h" | |
28 | |
29 #define ENTITY_RR | |
30 #define SAP_ACI | |
31 | |
32 /*==== INCLUDES ===================================================*/ | |
33 | |
34 #include <string.h> | |
35 #include <stdlib.h> | |
36 #include <stddef.h> /* offsetof */ | |
37 #include "typedefs.h" | |
38 #include "pcm.h" | |
39 #include "pconst.cdg" | |
40 #include "mconst.cdg" | |
41 #include "message.h" | |
42 #include "ccdapi.h" | |
43 #include "vsi.h" | |
44 #include "custom.h" | |
45 #include "gsm.h" | |
46 #include "prim.h" | |
47 #include "cnf_rr.h" | |
48 #include "tok.h" | |
49 #include "rr.h" | |
50 #include "cl_imei.h" /* IMEI common library */ | |
51 #if defined(_SIMULATION_FFS_) | |
52 #include "../../services/ffs/ffs.h" | |
53 #include "ffs_coat.h" | |
54 #endif /* _SIMULATION_FFS_ */ | |
55 | |
56 /*==== EXPORT =====================================================*/ | |
57 | |
58 /*==== PRIVAT =====================================================*/ | |
59 #if defined(_SIMULATION_FFS_) | |
60 LOCAL BOOL rr_csf_handle_ffs_read_result(T_FFS_SIZE status_read); | |
61 LOCAL BOOL rr_csf_handle_ffs_write_result(T_FFS_RET status_write); | |
62 LOCAL void rr_csf_check_ffs_dirs( void ); | |
63 LOCAL void rr_csf_create_ffs_dirs(const char *dir_name); | |
64 #endif /* _SIMULATION_FFS_ */ | |
65 | |
66 | |
67 | |
68 /*==== VARIABLES ==================================================*/ | |
69 /* Cell selection improvements LLD section 4.1.1.1 */ | |
70 #if defined(_SIMULATION_) | |
71 T_LIST win_black_list[MAX_REGIONS]; /* Simulates FFS for "Black List" */ | |
72 T_CS_WHITE_LIST win_white_list; /* Simulates FFS for "White List */ | |
73 | |
74 /*Simulates FFS for lower rxlevel thresholds*/ | |
75 UBYTE win_lower_rxlev_thr[MAX_NUM_BANDS] = { LOWER_RXLEV_THRESHOLD_850, LOWER_RXLEV_THRESHOLD, \ | |
76 LOWER_RXLEV_THRESHOLD, LOWER_RXLEV_THRESHOLD, LOWER_RXLEV_THRESHOLD }; | |
77 /*Simulates FFS for medium rxlevel thresholds*/ | |
78 UBYTE win_medium_rxlev_thr[MAX_NUM_BANDS] = { MEDIUM_RXLEV_THRESHOLD, MEDIUM_RXLEV_THRESHOLD, \ | |
79 MEDIUM_RXLEV_THRESHOLD, MEDIUM_RXLEV_THRESHOLD, MEDIUM_RXLEV_THRESHOLD }; | |
80 /*Simulates FFS for upper rxlevel thresholds*/ | |
81 UBYTE win_upper_rxlev_thr[MAX_NUM_BANDS] = { UPPER_RXLEV_THRESHOLD, UPPER_RXLEV_THRESHOLD, \ | |
82 UPPER_RXLEV_THRESHOLD, UPPER_RXLEV_THRESHOLD, UPPER_RXLEV_THRESHOLD }; | |
83 /* Initialize the simulated rxlevel thresholds here itself */ | |
84 #endif | |
85 | |
86 /* | |
87 +--------------------------------------------------------------------+ | |
88 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
89 | STATE : code ROUTINE : rr_csf_read_imei | | |
90 +--------------------------------------------------------------------+ | |
91 | |
92 PURPOSE : The function reads the International mobile identity number | |
93 from the non-volantile memory into an internal data structure. | |
94 | |
95 */ | |
96 | |
97 GLOBAL void rr_csf_read_imei (T_mob_ident *imei) | |
98 { | |
99 UBYTE buf[CL_IMEI_SIZE]; | |
100 | |
101 TRACE_FUNCTION ("rr_csf_read_imei()"); | |
102 | |
103 imei->v_ident_dig = TRUE; | |
104 imei->v_tmsi_1 = FALSE; | |
105 imei->ident_type = 3; /* set to TYPE_IMEISV */ | |
106 imei->c_ident_dig = 16; | |
107 imei->odd_even = 0; | |
108 | |
109 /* Get IMEISV from IMEI common library */ | |
110 cl_get_imeisv(CL_IMEI_SIZE, buf, CL_IMEI_GET_SECURE_IMEI); | |
111 | |
112 /* copy digits */ | |
113 imei->ident_dig[0] = (buf [0] >> 4) & 0x0F; /* TAC 8 byte */ | |
114 imei->ident_dig[1] = buf [0] & 0x0F; | |
115 imei->ident_dig[2] = (buf [1] >> 4) & 0x0F; | |
116 imei->ident_dig[3] = buf [1] & 0x0F; | |
117 imei->ident_dig[4] = (buf [2] >> 4) & 0x0F; | |
118 imei->ident_dig[5] = buf [2] & 0x0F; | |
119 imei->ident_dig[6] = (buf [3] >> 4) & 0x0F; | |
120 imei->ident_dig[7] = buf [3] & 0x0F; | |
121 imei->ident_dig[8] = (buf [4] >> 4) & 0x0F; /* SNR 6 byte */ | |
122 imei->ident_dig[9] = buf [4] & 0x0F; | |
123 imei->ident_dig[10]= (buf [5] >> 4) & 0x0F; | |
124 imei->ident_dig[11]= buf [5] & 0x0F; | |
125 imei->ident_dig[12]= (buf [6] >> 4) & 0x0F; | |
126 imei->ident_dig[13]= buf [6] & 0x0F; | |
127 imei->ident_dig[14]= (buf [7] >> 4) & 0x0F; /* SV 2 byte */ | |
128 imei->ident_dig[15]= buf [7] & 0x0F; | |
129 | |
130 TRACE_EVENT_P8("RR INFO IMEI: TAC %1x%1x%1x%1x%1x%1x%1x%1x", | |
131 imei->ident_dig[0], imei->ident_dig[1], imei->ident_dig[2], | |
132 imei->ident_dig[3], imei->ident_dig[4], imei->ident_dig[5], | |
133 imei->ident_dig[6], imei->ident_dig[7]); | |
134 TRACE_EVENT_P6("RR INFO IMEI: SNR %1x%1x%1x%1x%1x%1x", | |
135 imei->ident_dig[8], imei->ident_dig[9], imei->ident_dig[10], | |
136 imei->ident_dig[11], imei->ident_dig[12], imei->ident_dig[13]); | |
137 TRACE_EVENT_P2("RR INFO IMEI: SV %1x%1x", imei->ident_dig[14], | |
138 imei->ident_dig[15]); | |
139 } | |
140 | |
141 #if !defined(NTRACE) | |
142 GLOBAL void rr_csf_trace_power (void) | |
143 { | |
144 GET_INSTANCE_DATA; | |
145 UBYTE setbands = rr_data->ms_data.rf_cap.setbands; | |
146 UBYTE bands = rr_data->ms_data.rf_cap.bands; | |
147 UBYTE stdbands; | |
148 | |
149 if (setbands EQ 0) | |
150 { | |
151 setbands = bands; /* auto detection, use all supported bands */ | |
152 } | |
153 else | |
154 setbands &= bands;/* bands set, use only supported bands */ | |
155 | |
156 /* bands which might be supported with current std */ | |
157 stdbands = std_bands[std-1]; | |
158 | |
159 TRACE_EVENT_P5 ("std=%d(%02x), (set)bands=%02x(%02x)->%02x", | |
160 std, stdbands, rr_data->ms_data.rf_cap.setbands, | |
161 rr_data->ms_data.rf_cap.bands, setbands); | |
162 TRACE_EVENT_P6 ("%sGSM 900: power class=%u %s,%s%s%s", | |
163 (bands&0x08)?"E":" ", | |
164 rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_900].pow_class, | |
165 (bands&0x09)?"rfcap":" ", | |
166 (stdbands&0x09)?"std":" ", | |
167 (setbands&0x09)?",supported":"", | |
168 ((setbands&0x09) AND (setbands&0x09) EQ 0x01)?" (only GSM)":""); | |
169 TRACE_EVENT_P4 ("DCS 1800: power class=%u %s,%s%s", | |
170 rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class, | |
171 (bands&0x02)?"rfcap":" ", | |
172 (stdbands&0x02)?"std":" ", | |
173 (setbands&0x02)?",supported":""); | |
174 TRACE_EVENT_P4 ("PCS 1900: power class=%u %s,%s%s", | |
175 rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class, | |
176 (bands&0x04)?"rfcap":" ", | |
177 (stdbands&0x04)?"std":" ", | |
178 (setbands&0x04)?",supported":""); | |
179 TRACE_EVENT_P4 ("GSM 850: power class=%u %s,%s%s", | |
180 rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_850].pow_class, | |
181 (bands&0x10)?"rfcap":" ", | |
182 (stdbands&0x10)?"std":" ", | |
183 (setbands&0x10)?",supported":""); | |
184 TRACE_EVENT_P4 ("GSM 400: power class=%u %s,%s%s", | |
185 rr_data->ms_data.rf_cap.rf_power.pow_class4[IDX_PWRCLASS_400].pow_class, | |
186 (bands&0x60)?"rfcap":" ", | |
187 (stdbands&0x60)?"std":" ", | |
188 (setbands&0x60)?",supported":""); | |
189 TRACE_EVENT_P1 ("GPRS multislot class =%u", | |
190 rr_data->ms_data.rf_cap.rf_ms.gprs_ms_class); | |
191 } | |
192 #endif /* !NTRACE */ | |
193 | |
194 #if defined(_SIMULATION_) && !defined(NTRACE) | |
195 #define TRACE_STRUCT(struct_member) TRACE_EVENT_P1("0x%02x " #struct_member , *((unsigned int*)&struct_member)) | |
196 | |
197 LOCAL void rr_csf_trace_class1 (T_mob_class_1* cm1) | |
198 { | |
199 TRACE_STRUCT (cm1->rev_lev); | |
200 TRACE_STRUCT (cm1->es_ind); | |
201 TRACE_STRUCT (cm1->a5_1); | |
202 TRACE_STRUCT (cm1->rf_pow_cap); | |
203 } | |
204 | |
205 LOCAL void rr_csf_trace_class2 (T_mob_class_2* cm2) | |
206 { | |
207 TRACE_STRUCT (cm2->rev_lev); | |
208 TRACE_STRUCT (cm2->es_ind); | |
209 TRACE_STRUCT (cm2->a5_1); | |
210 TRACE_STRUCT (cm2->rf_pow_cap); | |
211 TRACE_STRUCT (cm2->ps); | |
212 TRACE_STRUCT (cm2->ss_screen); | |
213 TRACE_STRUCT (cm2->mt_pp_sms); | |
214 TRACE_STRUCT (cm2->vbs); | |
215 TRACE_STRUCT (cm2->vgcs); | |
216 TRACE_STRUCT (cm2->egsm); | |
217 TRACE_STRUCT (cm2->class3); | |
218 TRACE_STRUCT (cm2->lcsva); | |
219 TRACE_STRUCT (cm2->ucs2_treat); | |
220 TRACE_STRUCT (cm2->solsa); | |
221 TRACE_STRUCT (cm2->cmsp); | |
222 TRACE_STRUCT (cm2->a5_3); | |
223 TRACE_STRUCT (cm2->a5_2); | |
224 } | |
225 | |
226 LOCAL void rr_csf_trace_class3 (T_mob_class_3* cm3) | |
227 { | |
228 TRACE_STRUCT (cm3->mb_value); | |
229 TRACE_STRUCT (cm3->a5_7); | |
230 TRACE_STRUCT (cm3->a5_6); | |
231 TRACE_STRUCT (cm3->a5_5); | |
232 TRACE_STRUCT (cm3->a5_4); | |
233 if (cm3->v_radio_cap_2) | |
234 { | |
235 TRACE_STRUCT (cm3->radio_cap_2); | |
236 } | |
237 if (cm3->v_radio_cap_1) | |
238 { | |
239 TRACE_STRUCT (cm3->radio_cap_1); | |
240 } | |
241 if (cm3->v_rgsm_class) | |
242 { | |
243 TRACE_STRUCT (cm3->rgsm_class); | |
244 } | |
245 if (cm3->v_ms_class) | |
246 { | |
247 TRACE_STRUCT (cm3->ms_class); | |
248 } | |
249 | |
250 TRACE_STRUCT (cm3->ucs2_treat); | |
251 TRACE_STRUCT (cm3->ext_meas); | |
252 if (cm3->v_measurement) | |
253 { | |
254 TRACE_STRUCT (cm3->measurement); | |
255 } | |
256 if (cm3->v_pos_method) | |
257 { | |
258 TRACE_STRUCT (cm3->pos_method); | |
259 } | |
260 if (cm3->v_edge_ms_class) | |
261 { | |
262 TRACE_STRUCT (cm3->edge_ms_class); | |
263 } | |
264 if (cm3->v_egde_struct) | |
265 { | |
266 TRACE_STRUCT (cm3->egde_struct.mod); | |
267 if (cm3->egde_struct.v_egde_pow1) | |
268 { | |
269 TRACE_STRUCT (cm3->egde_struct.egde_pow1); | |
270 } | |
271 if (cm3->egde_struct.v_egde_pow2) | |
272 { | |
273 TRACE_STRUCT (cm3->egde_struct.egde_pow2); | |
274 } | |
275 } | |
276 #ifdef REL99 | |
277 if (cm3->v_gsm400_struct) | |
278 { | |
279 TRACE_STRUCT (cm3->gsm400_struct.gsm400_supp); | |
280 TRACE_STRUCT (cm3->gsm400_struct.gsm400_cap); | |
281 } | |
282 #endif | |
283 if (cm3->v_gsm850_cap) | |
284 { | |
285 TRACE_STRUCT (cm3->gsm850_cap); | |
286 } | |
287 if (cm3->v_pcs1900_cap) | |
288 { | |
289 TRACE_STRUCT (cm3->pcs1900_cap); | |
290 } | |
291 #ifdef REL99 | |
292 TRACE_STRUCT (cm3->umts_fdd); | |
293 TRACE_STRUCT (cm3->umts_tdd); | |
294 TRACE_STRUCT (cm3->cdma2000); | |
295 #endif | |
296 if (cm3->v_dtm_ms) | |
297 { | |
298 TRACE_STRUCT (cm3->dtm_ms.dtm_g_ms_class); | |
299 TRACE_STRUCT (cm3->dtm_ms.mac_support); | |
300 if (cm3->dtm_ms.v_dtm_e_ms_class) | |
301 { | |
302 TRACE_STRUCT (cm3->dtm_ms.dtm_e_ms_class); | |
303 } | |
304 } | |
305 if (cm3->v_single_band) | |
306 { | |
307 TRACE_STRUCT (cm3->single_band); | |
308 } | |
309 } | |
310 #endif /* _SIMULATION_ && !NTRACE */ | |
311 | |
312 /* | |
313 +--------------------------------------------------------------------+ | |
314 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
315 | STATE : code ROUTINE : rr_csf_ms_cap | | |
316 +--------------------------------------------------------------------+ | |
317 | |
318 PURPOSE : Read the mobile station capabilities from a non-volantile | |
319 memory into an internal data structure. | |
320 | |
321 */ | |
322 #if !defined(NTRACE) | |
323 #define RFCAP_TEST | |
324 #endif /* !NTRACE */ | |
325 | |
326 GLOBAL void rr_csf_ms_cap (void) | |
327 { | |
328 GET_INSTANCE_DATA; | |
329 drv_Return_Type pcm_ret; | |
330 UBYTE version; | |
331 | |
332 TRACE_FUNCTION ("rr_csf_ms_cap()"); | |
333 | |
334 pcm_ret = pcm_ReadFile ((UBYTE *)EF_MSCAP_ID, SIZE_EF_MSCAP, | |
335 (UBYTE *)&rr_data->mscap, &version); | |
336 if(pcm_ret NEQ PCM_OK ) | |
337 { | |
338 TRACE_ERROR( "MS RF capability (EF_MSCAP_ID) -> PCM read error" ); | |
339 } | |
340 #if defined(RFCAP_TEST) | |
341 else | |
342 { | |
343 TRACE_ARRAY ((UBYTE*)&rr_data->mscap, SIZE_EF_MSCAP, "EF_MSCAP_ID"); | |
344 } | |
345 #endif /* RFCAP_TEST */ | |
346 } | |
347 | |
348 | |
349 /* | |
350 +--------------------------------------------------------------------+ | |
351 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
352 | STATE : code ROUTINE : rr_csf_read_rf_cap | | |
353 +--------------------------------------------------------------------+ | |
354 | |
355 PURPOSE : Read the mobile station capabilities from a non-volantile | |
356 memory into an internal data structure. | |
357 | |
358 */ | |
359 GLOBAL void rr_csf_read_rfcap (void) | |
360 { | |
361 GET_INSTANCE_DATA; | |
362 #define FldSetEx(f,n,v) (f|=((((ULONG)f)&(~((ULONG)n##m)))|(((ULONG)v)<<n##s))) | |
363 | |
364 EF_RFCAP rfcap_stream; | |
365 BYTE ccd_ret; | |
366 UBYTE version; | |
367 #if !defined(_SIMULATION_) | |
368 unsigned int ffs_ret; | |
369 #else | |
370 drv_Return_Type pcm_ret; | |
371 #endif /* _TMS470 */ | |
372 UBYTE gprs_ms, cmsp; | |
373 | |
374 TRACE_FUNCTION ("rr_csf_read_rfcap()"); | |
375 | |
376 /* save configured GPRS multislot class */ | |
377 gprs_ms = rr_data->ms_data.rf_cap.rf_ms.gprs_ms_class; | |
378 /* save configured CMSP bit */ | |
379 cmsp = rr_data->ms_data.rf_cap.cmsp; | |
380 | |
381 #if !defined(_SIMULATION_) | |
382 ffs_ret = FFS_fread("/gsm/com/rfcap", (UBYTE *)&rfcap_stream, sizeof(EF_RFCAP)); | |
383 if (ffs_ret EQ sizeof(EF_RFCAP)) | |
384 version = TRUE; | |
385 else | |
386 version = FALSE; | |
387 #else | |
388 pcm_ret = pcm_ReadFile ((UBYTE *)EF_RFCAP_ID, SIZE_EF_RFCAP, | |
389 (UBYTE *)&rfcap_stream, &version); | |
390 if(pcm_ret EQ PCM_OK ) | |
391 version = TRUE; | |
392 else | |
393 version = FALSE; | |
394 #endif | |
395 #define RFCAP_DEFAULT /* G23M/RR-ENH-9401 */ | |
396 #if !defined(RFCAP_DEFAULT) | |
397 if (!version) | |
398 { | |
399 TRACE_ERROR ("MS RF capability (rfcap) -> FFS read error. Reset will follow ..."); | |
400 /* | |
401 * the following delay is made on the target for reasons highlighted with | |
402 * issue 7510: some customers do during their production the download of the | |
403 * configuration to the flash whilst the target ist running; another reason is | |
404 * that the target is not accessable (e.g. via PTCM) during resets; thus | |
405 * the delay is present to allow that writing of config data is not disturbed | |
406 * by the reset | |
407 */ | |
408 #if !defined(_SIMULATION_) | |
409 TRACE_ERROR ("... in some seconds; download config data to flash please!"); | |
410 vsi_t_sleep(VSI_CALLER DELAY_RESET_NO_CONFIG_DATA); | |
411 #endif | |
412 assert (FALSE); | |
413 } | |
414 #else /* !RFCAP_DEFAULT */ | |
415 if (!version) | |
416 { | |
417 /* Implements Measure#32: Row 150 */ | |
418 | |
419 /* error output via trace interface */ | |
420 TRACE_ERROR( "MS RF capability (RFCAP) -> FFS/PCM read error: use default values instead"); | |
421 | |
422 #ifdef TI_PS_CUSTOM_RFCAP_DEFAULT | |
423 /* Update with the Custom defined default RF capabilities */ | |
424 memcpy(&rfcap_stream, custom_rfcap_default, SIZE_EF_RFCAP); | |
425 TRACE_EVENT_P2("Using Custom RFCAP values: Set_bands=%d, Freq_bands=%d", rfcap_stream.setbands, rfcap_stream.bands); | |
426 #ifndef FF_L23_A5_3 | |
427 FldSetEx (rfcap_stream.encryption, rfCap_A5_3, NO); | |
428 #endif | |
429 #else | |
430 | |
431 memset (&rfcap_stream, 0, SIZE_EF_RFCAP); | |
432 | |
433 /* default frequency bands */ | |
434 rfcap_stream.setbands = BAND_AUTO; | |
435 rfcap_stream.bands = BAND_GSM_900|BAND_E_GSM|BAND_DCS_1800|BAND_PCS_1900|BAND_GSM_850; | |
436 | |
437 /* power classes */ | |
438 FldSetEx (rfcap_stream.power1, rfCap_900, POWER_CLASS_4); | |
439 FldSetEx (rfcap_stream.power1, rfCap_1800, POWER_CLASS_1); | |
440 FldSetEx (rfcap_stream.power2, rfCap_1900, POWER_CLASS_1); | |
441 FldSetEx (rfcap_stream.power2, rfCap_850, POWER_CLASS_4); | |
442 | |
443 #if CONFIG_TARGET_PIRELLI || CONFIG_TARGET_FCDEV3B | |
444 /* | |
445 * The Pirelli is known to always be 900/1800/1900 MHz triband, | |
446 * so let's operate it as such by default. | |
447 * | |
448 * In the case of FCDEV3B there is at least a hypothetical possibility | |
449 * that we may need to build a tri850 version some day, but we can | |
450 * still default to tri900 - overriding defaults is what the FFS is for. | |
451 */ | |
452 rfcap_stream.bands &= ~BAND_GSM_850; | |
453 FldSetEx (rfcap_stream.power2, rfCap_850, 0); | |
454 #endif | |
455 | |
456 /* multi slot classes */ | |
457 FldSetEx (rfcap_stream.msGPRS, rfCap_MSC, MSLOT_CLASS_10); | |
458 | |
459 /* classmark 2 capabilities */ | |
460 FldSetEx (rfcap_stream.capability1, rfCap_esind, YES); | |
461 FldSetEx (rfcap_stream.capability2, rfCap_vgcs, NOT_SUPPORTED); | |
462 FldSetEx (rfcap_stream.capability2, rfCap_vbs, NOT_SUPPORTED); | |
463 FldSetEx (rfcap_stream.capability1, rfCap_ppsms, SUPPORTED); | |
464 FldSetEx (rfcap_stream.capability2, rfCap_ssc, SS_SCREEN_PHASE_2); | |
465 FldSetEx (rfcap_stream.capability1, rfCap_ps, NOT_SUPPORTED); | |
466 FldSetEx (rfcap_stream.capability1, rfCap_cmsp, SUPPORTED); | |
467 FldSetEx (rfcap_stream.capability1, rfCap_solsa, NOT_SUPPORTED); | |
468 FldSetEx (rfcap_stream.capability2, rfCap_usc2, SUPPORTED); | |
469 FldSetEx (rfcap_stream.capability1, rfCap_lcsva, NOT_SUPPORTED); | |
470 | |
471 /* classmark 3 capabilities */ | |
472 FldSetEx (rfcap_stream.capability2, rfCap_extmeas, NOT_SUPPORTED); | |
473 FldSetEx (rfcap_stream.capability2, rfCap_meas, NO); | |
474 FldSetEx (rfcap_stream.switchmeasure, rfCap_smst, SM_1); | |
475 FldSetEx (rfcap_stream.switchmeasure, rfCap_smt, SM_1); | |
476 | |
477 /* encryption algorithm */ | |
478 /* | |
479 * note inverse logic for the A5/1 encryption algorithm between | |
480 * classmark 1 and 2 on the one hand and radio access capability | |
481 * on the other hand | |
482 */ | |
483 FldSetEx (rfcap_stream.encryption, rfCap_A5_1, YES); | |
484 FldSetEx (rfcap_stream.encryption, rfCap_A5_2, NO); | |
485 #ifdef FF_L23_A5_3 | |
486 FldSetEx (rfcap_stream.encryption, rfCap_A5_3, YES); | |
487 #else | |
488 FldSetEx (rfcap_stream.encryption, rfCap_A5_3, NO); | |
489 #endif | |
490 FldSetEx (rfcap_stream.encryption, rfCap_A5_4, NO); | |
491 FldSetEx (rfcap_stream.encryption, rfCap_A5_5, NO); | |
492 FldSetEx (rfcap_stream.encryption, rfCap_A5_6, NO); | |
493 FldSetEx (rfcap_stream.encryption, rfCap_A5_7, NO); | |
494 #endif /* TI_PS_CUSTOM_RFCAP_DEFAULT */ | |
495 } | |
496 #endif /* !RFCAP_DEFAULT */ | |
497 | |
498 /* E-GSM includes P-GSM */ | |
499 if (FldGet (rfcap_stream.bands, rf_EGSM)) | |
500 { | |
501 FldSetEx (rfcap_stream.bands, rf_900, SUPPORTED); | |
502 } | |
503 | |
504 #if defined(RFCAP_TEST) | |
505 TRACE_ARRAY ((UBYTE*)&rfcap_stream, SIZE_EF_RFCAP, "rfcap_stream"); | |
506 #endif /* RFCAP_TEST */ | |
507 | |
508 {/* decode stream into c struct */ | |
509 #define DECODE_TMP MS_RF_CAPABILITY | |
510 typedef struct | |
511 { | |
512 U32 dummy; /*< 0: 4> */ | |
513 T_sdu sdu; /*< 4: ? > Service Data Unit */ | |
514 } T_DECODE_TMP; | |
515 T_MS_RF_CAPABILITY *ms_rf_cap; | |
516 USHORT off; | |
517 PALLOC_SDU (encode, DECODE_TMP, (SIZE_EF_RFCAP + 1 ) * BITS_PER_BYTE); | |
518 MALLOC (ms_rf_cap, sizeof (T_MS_RF_CAPABILITY)); | |
519 | |
520 /* The dummy field is needed to make the structure compatible for * | |
521 * the CCD. We need to initialise it to keep LINT happy */ | |
522 encode->dummy = 0x00; | |
523 | |
524 off = (USHORT)(encode->sdu.o_buf / BITS_PER_BYTE); | |
525 memcpy ( &encode->sdu.buf[off+1], &rfcap_stream, SIZE_EF_RFCAP); | |
526 encode->sdu.buf[off] = MS_RF_CAPABILITY; | |
527 | |
528 memset (ms_rf_cap, 0, sizeof (T_MS_RF_CAPABILITY)); | |
529 ccd_ret = ccd_decodeMsg(CCDENT_RR_COM, DOWNLINK, | |
530 (T_MSGBUF *)&encode->sdu, (UBYTE *)ms_rf_cap, | |
531 0xFF); | |
532 rr_data->ms_data.rf_cap = ms_rf_cap->rf_cap; /* Struct copy */ | |
533 MFREE (ms_rf_cap); | |
534 PFREE (encode); | |
535 } | |
536 | |
537 /* restore configured GPRS multislot class */ | |
538 if (rr_data->ms_data.multislot_class_configured) | |
539 { | |
540 rr_data->ms_data.rf_cap.rf_ms.gprs_ms_class = gprs_ms; | |
541 TRACE_EVENT_P1 ("'gprs_ms_class' configured to a value of %d (overwrite of rfcap)", gprs_ms); | |
542 } | |
543 | |
544 /* restore configured CMSP bit */ | |
545 if (rr_data->ms_data.cmsp_configured) | |
546 { | |
547 rr_data->ms_data.rf_cap.cmsp = cmsp; | |
548 TRACE_EVENT_P1 ("'cmsp' configured to a value of %d (overwrite of rfcap)", cmsp); | |
549 } | |
550 | |
551 #if defined(RFCAP_TEST) | |
552 if (ccd_ret NEQ ccdOK) | |
553 { | |
554 /* | |
555 * CCD has detected an error | |
556 */ | |
557 UBYTE first_err; | |
558 USHORT parlist [6]; | |
559 /* Implements Measure#32: Row 152...165 */ | |
560 | |
561 TRACE_EVENT_P1 ("ccd_decodeMsg(): %02x", ccd_ret); | |
562 /* | |
563 * get the first error | |
564 */ | |
565 first_err = ccd_getFirstError (CCDENT_RR, parlist); | |
566 | |
567 /* | |
568 * Error Handling | |
569 */ | |
570 do | |
571 { | |
572 /* Implements Measure#32: Row 152...165 */ | |
573 switch (first_err) | |
574 { | |
575 case ERR_NO_MORE_ERROR: | |
576 TRACE_EVENT_P1("%u the end of the error list is reached", first_err); | |
577 break; | |
578 case ERR_INVALID_CALC: | |
579 TRACE_EVENT_P1("%u calculation of the element repeat value failed", first_err); | |
580 break; | |
581 case ERR_PATTERN_MISMATCH: | |
582 TRACE_EVENT_P1("%u a bit pattern was not expected", first_err); | |
583 break; | |
584 case ERR_COMPREH_REQUIRED: | |
585 TRACE_EVENT_P1("%u check for comprehension required failed", first_err); | |
586 break; | |
587 case ERR_IE_NOT_EXPECTED: | |
588 TRACE_EVENT_P1("%u an information element was not expected", first_err); | |
589 break; | |
590 case ERR_IE_SEQUENCE: | |
591 TRACE_EVENT_P1("%u wrong sequence of information elements", first_err); | |
592 break; | |
593 case ERR_MAX_IE_EXCEED: | |
594 TRACE_EVENT_P1("%u maximum amount of repeatable information elements has exceeded", first_err); | |
595 break; | |
596 case ERR_MAX_REPEAT: | |
597 TRACE_EVENT_P1("%u a repeatable element occurs too often in the message", first_err); | |
598 break; | |
599 case ERR_MAND_ELEM_MISS: | |
600 TRACE_EVENT_P1("%u a mandatory information element is missing", first_err); | |
601 break; | |
602 case ERR_INVALID_MID: | |
603 TRACE_EVENT_P1("%u the message ID is not correct", first_err); | |
604 break; | |
605 case ERR_INVALID_TYPE: | |
606 TRACE_EVENT_P1("%u the information element is not a spare padding", first_err); | |
607 break; | |
608 case ERR_EOC_TAG_MISSING: | |
609 TRACE_EVENT_P1("%u indefinite length is specified for the ASN.1-BER but the end tag is missing", first_err); | |
610 break; | |
611 case ERR_INTERNAL_ERROR: | |
612 TRACE_EVENT_P1("%u an internal CCD error occured ", first_err); | |
613 break; | |
614 default: | |
615 TRACE_EVENT_P1("%u unknown error", first_err); | |
616 break; | |
617 } | |
618 first_err = ccd_getNextError (CCDENT_RR, parlist); | |
619 }while (first_err); | |
620 | |
621 } | |
622 | |
623 #if 0 | |
624 if (ccd_ret < ccdError) | |
625 { | |
626 rr_csf_trace_power (); | |
627 } | |
628 #endif /* 0|1 */ | |
629 #endif /* RFCAP_TEST */ | |
630 } | |
631 | |
632 GLOBAL void rr_csf_get_freq_bands (UBYTE *pfreq_bands) | |
633 { | |
634 GET_INSTANCE_DATA; | |
635 T_rf_cap *rfc = &rr_data->ms_data.rf_cap; | |
636 | |
637 #if defined(_SIMULATION_) | |
638 rr_csf_check_rfcap (FALSE); | |
639 #endif /* _SIMULATION_ */ | |
640 | |
641 if (rfc->setbands EQ BAND_AUTO) | |
642 *pfreq_bands = rfc->bands; | |
643 else | |
644 *pfreq_bands = rfc->setbands & rfc->bands; | |
645 #if !defined(NTRACE) | |
646 rr_csf_trace_power (); | |
647 #endif /* !NTRACE */ | |
648 } | |
649 | |
650 /* | |
651 +--------------------------------------------------------------------+ | |
652 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
653 | STATE : code ROUTINE : rr_csf_get_classmark1 | | |
654 +--------------------------------------------------------------------+ | |
655 | |
656 PURPOSE : fills c structure of the mobile station classmark 1 | |
657 information element; returns 0 if OK. | |
658 | |
659 */ | |
660 /*lint -esym(765,rr_csf_get_classmark1) | used by MM*/ | |
661 /*lint -esym(714,rr_csf_get_classmark1) | used by MM */ | |
662 GLOBAL UBYTE rr_csf_get_classmark1 (T_mob_class_1 *mob_class_1) | |
663 { | |
664 GET_INSTANCE_DATA; | |
665 TRACE_FUNCTION ("rr_csf_get_classmark1()"); | |
666 | |
667 #if defined(_SIMULATION_) | |
668 rr_csf_check_rfcap (FALSE); | |
669 #endif /* _SIMULATION_ */ | |
670 | |
671 *mob_class_1 = rr_data->ms_data.classmark1; | |
672 | |
673 #if defined(_SIMULATION_) && !defined(NTRACE) | |
674 rr_csf_trace_class1 (mob_class_1); | |
675 #endif /* _SIMULATION_ && !NTRACE */ | |
676 return 0;/* no error */ | |
677 } | |
678 | |
679 /* | |
680 +--------------------------------------------------------------------+ | |
681 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
682 | STATE : code ROUTINE : rr_csf_get_classmark2 | | |
683 +--------------------------------------------------------------------+ | |
684 | |
685 PURPOSE : fills c structure of the mobile station classmark 2 | |
686 information element; returns 0 if OK. | |
687 | |
688 */ | |
689 /*lint -esym(765,rr_csf_get_classmark2) | used by CC,MM */ | |
690 /*lint -esym(714,rr_csf_get_classmark2) | used by CC,MM */ | |
691 GLOBAL UBYTE rr_csf_get_classmark2 (T_mob_class_2 *mob_class_2) | |
692 { | |
693 GET_INSTANCE_DATA; | |
694 TRACE_FUNCTION ("rr_csf_get_classmark2()"); | |
695 | |
696 #if defined(_SIMULATION_) | |
697 rr_csf_check_rfcap (FALSE); | |
698 #endif /* _SIMULATION_ */ | |
699 | |
700 *mob_class_2 = rr_data->ms_data.classmark2; | |
701 | |
702 #if defined(_SIMULATION_) && !defined(NTRACE) | |
703 rr_csf_trace_class2 (mob_class_2); | |
704 #endif /* _SIMULATION_ && !NTRACE */ | |
705 return 0;/* no error */ | |
706 } | |
707 | |
708 /* | |
709 +--------------------------------------------------------------------+ | |
710 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
711 | STATE : code ROUTINE : rr_csf_get_classmark3 | | |
712 +--------------------------------------------------------------------+ | |
713 | |
714 PURPOSE : fills c structure of the mobile station classmark 3 | |
715 information element; returns 0 if OK. | |
716 | |
717 */ | |
718 #if 0 | |
719 GLOBAL UBYTE rr_csf_get_classmark3 (T_mob_class_3 *mob_class_3) | |
720 { | |
721 TRACE_FUNCTION ("rr_csf_get_classmark3()"); | |
722 | |
723 #if defined(_SIMULATION_) | |
724 rr_csf_check_rfcap (FALSE); | |
725 #endif /* _SIMULATION_ */ | |
726 | |
727 *mob_class_3 = rr_data->ms_data.classmark3; | |
728 | |
729 #if defined(_SIMULATION_) && !defined(NTRACE) | |
730 rr_csf_trace_class3 (mob_class_3); | |
731 #endif /* _SIMULATION_ && !NTRACE */ | |
732 return 0;/* no error */ | |
733 } | |
734 #endif | |
735 | |
736 #ifdef GPRS | |
737 /* fills c structure of the mobile station radio access capability information element; returns 0 if OK */ | |
738 /*lint -esym(765,rr_csf_get_radio_access_capability) | used by GMM,GRR */ | |
739 /*lint -esym(714,rr_csf_get_radio_access_capability) | used by GMM,GRR */ | |
740 GLOBAL UBYTE rr_csf_get_radio_access_capability (T_ra_cap *ra_cap) | |
741 { | |
742 GET_INSTANCE_DATA; | |
743 TRACE_FUNCTION ("rr_csf_get_radio_access_capability()"); | |
744 | |
745 #if defined(_SIMULATION_) | |
746 rr_csf_check_rfcap (FALSE); | |
747 #endif /* _SIMULATION_ */ | |
748 | |
749 *ra_cap = rr_data->ms_data.ra_cap; | |
750 return 0; | |
751 } | |
752 #endif | |
753 | |
754 /* get pointer to mobile station RF capability c structure; returns NULL on error */ | |
755 /*lint -esym(765,rr_csf_get_rf_capability) | used by GRR */ | |
756 /*lint -esym(714,rr_csf_get_rf_capability) | used by GRR */ | |
757 GLOBAL T_rf_cap* rr_csf_get_rf_capability (void) | |
758 { | |
759 GET_INSTANCE_DATA; | |
760 #if defined(_SIMULATION_) | |
761 rr_csf_check_rfcap (FALSE); | |
762 #endif /* _SIMULATION_ */ | |
763 | |
764 return &rr_data->ms_data.rf_cap; | |
765 } | |
766 | |
767 GLOBAL void rr_csf_check_rfcap (UBYTE init) | |
768 { | |
769 GET_INSTANCE_DATA; | |
770 TRACE_FUNCTION ("rr_csf_check_rfcap()"); | |
771 | |
772 if (init OR (rr_data->ms_data.rf_cap.bands EQ 0)) | |
773 { | |
774 rr_csf_read_rfcap (); | |
775 rr_csf_fit_capability (); | |
776 } | |
777 } | |
778 | |
779 | |
780 #ifndef REL99 | |
781 | |
782 #define RAC_RELEASE97 | |
783 /* | |
784 +--------------------------------------------------------------------+ | |
785 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
786 | STATE : code ROUTINE : rr_csf_fit_capability | | |
787 +--------------------------------------------------------------------+ | |
788 | |
789 PURPOSE : fit classmark 2 and 3 and radio access capabilities | |
790 depend on the value of 'std' and the readed values of | |
791 /gsm/com/rfcap file according to R99 specifications | |
792 */ | |
793 | |
794 GLOBAL UBYTE rr_csf_fit_capability (void) | |
795 { | |
796 GET_INSTANCE_DATA; | |
797 USHORT serving_cell; | |
798 T_rf_cap *rfc = &rr_data->ms_data.rf_cap; | |
799 #ifdef GPRS | |
800 T_ra_cap *rac = &rr_data->ms_data.ra_cap; | |
801 #endif | |
802 T_mob_class_1 *cm1 = &rr_data->ms_data.classmark1; | |
803 T_mob_class_2 *cm2 = &rr_data->ms_data.classmark2; | |
804 T_mob_class_3 *cm3 = &rr_data->ms_data.classmark3; | |
805 | |
806 TRACE_FUNCTION ("rr_csf_fit_capability()"); | |
807 | |
808 if (rr_data->nc_data[SC_INDEX].bcch_status NEQ EMPTY) | |
809 serving_cell = rr_data->nc_data[SC_INDEX].arfcn; | |
810 else | |
811 serving_cell = (USHORT)-1; | |
812 | |
813 memset (cm2, 0, sizeof(T_mob_class_2)); | |
814 memset (cm3, 0, sizeof(T_mob_class_3)); | |
815 #ifdef GPRS | |
816 memset (rac, 0, sizeof(T_ra_cap)); | |
817 #endif | |
818 | |
819 cm1->rev_lev = cm2->rev_lev = REV_LEV_PHASE_2; /* PHASE_1 | PHASE_2 | R99_SUPPORT */ | |
820 #ifdef GPRS | |
821 #if !defined(RAC_RELEASE97) | |
822 rac->acc_cap.rev99 = REV_LEV_PHASE_1; /* PHASE_1 | RELEASE99 */ | |
823 #endif /* !RAC_RELEASE97 */ | |
824 #endif | |
825 cm1->es_ind = cm2->es_ind = rfc->es_ind; | |
826 cm2->ps = rfc->ps; | |
827 cm2->ss_screen = rfc->ss_screen; | |
828 cm2->mt_pp_sms = rfc->mt_pp_sms; | |
829 cm2->vbs = rfc->vbs; | |
830 cm2->vgcs = rfc->vgcs; | |
831 cm2->class3 = SUPPORTED; /* options indicated in classmark 3 */ | |
832 cm2->lcsva = rfc->lcsva; | |
833 cm2->ucs2_treat = cm3->ucs2_treat = rfc->ucs2_treat; | |
834 cm2->solsa = rfc->solsa; | |
835 cm2->cmsp = rfc->cmsp; | |
836 | |
837 /* | |
838 * note inverse logic for the A5/1 encryption algorithm between | |
839 * classmark 1 and 2 on the one hand and radio access capability | |
840 * on the other hand | |
841 */ | |
842 cm1->a5_1 = cm2->a5_1 = !rfc->a5_bits.a5_1; | |
843 cm2->a5_2 = rfc->a5_bits.a5_2; | |
844 cm2->a5_3 = rfc->a5_bits.a5_3; | |
845 | |
846 cm3->a5_4 = rfc->a5_bits.a5_4; | |
847 cm3->a5_5 = rfc->a5_bits.a5_5; | |
848 cm3->a5_6 = rfc->a5_bits.a5_6; | |
849 cm3->a5_7 = rfc->a5_bits.a5_7; | |
850 | |
851 #ifdef GPRS | |
852 rac->acc_cap.es_ind = rfc->es_ind; | |
853 rac->acc_cap.ps = rfc->ps; | |
854 rac->acc_cap.vbs = rfc->vbs; | |
855 rac->acc_cap.vgcs = rfc->vgcs; | |
856 rac->acc_cap.v_a5_bits = SUPPORTED; | |
857 rac->acc_cap.a5_bits = rfc->a5_bits; | |
858 #if !defined(RAC_RELEASE97) | |
859 rac->acc_cap.compact = rfc->compact; | |
860 #endif /* !RAC_RELEASE97 */ | |
861 | |
862 /* single- or multiband */ | |
863 rac->flag_ra_cap2 = rac->v_ra_cap2 = NO; | |
864 | |
865 #endif | |
866 | |
867 switch (std) | |
868 { | |
869 case STD_900: | |
870 cm3->mb_value = MB_GSM900; | |
871 #ifdef GPRS | |
872 rac->acc_tech_typ = ACC_GSM_P; | |
873 #endif | |
874 break; | |
875 case STD_EGSM: | |
876 cm2->egsm = SUPPORTED; | |
877 cm3->mb_value = MB_EGSM; | |
878 #ifdef GPRS | |
879 rac->acc_tech_typ = ACC_GSM_E; | |
880 #endif | |
881 break; | |
882 case STD_1800: | |
883 cm3->mb_value = MB_DCS1800; | |
884 #ifdef GPRS | |
885 rac->acc_tech_typ = ACC_GSM_1800; | |
886 #endif | |
887 break; | |
888 case STD_DUAL: | |
889 cm3->mb_value = MB_DUAL; | |
890 #ifdef GPRS | |
891 rac->acc_tech_typ = ACC_GSM_P; | |
892 rac->flag_ra_cap2 = rac->v_ra_cap2 = YES; | |
893 rac->ra_cap2.acc_tech_typ = ACC_GSM_1800; | |
894 rac->ra_cap2.acc_cap = rac->acc_cap; | |
895 rac->ra_cap2.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
896 rac->ra_cap2.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
897 #if !defined(RAC_RELEASE97) | |
898 rac->ra_cap2.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
899 #endif /* !RAC_RELEASE97 */ | |
900 #endif | |
901 break; | |
902 case STD_DUAL_EGSM: | |
903 /* note: incase of 1800 band, the FC bit shall be set to 0 */ | |
904 if ((rr_data->ms_data.rr_service EQ FULL_SERVICE) AND | |
905 (!INRANGE(LOW_CHANNEL_1800, rr_data->nc_data[SC_INDEX].arfcn, | |
906 HIGH_CHANNEL_1800))) | |
907 cm2->egsm = SUPPORTED; | |
908 cm3->mb_value = MB_DUAL_EXT; | |
909 #ifdef GPRS | |
910 rac->acc_tech_typ = ACC_GSM_E; | |
911 rac->flag_ra_cap2 = rac->v_ra_cap2 = YES; | |
912 rac->ra_cap2.acc_tech_typ = ACC_GSM_1800; | |
913 rac->ra_cap2.acc_cap = rac->acc_cap; | |
914 rac->ra_cap2.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
915 rac->ra_cap2.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
916 #if !defined(RAC_RELEASE97) | |
917 rac->ra_cap2.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
918 #endif /* !RAC_RELEASE97 */ | |
919 #endif | |
920 break; | |
921 | |
922 case STD_1900: | |
923 case STD_850: | |
924 case STD_DUAL_US: | |
925 /* no break; go through */ | |
926 default: | |
927 cm3->mb_value = MB_NO_EUROPEAN_BAND; | |
928 break; | |
929 } | |
930 | |
931 /* power classes */ | |
932 if (rfc->bands & 0x80) | |
933 { | |
934 TRACE_ERROR("R-GSM not supported by PS software"); | |
935 /* note: cm3->v_rgsm_class (and cm3->rgsm_class) are hard coded to 0 */ | |
936 } | |
937 if (rfc->bands & 0x60) | |
938 { | |
939 TRACE_ERROR("GSM 400 not supported by PS software"); | |
940 /* note: cm3->v_gsm400_struct (and cm3->gsm400_struct) are hard coded to 0 */ | |
941 } | |
942 switch (std) | |
943 { | |
944 case STD_900: | |
945 case STD_EGSM: | |
946 cm3->v_radio_cap_1 = TRUE; | |
947 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
948 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
949 #ifdef GPRS | |
950 rac->acc_cap.pow_class = cm3->radio_cap_1; | |
951 #endif | |
952 break; | |
953 | |
954 case STD_1800: | |
955 /* single band => only radio_cap_1 */ | |
956 cm3->v_radio_cap_1 = TRUE; | |
957 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class; | |
958 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
959 #ifdef GPRS | |
960 rac->acc_cap.pow_class = cm3->radio_cap_1; | |
961 #endif | |
962 break; | |
963 | |
964 case STD_DUAL: | |
965 case STD_DUAL_EGSM: | |
966 cm3->v_radio_cap_1 = TRUE; | |
967 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
968 cm3->v_radio_cap_2 = TRUE; | |
969 cm3->radio_cap_2 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class; | |
970 /* note: in case the sc is´nt set, it is out of range */ | |
971 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
972 cm2->rf_pow_cap = cm3->radio_cap_2 - 1; | |
973 else | |
974 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
975 #ifdef GPRS | |
976 rac->acc_cap.pow_class = cm3->radio_cap_1; | |
977 rac->ra_cap2.acc_cap.pow_class = cm3->radio_cap_2; | |
978 #endif | |
979 break; | |
980 | |
981 case STD_1900: | |
982 cm3->v_pcs1900_cap = SUPPORTED; | |
983 cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class; | |
984 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
985 #ifdef GPRS | |
986 rac->acc_tech_typ = ACC_GSM_1900; | |
987 rac->acc_cap.pow_class = cm3->pcs1900_cap; | |
988 #endif | |
989 break; | |
990 | |
991 case STD_850: | |
992 cm3->v_gsm850_cap = SUPPORTED; | |
993 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
994 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
995 #ifdef GPRS | |
996 rac->acc_tech_typ = ACC_GSM_850; | |
997 rac->acc_cap.pow_class = cm3->gsm850_cap; | |
998 #endif | |
999 break; | |
1000 | |
1001 case STD_DUAL_US: | |
1002 cm3->v_gsm850_cap = SUPPORTED; | |
1003 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
1004 cm3->v_pcs1900_cap = SUPPORTED; | |
1005 cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class; | |
1006 /* note: in case the sc isn't set, it is out of range */ | |
1007 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1008 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
1009 else | |
1010 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1011 #ifdef GPRS | |
1012 rac->acc_tech_typ = ACC_GSM_850; | |
1013 rac->acc_cap.pow_class = cm3->gsm850_cap; | |
1014 rac->flag_ra_cap2 = rac->v_ra_cap2 = YES; | |
1015 rac->ra_cap2.acc_tech_typ = ACC_GSM_1900; | |
1016 rac->ra_cap2.acc_cap = rac->acc_cap; | |
1017 rac->ra_cap2.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1018 rac->ra_cap2.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1019 #if !defined(RAC_RELEASE97) | |
1020 rac->ra_cap2.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1021 #endif /* !RAC_RELEASE97 */ | |
1022 rac->ra_cap2.acc_cap.pow_class = cm3->pcs1900_cap; | |
1023 #endif | |
1024 break; | |
1025 | |
1026 default: | |
1027 break; | |
1028 } | |
1029 cm1->rf_pow_cap = cm2->rf_pow_cap; | |
1030 | |
1031 #if defined(_SIMULATION_) && defined(RFCAP_TEST) | |
1032 rr_csf_trace_power (); | |
1033 #endif /* RFCAP_TEST*/ | |
1034 | |
1035 #if defined(FF_EGDE) | |
1036 if (rfc->mod OR rfc->rf_power.egde_pow1 OR rfc->rf_power.egde_pow2) | |
1037 { | |
1038 cm3->v_egde_struct = SUPPORTED; | |
1039 cm3->egde_struct.mod = rfc->mod; | |
1040 } | |
1041 switch (std) | |
1042 { | |
1043 case STD_900: | |
1044 case STD_EGSM: | |
1045 case STD_850: | |
1046 if (rfc->rf_power.egde_pow1) | |
1047 { | |
1048 if (rfc->mod) | |
1049 { | |
1050 cm3->egde_struct.v_egde_pow1 = SUPPORTED; | |
1051 cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1; | |
1052 } | |
1053 #ifdef GPRS | |
1054 rac->acc_cap.v_pow_8psk_cap = SUPPORTED; | |
1055 rac->acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1; | |
1056 #endif | |
1057 } | |
1058 break; | |
1059 case STD_1800: | |
1060 case STD_1900: | |
1061 if (rfc->rf_power.egde_pow2) | |
1062 { | |
1063 if (rfc->mod) | |
1064 { | |
1065 cm3->egde_struct.v_egde_pow2 = SUPPORTED; | |
1066 cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2; | |
1067 } | |
1068 #ifdef GPRS | |
1069 rac->acc_cap.v_pow_8psk_cap = SUPPORTED; | |
1070 rac->acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2; | |
1071 #endif | |
1072 } | |
1073 break; | |
1074 case STD_DUAL: | |
1075 case STD_DUAL_EGSM: | |
1076 case STD_DUAL_US: | |
1077 if (rfc->rf_power.egde_pow1) | |
1078 { | |
1079 if (rfc->mod) | |
1080 { | |
1081 cm3->egde_struct.v_egde_pow1 = SUPPORTED; | |
1082 cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1; | |
1083 } | |
1084 #ifdef GPRS | |
1085 rac->acc_cap.v_pow_8psk_cap = SUPPORTED; | |
1086 rac->acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1; | |
1087 #endif | |
1088 } | |
1089 if (rfc->rf_power.egde_pow2) | |
1090 { | |
1091 if (rfc->mod) | |
1092 { | |
1093 cm3->egde_struct.v_egde_pow2 = SUPPORTED; | |
1094 cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2; | |
1095 } | |
1096 #ifdef GPRS | |
1097 rac->ra_cap2.acc_cap.v_pow_8psk_cap = SUPPORTED; | |
1098 rac->ra_cap2.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2; | |
1099 #endif | |
1100 } | |
1101 break; | |
1102 default: | |
1103 break; | |
1104 } | |
1105 #endif /* FF_EGDE */ | |
1106 | |
1107 /* multi slot capabilities */ | |
1108 if (rfc->rf_ms.gsm_ms_class) | |
1109 { | |
1110 cm3->v_ms_class = SUPPORTED; | |
1111 cm3->ms_class = rfc->rf_ms.gsm_ms_class; | |
1112 } | |
1113 #if defined(FF_EGDE) | |
1114 if (rfc->rf_ms.edge_ms_class) | |
1115 { | |
1116 cm3->v_edge_ms_class = SUPPORTED; | |
1117 cm3->edge_ms_class = rfc->rf_ms.edge_ms_class; | |
1118 } | |
1119 #endif /* FF_EGDE */ | |
1120 if (rfc->rf_ms.dtm_g) | |
1121 { | |
1122 #ifdef GPRS | |
1123 rac->acc_cap.v_ms_struct = SUPPORTED; | |
1124 #endif | |
1125 cm3->v_dtm_ms = SUPPORTED; | |
1126 cm3->dtm_ms.mac_support = rfc->mac_support; | |
1127 cm3->dtm_ms.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class; | |
1128 #ifdef GPRS | |
1129 #if !defined(RAC_RELEASE97) | |
1130 rac->acc_cap.ms_struct.v_dtm_struct = SUPPORTED; | |
1131 rac->acc_cap.ms_struct.dtm_struct.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class; | |
1132 rac->acc_cap.ms_struct.dtm_struct.mac_support = rfc->mac_support; | |
1133 #endif /* !RAC_RELEASE97 */ | |
1134 #endif | |
1135 | |
1136 #if defined(FF_EGDE) | |
1137 if (rfc->rf_ms.dtm_e) | |
1138 { | |
1139 cm3->dtm_ms.v_dtm_e_ms_class = SUPPORTED; | |
1140 cm3->dtm_ms.dtm_e_ms_class = rfc->rf_ms.dtm_e_ms_class; | |
1141 #ifdef GPRS | |
1142 #if !defined(RAC_RELEASE97) | |
1143 rac->acc_cap.ms_struct.v_dtm_struct = SUPPORTED; | |
1144 rac->acc_cap.ms_struct.dtm_struct.v_dtm_e_ms_class = SUPPORTED; | |
1145 rac->acc_cap.ms_struct.dtm_struct.dtm_e_ms_class = rfc->rf_ms.dtm_e_ms_class; | |
1146 #endif /* !RAC_RELEASE97 */ | |
1147 #endif | |
1148 } | |
1149 #endif /* FF_EGDE */ | |
1150 } | |
1151 | |
1152 #ifdef GPRS | |
1153 if (rfc->rf_ms.hscsd_ms_class) | |
1154 { | |
1155 rac->acc_cap.v_ms_struct = SUPPORTED; | |
1156 rac->acc_cap.ms_struct.v_hscsd_ms_class = SUPPORTED; | |
1157 rac->acc_cap.ms_struct.hscsd_ms_class = rfc->rf_ms.hscsd_ms_class; | |
1158 } | |
1159 | |
1160 if (rfc->rf_ms.gprs_ms_class) | |
1161 { | |
1162 rac->acc_cap.v_ms_struct = SUPPORTED; | |
1163 rac->acc_cap.ms_struct.v_gprs_struct = SUPPORTED; | |
1164 rac->acc_cap.ms_struct.gprs_struct.gprs_ms_class = rfc->rf_ms.gprs_ms_class; | |
1165 rac->acc_cap.ms_struct.gprs_struct.gprs_eda = rfc->gprs_eda; | |
1166 } | |
1167 #endif | |
1168 | |
1169 cm3->ext_meas = rfc->ext_meas; | |
1170 | |
1171 if (rfc->meas) | |
1172 { | |
1173 #ifdef GPRS | |
1174 rac->acc_cap.v_ms_struct = SUPPORTED; | |
1175 rac->acc_cap.ms_struct.v_sms_sm_value = SUPPORTED; | |
1176 rac->acc_cap.ms_struct.sms_sm_value.sms_val = rfc->sms_val; | |
1177 rac->acc_cap.ms_struct.sms_sm_value.sm_val = rfc->sm_val; | |
1178 #endif | |
1179 | |
1180 cm3->v_measurement = SUPPORTED; | |
1181 cm3->measurement.sms_val = rfc->sms_val; | |
1182 cm3->measurement.sm_val = rfc->sm_val; | |
1183 } | |
1184 | |
1185 #ifdef GPRS | |
1186 if (rfc->rf_ms.ecsd_ms_class) | |
1187 { | |
1188 rac->acc_cap.v_ms_struct = SUPPORTED; | |
1189 #if !defined(RAC_RELEASE97) | |
1190 rac->acc_cap.ms_struct.v_ecsd_ms_class = SUPPORTED; | |
1191 rac->acc_cap.ms_struct.ecsd_ms_class = rfc->rf_ms.ecsd_ms_class; | |
1192 #endif /* !RAC_RELEASE97 */ | |
1193 } | |
1194 #endif | |
1195 | |
1196 #ifdef GPRS | |
1197 if (rfc->rf_ms.egprs_ms_class) | |
1198 { | |
1199 rac->acc_cap.v_ms_struct = SUPPORTED; | |
1200 #if !defined(RAC_RELEASE97) | |
1201 rac->acc_cap.ms_struct.v_egprs_struct = SUPPORTED; | |
1202 rac->acc_cap.ms_struct.egprs_struct.egprs_ms_class = rfc->rf_ms.egprs_ms_class; | |
1203 rac->acc_cap.ms_struct.egprs_struct.egprs_eda = rfc->egprs_eda; | |
1204 #endif /* !RAC_RELEASE97 */ | |
1205 } | |
1206 | |
1207 if (rac->v_ra_cap2 AND rac->acc_cap.v_ms_struct) | |
1208 { | |
1209 #if !defined(RAC_RELEASE97) | |
1210 rac->ra_cap2.acc_cap.rev99 = PHASE_1; /* PHASE_1 | RELEASE99 */ | |
1211 rac->ra_cap2.acc_cap.compact = rfc->compact; | |
1212 #endif /* !RAC_RELEASE97 */ | |
1213 rac->ra_cap2.acc_cap.es_ind = rfc->es_ind; | |
1214 rac->ra_cap2.acc_cap.ps = rfc->ps; | |
1215 rac->ra_cap2.acc_cap.vbs = rfc->vbs; | |
1216 rac->ra_cap2.acc_cap.vgcs = rfc->vgcs; | |
1217 /* | |
1218 * zero means that the same value for multislot parameters as given | |
1219 * in an earlier access capabilities field within this IE apply | |
1220 * also here. | |
1221 */ | |
1222 rac->ra_cap2.acc_cap.v_ms_struct = FALSE; | |
1223 } | |
1224 #endif | |
1225 | |
1226 #if defined FF_EOTD | |
1227 if (rfc->assist_eotd OR rfc->based_eotd OR rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps) | |
1228 #else | |
1229 if (rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps) | |
1230 #endif /* FF_EOTD */ | |
1231 { | |
1232 cm3->v_pos_method = SUPPORTED; | |
1233 #if defined FF_EOTD | |
1234 cm3->pos_method.assist_eotd = rfc->assist_eotd; | |
1235 cm3->pos_method.based_eotd = rfc->based_eotd; | |
1236 #endif /* FF_EOTD */ | |
1237 cm3->pos_method.assist_gps = rfc->assist_gps; | |
1238 cm3->pos_method.based_gps = rfc->based_gps; | |
1239 cm3->pos_method.conv_gps = rfc->conv_gps; | |
1240 } | |
1241 | |
1242 #if defined TI_PS_FF_REL99_AND_ABOVE | |
1243 cm3->v_gsm700_cap = NOT_SUPPORTED; | |
1244 cm3->umts_tdd_128 = NOT_SUPPORTED; | |
1245 cm3->geran_feat_pack_1 = NOT_SUPPORTED; | |
1246 cm3->v_ext_dtm_ms = NOT_SUPPORTED; | |
1247 cm3->v_high_ms_cap = NOT_SUPPORTED; | |
1248 cm3->geran_iu_mod_cap = NOT_SUPPORTED; | |
1249 cm3->geran_feat_pack_2 = NOT_SUPPORTED; | |
1250 cm3->gmsk_ms_pwr_prof = MS_PWR_PROF0; | |
1251 cm3->psk8_ms_pwr_prof = MS_PWR_PROF0; | |
1252 cm3->v_t_gsm400_struct = NOT_SUPPORTED; | |
1253 cm3->v_t_gsm900_cap = NOT_SUPPORTED; | |
1254 #ifdef L1_SAIC | |
1255 /* To support SAIC release 6 feature */ | |
1256 cm3->dl_adv_rx_per = DL_ADVANC_RX_PERF_PHASE1_SUPPORT; | |
1257 #else | |
1258 cm3->dl_adv_rx_per = DL_ADVANC_RX_PERF_NOT_SUPPORT; | |
1259 #endif /* L1_SAIC */ | |
1260 cm3->dtm_enhance_cap = NOT_SUPPORTED; | |
1261 cm3->v_dtm_high_ms = NOT_SUPPORTED; | |
1262 #ifdef FF_REPEATED_SACCH | |
1263 cm3->rep_acch_cap = REP_SACCH_DL_FACCH; | |
1264 #else | |
1265 cm3->rep_acch_cap = REP_DL_FACCH; | |
1266 #endif /* FF_REPEATED_SACCH */ | |
1267 #endif /* TI_PS_FF_REL99_AND_ABOVE */ | |
1268 | |
1269 #if defined(_SIMULATION_) && !defined(NTRACE) | |
1270 rr_csf_trace_class1 (cm1); | |
1271 rr_csf_trace_class2 (cm2); | |
1272 rr_csf_trace_class3 (cm3); | |
1273 #endif /* _SIMULATION_ && !NTRACE */ | |
1274 /* | |
1275 * note: cm3->umts_fdd, cm3->umts_tdd, cm3->cdma2000, cm3->v_single_band and | |
1276 * cm3->single_band are hard coded to 0 due to the lack of information about | |
1277 * these features inside the T_rf_cap structure | |
1278 */ | |
1279 return 0; | |
1280 } | |
1281 | |
1282 #else /* Release 99 */ | |
1283 | |
1284 /* | |
1285 +--------------------------------------------------------------------+ | |
1286 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
1287 | STATE : code ROUTINE : rr_csf_fit_capability | | |
1288 +--------------------------------------------------------------------+ | |
1289 | |
1290 PURPOSE : fit classmark 2 and 3 and radio access capabilities | |
1291 depend on the value of 'std' and the readed values of | |
1292 /gsm/com/rfcap file according to R99 specifications | |
1293 | |
1294 */ | |
1295 | |
1296 GLOBAL UBYTE rr_csf_fit_capability (void) | |
1297 { | |
1298 GET_INSTANCE_DATA; | |
1299 USHORT serving_cell; | |
1300 T_rf_cap *rfc = &rr_data->ms_data.rf_cap; | |
1301 #ifdef GPRS | |
1302 T_ra_cap *rac = &rr_data->ms_data.ra_cap; | |
1303 #ifdef TI_PS_FF_QUAD_BAND_SUPPORT | |
1304 int i; | |
1305 #endif | |
1306 #endif | |
1307 T_mob_class_1 *cm1 = &rr_data->ms_data.classmark1; | |
1308 T_mob_class_2 *cm2 = &rr_data->ms_data.classmark2; | |
1309 T_mob_class_3 *cm3 = &rr_data->ms_data.classmark3; | |
1310 | |
1311 TRACE_FUNCTION ("rr_csf_fit_capability()"); | |
1312 | |
1313 if (rr_data->nc_data[SC_INDEX].bcch_status NEQ EMPTY) | |
1314 serving_cell = rr_data->nc_data[SC_INDEX].arfcn; | |
1315 else | |
1316 serving_cell = (USHORT)-1; | |
1317 | |
1318 memset (cm2, 0, sizeof(T_mob_class_2)); | |
1319 memset (cm3, 0, sizeof(T_mob_class_3)); | |
1320 #ifdef GPRS | |
1321 memset (rac, 0, sizeof(T_ra_cap)); | |
1322 #endif | |
1323 | |
1324 | |
1325 /* Set clasmark 1 fields */ | |
1326 cm1->rev_lev = REV_LEV_R99_SUPPORT; /* R99 mobile */ | |
1327 cm1->es_ind = rfc->es_ind; | |
1328 cm1->a5_1 = !rfc->a5_bits.a5_1; | |
1329 | |
1330 | |
1331 /* Set classmark 2 fields */ | |
1332 cm2->rev_lev = REV_LEV_R99_SUPPORT; | |
1333 cm2->es_ind = rfc->es_ind; | |
1334 cm2->ps = rfc->ps; | |
1335 cm2->ss_screen = rfc->ss_screen; | |
1336 cm2->mt_pp_sms = rfc->mt_pp_sms; | |
1337 cm2->vbs = rfc->vbs; | |
1338 cm2->vgcs = rfc->vgcs; | |
1339 cm2->class3 = SUPPORTED; | |
1340 cm2->lcsva = rfc->lcsva; | |
1341 cm2->ucs2_treat = rfc->ucs2_treat; | |
1342 cm2->solsa = rfc->solsa; | |
1343 cm2->cmsp = rfc->cmsp; | |
1344 cm2->a5_1 = !rfc->a5_bits.a5_1; | |
1345 cm2->a5_2 = rfc->a5_bits.a5_2; | |
1346 cm2->a5_3 = rfc->a5_bits.a5_3; | |
1347 | |
1348 | |
1349 /* Set classmark 3 fields */ | |
1350 cm3->a5_4 = rfc->a5_bits.a5_4; | |
1351 cm3->a5_5 = rfc->a5_bits.a5_5; | |
1352 cm3->a5_6 = rfc->a5_bits.a5_6; | |
1353 cm3->a5_7 = rfc->a5_bits.a5_7; | |
1354 cm3->ucs2_treat = rfc->ucs2_treat; | |
1355 cm3->ext_meas = rfc->ext_meas; | |
1356 | |
1357 /* Set multi slot capabilities */ | |
1358 if (rfc->rf_ms.gsm_ms_class) | |
1359 { | |
1360 cm3->v_ms_class = SUPPORTED; | |
1361 cm3->ms_class = rfc->rf_ms.gsm_ms_class; | |
1362 } | |
1363 | |
1364 /* Set MS measurement capability */ | |
1365 if (rfc->meas) | |
1366 { | |
1367 cm3->v_measurement = SUPPORTED; | |
1368 cm3->measurement.sms_val = rfc->sms_val; | |
1369 cm3->measurement.sm_val = rfc->sm_val; | |
1370 } | |
1371 | |
1372 /* Set MS positioning method */ | |
1373 #if defined FF_EOTD | |
1374 if (rfc->assist_eotd OR rfc->based_eotd OR rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps) | |
1375 #else | |
1376 if (rfc->assist_gps OR rfc->based_gps OR rfc->conv_gps) | |
1377 #endif /* FF_EOTD */ | |
1378 { | |
1379 cm3->v_pos_method = SUPPORTED; | |
1380 #if defined FF_EOTD | |
1381 cm3->pos_method.assist_eotd = rfc->assist_eotd; | |
1382 cm3->pos_method.based_eotd = rfc->based_eotd; | |
1383 #endif /* FF_EOTD */ | |
1384 cm3->pos_method.assist_gps = rfc->assist_gps; | |
1385 cm3->pos_method.based_gps = rfc->based_gps; | |
1386 cm3->pos_method.conv_gps = rfc->conv_gps; | |
1387 } | |
1388 | |
1389 | |
1390 #ifdef GPRS | |
1391 /* Set Radio Access Capability info */ | |
1392 rac->ra_cap_values.v_acc_cap = YES; | |
1393 rac->ra_cap_values.acc_cap.v_a5_bits = SUPPORTED; | |
1394 | |
1395 rac->ra_cap_values.acc_cap.rev99 = RELEASE99; | |
1396 rac->ra_cap_values.acc_cap.es_ind = rfc->es_ind; | |
1397 rac->ra_cap_values.acc_cap.ps = rfc->ps; | |
1398 rac->ra_cap_values.acc_cap.vbs = rfc->vbs; | |
1399 rac->ra_cap_values.acc_cap.vgcs = rfc->vgcs; | |
1400 rac->ra_cap_values.acc_cap.a5_bits = rfc->a5_bits; | |
1401 rac->ra_cap_values.acc_cap.compact = rfc->compact; | |
1402 | |
1403 rac->ra_cap_values.acc_cap.v_ms_struct = SUPPORTED; | |
1404 rac->ra_cap_values.acc_cap.ms_struct.v_ecsd_ms_class = NOT_SUPPORTED;/*CR 637 */ | |
1405 rac->ra_cap_values.acc_cap.ms_struct.v_hscsd_ms_class = NOT_SUPPORTED;/*CR 637 */ | |
1406 rac->ra_cap_values.acc_cap.ms_struct.v_sms_sm_value = NOT_SUPPORTED;/*CR 637 */ | |
1407 | |
1408 rac->c_ra_cap_r = NO; | |
1409 rac->v_ra_cap_r = NO; | |
1410 | |
1411 #endif | |
1412 | |
1413 #ifdef TI_PS_FF_QUAD_BAND_SUPPORT | |
1414 /* Set the MS multiband capabilities */ | |
1415 switch (std) | |
1416 { | |
1417 case STD_900: | |
1418 cm3->mb_value = MB_GSM900; | |
1419 #ifdef GPRS | |
1420 rac->ra_cap_values.acc_tech_typ = ACC_GSM_P; | |
1421 #endif | |
1422 break; | |
1423 case STD_EGSM: | |
1424 cm2->egsm = SUPPORTED; | |
1425 #ifdef GPRS | |
1426 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1427 #endif | |
1428 /* No break */ | |
1429 case STD_900_1900: | |
1430 case STD_850_900_1900: | |
1431 cm3->mb_value = MB_EGSM; | |
1432 if ((!INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1433 AND (!INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))) | |
1434 { | |
1435 cm2->egsm = SUPPORTED; | |
1436 } | |
1437 break; | |
1438 case STD_1800: | |
1439 #ifdef GPRS | |
1440 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1441 #endif | |
1442 /* NO break */ | |
1443 case STD_850_1800: | |
1444 cm3->mb_value = MB_DCS1800; | |
1445 break; | |
1446 case STD_DUAL: | |
1447 cm3->mb_value = MB_DUAL; | |
1448 #ifdef GPRS | |
1449 rac->v_ra_cap_r = YES; | |
1450 rac->c_ra_cap_r++; | |
1451 rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES; | |
1452 | |
1453 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1454 { | |
1455 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1456 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_P; | |
1457 } | |
1458 else | |
1459 { | |
1460 rac->ra_cap_values.acc_tech_typ = ACC_GSM_P; | |
1461 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1462 } | |
1463 | |
1464 rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap; | |
1465 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1466 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1467 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1468 #endif | |
1469 break; | |
1470 case STD_DUAL_EGSM: | |
1471 case STD_850_900_1800: | |
1472 /* note: incase of 1800 band, the FC bit shall be set to 0 */ | |
1473 if((!INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1474 AND (!INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850))) | |
1475 cm2->egsm = SUPPORTED; | |
1476 cm3->mb_value = MB_DUAL_EXT; | |
1477 | |
1478 #ifdef GPRS | |
1479 rac->v_ra_cap_r = YES; | |
1480 rac->c_ra_cap_r++; | |
1481 rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES; | |
1482 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1483 { | |
1484 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1485 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1486 } | |
1487 else | |
1488 { | |
1489 if(INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)) | |
1490 { | |
1491 rac->ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1492 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1493 } | |
1494 else | |
1495 { | |
1496 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1497 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1498 } | |
1499 } | |
1500 | |
1501 rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap; | |
1502 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1503 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1504 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1505 #endif | |
1506 break; | |
1507 | |
1508 case STD_1900: | |
1509 case STD_850: | |
1510 case STD_DUAL_US: | |
1511 /* no break; go through */ | |
1512 default: | |
1513 cm3->mb_value = MB_NO_EUROPEAN_BAND; | |
1514 break; | |
1515 } | |
1516 #else | |
1517 /* Set the MS multiband capabilities */ | |
1518 switch (std) | |
1519 { | |
1520 case STD_900: | |
1521 cm3->mb_value = MB_GSM900; | |
1522 #ifdef GPRS | |
1523 rac->ra_cap_values.acc_tech_typ = ACC_GSM_P; | |
1524 #endif | |
1525 break; | |
1526 case STD_EGSM: | |
1527 cm2->egsm = SUPPORTED; | |
1528 cm3->mb_value = MB_EGSM; | |
1529 #ifdef GPRS | |
1530 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1531 #endif | |
1532 break; | |
1533 case STD_1800: | |
1534 cm3->mb_value = MB_DCS1800; | |
1535 #ifdef GPRS | |
1536 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1537 #endif | |
1538 break; | |
1539 case STD_DUAL: | |
1540 cm3->mb_value = MB_DUAL; | |
1541 #ifdef GPRS | |
1542 rac->v_ra_cap_r = YES; | |
1543 rac->c_ra_cap_r++; | |
1544 rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES; | |
1545 | |
1546 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1547 { | |
1548 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1549 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_P; | |
1550 } | |
1551 else | |
1552 { | |
1553 rac->ra_cap_values.acc_tech_typ = ACC_GSM_P; | |
1554 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1555 } | |
1556 | |
1557 rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap; | |
1558 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1559 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1560 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1561 #endif | |
1562 break; | |
1563 case STD_DUAL_EGSM: | |
1564 /* note: incase of 1800 band, the FC bit shall be set to 0 */ | |
1565 if(!INRANGE(LOW_CHANNEL_1800,rr_data->nc_data[SC_INDEX].arfcn,HIGH_CHANNEL_1800)) | |
1566 cm2->egsm = SUPPORTED; | |
1567 cm3->mb_value = MB_DUAL_EXT; | |
1568 | |
1569 #ifdef GPRS | |
1570 rac->v_ra_cap_r = YES; | |
1571 rac->c_ra_cap_r++; | |
1572 rac->ra_cap_r[0].ra_cap_values.v_acc_cap = YES; | |
1573 | |
1574 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1575 { | |
1576 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1577 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1578 } | |
1579 else | |
1580 { | |
1581 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1582 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1583 } | |
1584 | |
1585 rac->ra_cap_r[0].ra_cap_values.acc_cap = rac->ra_cap_values.acc_cap; | |
1586 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1587 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1588 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1589 #endif | |
1590 break; | |
1591 | |
1592 case STD_1900: | |
1593 case STD_850: | |
1594 case STD_DUAL_US: | |
1595 /* no break; go through */ | |
1596 default: | |
1597 cm3->mb_value = MB_NO_EUROPEAN_BAND; | |
1598 break; | |
1599 } | |
1600 #endif | |
1601 | |
1602 /* Set MS power classes info */ | |
1603 if (rfc->bands & 0x80) | |
1604 { | |
1605 TRACE_ERROR("R-GSM not supported by PS software"); | |
1606 /* note: cm3->v_rgsm_class (and cm3->rgsm_class) are hard coded to 0 */ | |
1607 } | |
1608 if (rfc->bands & 0x60) | |
1609 { | |
1610 TRACE_ERROR("GSM 400 not supported by PS software"); | |
1611 /* note: cm3->v_gsm400_struct (and cm3->gsm400_struct) are hard coded to 0 */ | |
1612 } | |
1613 | |
1614 switch (std) | |
1615 { | |
1616 case STD_900: | |
1617 case STD_EGSM: | |
1618 cm3->v_radio_cap_1 = TRUE; | |
1619 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
1620 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1621 #ifdef GPRS | |
1622 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1623 #endif | |
1624 break; | |
1625 | |
1626 case STD_1800: | |
1627 /* single band => only radio_cap_1 */ | |
1628 cm3->v_radio_cap_1 = TRUE; | |
1629 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class; | |
1630 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1631 #ifdef GPRS | |
1632 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1633 #endif | |
1634 break; | |
1635 | |
1636 case STD_DUAL: | |
1637 case STD_DUAL_EGSM: | |
1638 cm3->v_radio_cap_1 = TRUE; | |
1639 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
1640 cm3->v_radio_cap_2 = TRUE; | |
1641 cm3->radio_cap_2 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class; | |
1642 /* note: in case the sc is´nt set, it is out of range */ | |
1643 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1644 cm2->rf_pow_cap = cm3->radio_cap_2 - 1; | |
1645 else | |
1646 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1647 #ifdef GPRS | |
1648 if (rac->ra_cap_values.acc_tech_typ EQ ACC_GSM_1800) | |
1649 { | |
1650 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2; | |
1651 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1652 } | |
1653 else | |
1654 { | |
1655 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1656 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2; | |
1657 } | |
1658 #endif | |
1659 break; | |
1660 | |
1661 case STD_1900: | |
1662 cm3->v_pcs1900_cap = SUPPORTED; | |
1663 cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class; | |
1664 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
1665 #ifdef GPRS | |
1666 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1667 rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1668 #endif | |
1669 break; | |
1670 | |
1671 case STD_850: | |
1672 cm3->v_gsm850_cap = SUPPORTED; | |
1673 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
1674 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1675 #ifdef GPRS | |
1676 rac->ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1677 rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1678 #endif | |
1679 break; | |
1680 | |
1681 case STD_DUAL_US: | |
1682 cm3->v_gsm850_cap = SUPPORTED; | |
1683 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
1684 cm3->v_pcs1900_cap = SUPPORTED; | |
1685 cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class; | |
1686 | |
1687 /* note: in case the sc isn't set, it is out of range */ | |
1688 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1689 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
1690 else | |
1691 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1692 | |
1693 #ifdef GPRS | |
1694 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1695 { | |
1696 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
1697 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1698 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1699 rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1700 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1701 } | |
1702 else | |
1703 { | |
1704 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1705 rac->ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1706 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1707 rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1708 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1709 } | |
1710 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1711 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1712 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1713 #endif | |
1714 break; | |
1715 | |
1716 #ifdef TI_PS_FF_QUAD_BAND_SUPPORT | |
1717 case STD_900_1900: | |
1718 cm3->v_radio_cap_1 = TRUE; | |
1719 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
1720 cm3->v_pcs1900_cap = SUPPORTED; | |
1721 cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class; | |
1722 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1723 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
1724 else | |
1725 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1726 #ifdef GPRS | |
1727 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1728 { | |
1729 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1730 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1731 rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1732 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1733 } | |
1734 else | |
1735 { | |
1736 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1737 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1738 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1739 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1740 } | |
1741 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1742 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1743 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1744 #endif | |
1745 break; | |
1746 | |
1747 case STD_850_1800: | |
1748 cm3->v_radio_cap_1 = TRUE; | |
1749 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class; | |
1750 cm3->v_gsm850_cap = SUPPORTED; | |
1751 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
1752 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1753 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1754 else | |
1755 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1756 #ifdef GPRS | |
1757 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1758 { | |
1759 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1760 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1761 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1762 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1763 } | |
1764 else | |
1765 { | |
1766 rac->ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1767 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1768 rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1769 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1770 } | |
1771 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1772 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1773 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1774 #endif | |
1775 break; | |
1776 | |
1777 case STD_850_900_1900: | |
1778 cm3->v_gsm850_cap = SUPPORTED; | |
1779 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
1780 cm3->v_pcs1900_cap = SUPPORTED; | |
1781 cm3->pcs1900_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_1900].pow_class; | |
1782 cm3->v_radio_cap_1 = TRUE; | |
1783 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
1784 /* note: in case the sc is´nt set, it is out of range */ | |
1785 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1786 cm2->rf_pow_cap = cm3->pcs1900_cap - 1; | |
1787 else if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)) | |
1788 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1789 else | |
1790 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1791 | |
1792 #ifdef GPRS | |
1793 if (INRANGE(LOW_CHANNEL_1900,serving_cell,HIGH_CHANNEL_1900)) | |
1794 { | |
1795 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1796 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1797 rac->ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1798 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1799 } | |
1800 else | |
1801 { | |
1802 if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)) | |
1803 { | |
1804 rac->ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1805 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1806 rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1807 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1808 } | |
1809 else | |
1810 { | |
1811 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1812 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1900; | |
1813 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1814 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->pcs1900_cap; | |
1815 } | |
1816 } | |
1817 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1818 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1819 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1820 #endif | |
1821 break; | |
1822 case STD_850_900_1800: | |
1823 cm3->v_radio_cap_1 = TRUE; | |
1824 cm3->radio_cap_1 = rfc->rf_power.pow_class4[IDX_PWRCLASS_900].pow_class; | |
1825 cm3->v_radio_cap_2 = TRUE; | |
1826 cm3->radio_cap_2 = rfc->rf_power.pow_class4[IDX_PWRCLASS_1800].pow_class; | |
1827 cm3->v_gsm850_cap = SUPPORTED; | |
1828 cm3->gsm850_cap = rfc->rf_power.pow_class4[IDX_PWRCLASS_850].pow_class; | |
1829 /* note: in case the sc is´nt set, it is out of range */ | |
1830 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1831 cm2->rf_pow_cap = cm3->radio_cap_2 - 1; | |
1832 else if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)) | |
1833 cm2->rf_pow_cap = cm3->gsm850_cap - 1; | |
1834 else | |
1835 cm2->rf_pow_cap = cm3->radio_cap_1 - 1; | |
1836 #ifdef GPRS | |
1837 if (INRANGE(LOW_CHANNEL_1800,serving_cell,HIGH_CHANNEL_1800)) | |
1838 { | |
1839 rac->ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1840 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1841 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2; | |
1842 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1843 } | |
1844 else | |
1845 { | |
1846 if (INRANGE(LOW_CHANNEL_850,serving_cell,HIGH_CHANNEL_850)) | |
1847 { | |
1848 rac->ra_cap_values.acc_tech_typ = ACC_GSM_850; | |
1849 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1850 rac->ra_cap_values.acc_cap.pow_class = cm3->gsm850_cap; | |
1851 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2; | |
1852 } | |
1853 else | |
1854 { | |
1855 rac->ra_cap_values.acc_tech_typ = ACC_GSM_E; | |
1856 rac->ra_cap_r[0].ra_cap_values.acc_tech_typ = ACC_GSM_1800; | |
1857 rac->ra_cap_values.acc_cap.pow_class = cm3->radio_cap_1; | |
1858 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_class = cm3->radio_cap_2; | |
1859 } | |
1860 } | |
1861 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_a5_bits = NOT_SUPPORTED; | |
1862 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_ms_struct = NOT_SUPPORTED; | |
1863 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1864 #endif | |
1865 break; | |
1866 #endif | |
1867 | |
1868 default: | |
1869 break; | |
1870 } | |
1871 | |
1872 cm1->rf_pow_cap = cm2->rf_pow_cap; | |
1873 | |
1874 #if defined(_SIMULATION_) && defined(RFCAP_TEST) | |
1875 rr_csf_trace_power (); | |
1876 #endif /* RFCAP_TEST*/ | |
1877 | |
1878 /*Set 8psk capability in uplink for EGPRS*/ | |
1879 #if defined(FF_EGPRS) | |
1880 | |
1881 /*Initialize with 8psk is not supported in uplink*/ | |
1882 cm3->v_egde_struct = NOT_SUPPORTED; | |
1883 rac->ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1884 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = NOT_SUPPORTED; | |
1885 | |
1886 switch (std) | |
1887 { | |
1888 case STD_900: | |
1889 case STD_EGSM: | |
1890 case STD_850: | |
1891 if (rfc->mod) | |
1892 { | |
1893 if (rfc->rf_power.egde_pow1) | |
1894 { | |
1895 cm3->v_egde_struct = TRUE; | |
1896 cm3->egde_struct.mod = SUPPORTED; | |
1897 cm3->egde_struct.v_egde_pow1 = TRUE; | |
1898 cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1; | |
1899 rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE; | |
1900 rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1; | |
1901 TRACE_EVENT_P1 ("1: 8PSK SUPPORTED (EGPRS) POWER CLASS E1 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap); | |
1902 } | |
1903 } | |
1904 break; | |
1905 case STD_1800: | |
1906 case STD_1900: | |
1907 if (rfc->mod) | |
1908 { | |
1909 if (rfc->rf_power.egde_pow2) | |
1910 { | |
1911 cm3->v_egde_struct = TRUE; | |
1912 cm3->egde_struct.mod = SUPPORTED; | |
1913 cm3->egde_struct.v_egde_pow2 = TRUE; | |
1914 cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2; | |
1915 rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE; | |
1916 rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2; | |
1917 TRACE_EVENT_P1 ("2: 8PSK SUPPORTED (EGPRS) POWER CLASS E2 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap); | |
1918 } | |
1919 } | |
1920 break; | |
1921 case STD_DUAL: | |
1922 case STD_DUAL_EGSM: | |
1923 case STD_DUAL_US: | |
1924 if ((rac->ra_cap_values.acc_tech_typ EQ ACC_GSM_1800) OR (rac->ra_cap_values.acc_tech_typ EQ ACC_GSM_1900)) | |
1925 { | |
1926 if (rfc->mod) | |
1927 { | |
1928 if (rfc->rf_power.egde_pow2) | |
1929 { | |
1930 /*8psk is supported in uplink in 1800/1900 BAND*/ | |
1931 cm3->v_egde_struct = TRUE; | |
1932 cm3->egde_struct.mod = SUPPORTED; | |
1933 cm3->egde_struct.v_egde_pow2 = TRUE; | |
1934 cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2; | |
1935 rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE; | |
1936 rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2; | |
1937 TRACE_EVENT_P1 ("3: 8PSK SUPPORTED (EGPRS) POWER CLASS E2 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap); | |
1938 } | |
1939 if (rfc->rf_power.egde_pow1) | |
1940 { | |
1941 /*Set 8psk capability for 850/900 BAND*/ | |
1942 cm3->v_egde_struct = TRUE; | |
1943 cm3->egde_struct.mod = SUPPORTED; | |
1944 cm3->egde_struct.v_egde_pow1 = TRUE; | |
1945 cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1; | |
1946 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE; | |
1947 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1; | |
1948 TRACE_EVENT_P1 ("4: 8PSK SUPPORTED (EGPRS) POWER CLASS E1 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap); | |
1949 } | |
1950 } | |
1951 } | |
1952 else | |
1953 { | |
1954 if (rfc->mod) | |
1955 { | |
1956 if (rfc->rf_power.egde_pow1) | |
1957 { | |
1958 /*8psk is supported in uplink in 1800/1900*/ | |
1959 cm3->v_egde_struct = TRUE; | |
1960 cm3->egde_struct.mod = SUPPORTED; | |
1961 cm3->egde_struct.v_egde_pow1 = TRUE; | |
1962 cm3->egde_struct.egde_pow1 = rfc->rf_power.egde_pow1; | |
1963 rac->ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE; | |
1964 rac->ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow1; | |
1965 TRACE_EVENT_P1 ("5: 8PSK SUPPORTED (EGPRS) POWER CLASS E1 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap); | |
1966 } | |
1967 if (rfc->rf_power.egde_pow2) | |
1968 { | |
1969 /*Set 8psk capability for 850/900*/ | |
1970 cm3->v_egde_struct = TRUE; | |
1971 cm3->egde_struct.mod = SUPPORTED; | |
1972 cm3->egde_struct.v_egde_pow2 = TRUE; | |
1973 cm3->egde_struct.egde_pow2 = rfc->rf_power.egde_pow2; | |
1974 rac->ra_cap_r[0].ra_cap_values.acc_cap.v_pow_8psk_cap = TRUE; | |
1975 rac->ra_cap_r[0].ra_cap_values.acc_cap.pow_8psk_cap = rfc->rf_power.egde_pow2; | |
1976 TRACE_EVENT_P1 ("6: 8PSK SUPPORTED (EGPRS) POWER CLASS E2 = %d",rac->ra_cap_values.acc_cap.pow_8psk_cap); | |
1977 } | |
1978 } | |
1979 } | |
1980 break; | |
1981 default: | |
1982 break; | |
1983 } | |
1984 #endif /* FF_EGPRS */ | |
1985 | |
1986 if (rfc->rf_ms.dtm_g) | |
1987 { | |
1988 cm3->v_dtm_ms = SUPPORTED; | |
1989 cm3->dtm_ms.mac_support = rfc->mac_support; | |
1990 cm3->dtm_ms.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class; | |
1991 #ifdef GPRS | |
1992 rac->ra_cap_values.acc_cap.ms_struct.v_dtm_struct = SUPPORTED; | |
1993 rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.dtm_g_ms_class = rfc->rf_ms.dtm_g_ms_class; | |
1994 rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.mac_support = rfc->mac_support; | |
1995 #endif | |
1996 | |
1997 #if defined(FF_EGPRS) | |
1998 if (rfc->rf_ms.dtm_e) | |
1999 { | |
2000 cm3->dtm_ms.v_dtm_e_ms_class = SUPPORTED; | |
2001 cm3->dtm_ms.dtm_e_ms_class = rfc->rf_ms.dtm_e_ms_class; | |
2002 #ifdef GPRS | |
2003 rac->ra_cap_values.acc_cap.ms_struct.v_dtm_struct = SUPPORTED; | |
2004 rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.v_dtm_e_ms_class = SUPPORTED; | |
2005 rac->ra_cap_values.acc_cap.ms_struct.dtm_struct.dtm_e_ms_class = rfc->rf_ms.dtm_e_ms_class; | |
2006 #endif | |
2007 } | |
2008 #endif /* FF_EGDE */ | |
2009 } | |
2010 | |
2011 #ifdef GPRS | |
2012 | |
2013 #if 0 /* CR 637 */ | |
2014 if (rfc->rf_ms.hscsd_ms_class) | |
2015 { | |
2016 rac->ra_cap_values.acc_cap.v_ms_struct = SUPPORTED; | |
2017 rac->ra_cap_values.acc_cap.ms_struct.v_hscsd_ms_class = SUPPORTED; | |
2018 rac->ra_cap_values.acc_cap.ms_struct.hscsd_ms_class = rfc->rf_ms.hscsd_ms_class; | |
2019 } | |
2020 #endif | |
2021 | |
2022 if (rfc->rf_ms.gprs_ms_class) | |
2023 { | |
2024 rac->ra_cap_values.acc_cap.ms_struct.v_gprs_struct = SUPPORTED; | |
2025 rac->ra_cap_values.acc_cap.ms_struct.gprs_struct.gprs_ms_class = rfc->rf_ms.gprs_ms_class; | |
2026 rac->ra_cap_values.acc_cap.ms_struct.gprs_struct.gprs_eda = rfc->gprs_eda; | |
2027 } | |
2028 | |
2029 if (rfc->meas) | |
2030 { | |
2031 rac->ra_cap_values.acc_cap.ms_struct.v_sms_sm_value = SUPPORTED; | |
2032 rac->ra_cap_values.acc_cap.ms_struct.sms_sm_value.sms_val = rfc->sms_val; | |
2033 rac->ra_cap_values.acc_cap.ms_struct.sms_sm_value.sm_val = rfc->sm_val; | |
2034 } | |
2035 | |
2036 #if 0 /* CR 637 */ | |
2037 if (rfc->rf_ms.ecsd_ms_class) | |
2038 { | |
2039 rac->ra_cap_values.acc_cap.v_ms_struct = SUPPORTED; | |
2040 rac->ra_cap_values.acc_cap.ms_struct.v_ecsd_ms_class = SUPPORTED; | |
2041 rac->ra_cap_values.acc_cap.ms_struct.ecsd_ms_class = rfc->rf_ms.ecsd_ms_class; | |
2042 } | |
2043 #endif | |
2044 | |
2045 #if defined(FF_EGPRS) | |
2046 if (rfc->rf_ms.egprs_ms_class) | |
2047 { | |
2048 cm3->v_edge_ms_class = TRUE; | |
2049 cm3->edge_ms_class = rfc->rf_ms.egprs_ms_class; | |
2050 rac->ra_cap_values.acc_cap.ms_struct.v_egprs_struct = TRUE; | |
2051 rac->ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_ms_class = rfc->rf_ms.egprs_ms_class; | |
2052 rac->ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_eda = rfc->egprs_eda; | |
2053 } | |
2054 #endif | |
2055 | |
2056 if ((rac->c_ra_cap_r > 0) AND rac->ra_cap_values.acc_cap.v_ms_struct) | |
2057 { | |
2058 rac->v_ra_cap_r = TRUE; | |
2059 rac->ra_cap_r[0].ra_cap_values.acc_cap.rev99 = RELEASE99; | |
2060 | |
2061 rac->ra_cap_r[0].ra_cap_values.acc_cap.compact = rfc->compact; | |
2062 rac->ra_cap_r[0].ra_cap_values.acc_cap.es_ind = rfc->es_ind; | |
2063 rac->ra_cap_r[0].ra_cap_values.acc_cap.ps = rfc->ps; | |
2064 rac->ra_cap_r[0].ra_cap_values.acc_cap.vbs = rfc->vbs; | |
2065 rac->ra_cap_r[0].ra_cap_values.acc_cap.vgcs = rfc->vgcs; | |
2066 | |
2067 #if defined(FF_EGPRS) | |
2068 if (rfc->rf_ms.egprs_ms_class) | |
2069 { | |
2070 rac->ra_cap_r[0].ra_cap_values.acc_cap.ms_struct.v_egprs_struct = TRUE; | |
2071 rac->ra_cap_r[0].ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_ms_class = rfc->rf_ms.egprs_ms_class; | |
2072 rac->ra_cap_r[0].ra_cap_values.acc_cap.ms_struct.egprs_struct.egprs_eda = rfc->egprs_eda; | |
2073 } | |
2074 #endif | |
2075 | |
2076 } | |
2077 #endif | |
2078 | |
2079 #if defined TI_PS_FF_REL99_AND_ABOVE | |
2080 /* To support SAIC release 6 feature */ | |
2081 cm3->v_gsm700_cap = NOT_SUPPORTED; | |
2082 cm3->umts_tdd_128 = NOT_SUPPORTED; | |
2083 cm3->geran_feat_pack_1 = NOT_SUPPORTED; | |
2084 cm3->v_ext_dtm_ms = NOT_SUPPORTED; | |
2085 cm3->v_high_ms_cap = NOT_SUPPORTED; | |
2086 cm3->geran_iu_mod_cap = NOT_SUPPORTED; | |
2087 cm3->geran_feat_pack_2 = NOT_SUPPORTED; | |
2088 cm3->gmsk_ms_pwr_prof = MS_PWR_PROF0; | |
2089 cm3->psk8_ms_pwr_prof = MS_PWR_PROF0; | |
2090 cm3->v_t_gsm400_struct = NOT_SUPPORTED; | |
2091 cm3->v_t_gsm900_cap = NOT_SUPPORTED; | |
2092 cm3->dtm_enhance_cap = NOT_SUPPORTED; | |
2093 cm3->v_dtm_high_ms = NOT_SUPPORTED; | |
2094 #ifdef L1_SAIC | |
2095 /* To support SAIC release 6 feature */ | |
2096 cm3->dl_adv_rx_per = DL_ADVANC_RX_PERF_PHASE1_SUPPORT; | |
2097 #else | |
2098 cm3->dl_adv_rx_per = DL_ADVANC_RX_PERF_NOT_SUPPORT; | |
2099 #endif /* L1_SAIC */ | |
2100 #ifdef FF_REPEATED_SACCH | |
2101 cm3->rep_acch_cap = REP_SACCH_DL_FACCH; | |
2102 #else | |
2103 cm3->rep_acch_cap = REP_DL_FACCH; | |
2104 #endif /* FF_REPEATED_SACCH */ | |
2105 #endif /* TI_PS_FF_REL99_AND_ABOVE */ | |
2106 | |
2107 #if defined(_SIMULATION_) && !defined(NTRACE) | |
2108 rr_csf_trace_class1 (cm1); | |
2109 rr_csf_trace_class2 (cm2); | |
2110 rr_csf_trace_class3 (cm3); | |
2111 #endif /* _SIMULATION_ && !NTRACE */ | |
2112 /* | |
2113 * note: cm3->umts_fdd, cm3->umts_tdd, cm3->cdma2000, cm3->v_single_band and | |
2114 * cm3->single_band are hard coded to 0 due to the lack of information about | |
2115 * these features inside the T_rf_cap structure | |
2116 */ | |
2117 return 0; | |
2118 } | |
2119 #endif | |
2120 | |
2121 /* | |
2122 +--------------------------------------------------------------------+ | |
2123 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2124 | STATE : code ROUTINE : RX_Enable | | |
2125 +--------------------------------------------------------------------+ | |
2126 | |
2127 PURPOSE : This function enables reporting of RX level. | |
2128 | |
2129 */ | |
2130 static T_VOID_FUNC rx_driver_entry = NULL; | |
2131 static UBYTE rx_act_value = 0; | |
2132 static UBYTE rx_act_qual = RX_QUAL_UNAVAILABLE; | |
2133 #ifdef FF_PS_RSSI | |
2134 static UBYTE rx_act_rxlev_access_min = RX_ACCE_UNAVAILABLE; | |
2135 #endif | |
2136 | |
2137 /*lint -esym(765,RX_Enable) | used by RX driver */ | |
2138 /*lint -esym(714,RX_Enable) | used by RX driver */ | |
2139 GLOBAL void RX_Enable (T_VOID_FUNC rx_indication) | |
2140 { | |
2141 /* | |
2142 * store callback function | |
2143 */ | |
2144 rx_driver_entry = rx_indication; | |
2145 } | |
2146 | |
2147 /* | |
2148 +--------------------------------------------------------------------+ | |
2149 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2150 | STATE : code ROUTINE : RX_SetValue | | |
2151 +--------------------------------------------------------------------+ | |
2152 | |
2153 PURPOSE : This function stores a new fieldstrength value and | |
2154 informs the RX driver if possible about a change. | |
2155 | |
2156 */ | |
2157 | |
2158 /* | |
2159 * for reduce number of indications during dedicated mode | |
2160 */ | |
2161 static UBYTE rssi_dedi_counter = 0; | |
2162 | |
2163 /* | |
2164 * Minimum RSSI difference for indication to MMI | |
2165 */ | |
2166 #define RSSI_MIN_DIFFERENCE 5 | |
2167 #define RSSI_MIN_LEVEL 10 | |
2168 | |
2169 | |
2170 #ifdef FF_PS_RSSI | |
2171 GLOBAL void RX_SetValue (UBYTE new_value, UBYTE new_qual, UBYTE new_access) | |
2172 #else | |
2173 GLOBAL void RX_SetValue (UBYTE new_value) | |
2174 #endif | |
2175 { | |
2176 GET_INSTANCE_DATA; | |
2177 UBYTE rssi_delta; | |
2178 | |
2179 #ifdef FF_PS_RSSI | |
2180 rx_act_rxlev_access_min = new_access; | |
2181 #endif | |
2182 | |
2183 if (rx_driver_entry EQ NULL) | |
2184 { | |
2185 rx_act_value = new_value; | |
2186 #ifdef FF_PS_RSSI | |
2187 rx_act_qual = new_qual; | |
2188 #endif | |
2189 } | |
2190 else /*if a callback is installed*/ | |
2191 { | |
2192 | |
2193 /* | |
2194 * Compute delta compared to last MMI value | |
2195 */ | |
2196 rssi_delta = ( new_value >= rx_act_value ? | |
2197 ( new_value - rx_act_value ) : | |
2198 ( rx_act_value - new_value ) | |
2199 ); | |
2200 /* | |
2201 * if difference greather than defined threshold | |
2202 * rx_qual is available in dedicated state only | |
2203 * Change in RX_QUAL | |
2204 */ | |
2205 if ((rssi_delta >= RSSI_MIN_DIFFERENCE) OR (new_value < RSSI_MIN_LEVEL) | |
2206 #ifdef FF_PS_RSSI | |
2207 OR (new_qual NEQ rx_act_qual) | |
2208 #endif | |
2209 ) | |
2210 { | |
2211 if ( GET_STATE (STATE_ATT) NEQ ATT_DEDICATED ) | |
2212 { | |
2213 rx_act_value = new_value; | |
2214 #ifdef FF_PS_RSSI | |
2215 rx_act_qual = new_qual; | |
2216 #endif | |
2217 (*rx_driver_entry)(); | |
2218 } | |
2219 else | |
2220 { | |
2221 /* | |
2222 * in dedicated mode take only each 16 the attempt | |
2223 * equal 8 seconds | |
2224 */ | |
2225 if (!((rssi_dedi_counter ++ ) & 0x0F )) | |
2226 { | |
2227 /* | |
2228 * New RSSI to be forwarded | |
2229 */ | |
2230 rx_act_value = new_value; | |
2231 #ifdef FF_PS_RSSI | |
2232 rx_act_qual = new_qual; | |
2233 #endif | |
2234 (*rx_driver_entry)(); | |
2235 } | |
2236 } | |
2237 } | |
2238 } | |
2239 } | |
2240 | |
2241 /* | |
2242 +--------------------------------------------------------------------+ | |
2243 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2244 | STATE : code ROUTINE : RX_GetValue | | |
2245 +--------------------------------------------------------------------+ | |
2246 | |
2247 PURPOSE : This function simulates a low level driver call to get | |
2248 the actual fieldstrength. | |
2249 | |
2250 */ | |
2251 /*lint -esym(765,RX_GetValue) | used by RX driver */ | |
2252 /*lint -esym(714,RX_GetValue) | used by RX driver */ | |
2253 GLOBAL USHORT RX_GetValue (void) | |
2254 { | |
2255 USHORT rx_level; | |
2256 | |
2257 rx_level = (USHORT)rx_act_value; | |
2258 | |
2259 return rx_level; | |
2260 } | |
2261 | |
2262 #ifdef FF_PS_RSSI | |
2263 /* | |
2264 +--------------------------------------------------------------------+ | |
2265 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2266 | STATE : code ROUTINE : RX_GetRxLevAccessMin | | |
2267 +--------------------------------------------------------------------+ | |
2268 | |
2269 PURPOSE : This function simulates a low level driver call to get | |
2270 the minimum access level. | |
2271 | |
2272 */ | |
2273 GLOBAL UBYTE RX_GetRxLevAccessMin (void) | |
2274 { | |
2275 return rx_act_rxlev_access_min; | |
2276 } | |
2277 #endif | |
2278 | |
2279 /* | |
2280 +--------------------------------------------------------------------+ | |
2281 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2282 | STATE : code ROUTINE : RX_SetRxQual | | |
2283 +--------------------------------------------------------------------+ | |
2284 | |
2285 PURPOSE : This function simulates a low level driver call to set | |
2286 the actual RXQUAL value. | |
2287 | |
2288 */ | |
2289 /*lint -esym(765,RX_SetRxQual) | used by GRR */ | |
2290 /*lint -esym(714,RX_SetRxQual) | used by GRR */ | |
2291 GLOBAL void RX_SetRxQual (UBYTE new_rx_qual) | |
2292 { | |
2293 rx_act_qual = new_rx_qual; | |
2294 } | |
2295 | |
2296 /* | |
2297 +--------------------------------------------------------------------+ | |
2298 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2299 | STATE : code ROUTINE : RX_GetRxQual | | |
2300 +--------------------------------------------------------------------+ | |
2301 | |
2302 PURPOSE : This function simulates a low level driver call to get | |
2303 the actual RXQUAL value. | |
2304 | |
2305 */ | |
2306 /*lint -esym(765,RX_GetRxQual) | used by RX driver */ | |
2307 /*lint -esym(714,RX_GetRxQual) | used by RX driver */ | |
2308 GLOBAL UBYTE RX_GetRxQual (void) | |
2309 { | |
2310 return rx_act_qual; | |
2311 } | |
2312 | |
2313 /* | |
2314 +--------------------------------------------------------------------+ | |
2315 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2316 | STATE : code ROUTINE : rr_get_found_channels | | |
2317 +--------------------------------------------------------------------+ | |
2318 | |
2319 PURPOSE : This function is a little bit dirty solution to get | |
2320 the BCCH channel numbers of a PLMN available list. | |
2321 | |
2322 */ | |
2323 #if 0 | |
2324 GLOBAL USHORT * rr_get_found_channels (void) | |
2325 { | |
2326 static USHORT found_channels[MAX_PLMN]; | |
2327 int i; | |
2328 for (i=0; i<MAX_PLMN; i++) | |
2329 found_channels[i] = rr_data->sc_data.found[i].arfcn; | |
2330 return found_channels; | |
2331 } | |
2332 #endif | |
2333 /* | |
2334 +--------------------------------------------------------------------+ | |
2335 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2336 | STATE : code ROUTINE : rr_get_bcch_channel | | |
2337 +--------------------------------------------------------------------+ | |
2338 | |
2339 PURPOSE : This function is a little bit dirty solution to get | |
2340 the BCCH channel numbers of the current PLMN. | |
2341 | |
2342 */ | |
2343 #if 0 | |
2344 GLOBAL USHORT rr_get_bcch_channel (void) | |
2345 { | |
2346 return rr_data->nc_data[SC_INDEX].arfcn; | |
2347 } | |
2348 #endif | |
2349 | |
2350 /* | |
2351 * These functions (get_network_meas() & get_bcch_chan_list()) should only | |
2352 * temporary defined here. | |
2353 */ | |
2354 /*lint -esym(765,get_network_meas) | used by SIM */ | |
2355 /*lint -esym(714,get_network_meas) | used by SIM */ | |
2356 GLOBAL UBYTE get_network_meas (UBYTE * chan_list) | |
2357 { | |
2358 GET_INSTANCE_DATA; | |
2359 #if defined (_SIMULATION_) | |
2360 /* | |
2361 * fixed values for the windows simulation | |
2362 */ | |
2363 memset (chan_list, 0, 16); | |
2364 chan_list [0] = 0x32; | |
2365 chan_list [1] = 0x16; | |
2366 chan_list [2] = 0x7E; | |
2367 chan_list [3] = 0x52; | |
2368 chan_list [4] = 0x37; | |
2369 return 1; | |
2370 #else /* _SIMULATION_ */ | |
2371 switch (GET_STATE (STATE_ATT)) | |
2372 { | |
2373 case ATT_IDLE: | |
2374 memset (chan_list, 0, 16); | |
2375 chan_list [0] = rr_data->nc_data[SC_INDEX].rxlev; | |
2376 return 1; | |
2377 case ATT_DEDICATED: | |
2378 memcpy (chan_list, dl_get_sacch_buffer(), 16); | |
2379 return 1; | |
2380 default: | |
2381 return 0; | |
2382 } | |
2383 #endif /* _SIMULATION_ */ | |
2384 } | |
2385 | |
2386 #ifdef REL99 | |
2387 /* | |
2388 +--------------------------------------------------------------------+ | |
2389 | PROJECT : GPRS EDGE MODULE : RR_CSF | | |
2390 | STATE : code ROUTINE : get_msc_release_version | | |
2391 +--------------------------------------------------------------------+ | |
2392 | |
2393 PURPOSE : use to get the MSC release version of the serving cell. | |
2394 */ | |
2395 | |
2396 GLOBAL void get_msc_release_version(UBYTE* mscr) | |
2397 { | |
2398 GET_INSTANCE_DATA; | |
2399 T_NC_DATA * rrd; | |
2400 rrd = &rr_data->nc_data[SC_INDEX]; | |
2401 *mscr = rrd->mscr_flag; | |
2402 } | |
2403 #endif | |
2404 | |
2405 | |
2406 /* | |
2407 +--------------------------------------------------------------------+ | |
2408 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2409 | STATE : code ROUTINE : get_bcch_chan_list | | |
2410 +--------------------------------------------------------------------+ | |
2411 | |
2412 PURPOSE : This function returns the network measurement results | |
2413 in the SIM TOOLKIT Format. | |
2414 | |
2415 */ | |
2416 #if defined (_SIMULATION_) | |
2417 /* | |
2418 * predefined values for windows simulation | |
2419 */ | |
2420 static USHORT win_list[MAX_NEIGHBOURCELLS] = { 124, 512, 17, 0xFFFF, | |
2421 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2422 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2423 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2424 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2425 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2426 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2427 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, | |
2428 0xFFFF } ; | |
2429 #endif /* _SIMULATION_ */ | |
2430 /*lint -esym(765,get_bcch_chan_list) | used by SIM */ | |
2431 /*lint -esym(714,get_bcch_chan_list) | used by SIM */ | |
2432 GLOBAL UBYTE get_bcch_chan_list (stk_data_type * out_stk_data) | |
2433 { | |
2434 GET_INSTANCE_DATA; | |
2435 UBYTE i; | |
2436 UBYTE value; | |
2437 #if defined (_SIMULATION_) | |
2438 USHORT * ncell_list = win_list; | |
2439 #else /* _SIMULATION_ */ | |
2440 USHORT * ncell_list = rr_data->act_ncell_list; | |
2441 #endif /* _SIMULATION_ */ | |
2442 | |
2443 #if !defined (_SIMULATION_) | |
2444 switch (GET_STATE (STATE_ATT)) | |
2445 { | |
2446 case ATT_IDLE: | |
2447 case ATT_DEDICATED: | |
2448 #endif /* !_SIMULATION_ */ | |
2449 | |
2450 /* | |
2451 * clear output parameter | |
2452 */ | |
2453 memset (out_stk_data->stk_parameter, 0, sizeof (out_stk_data->stk_parameter)); | |
2454 for (i=0;i<MAX_NEIGHBOURCELLS;i++) | |
2455 { | |
2456 if (ncell_list[i] EQ NOT_PRESENT_16BIT) | |
2457 { | |
2458 /* | |
2459 * if no further channel is available | |
2460 * calculate length in bytes | |
2461 * number of channels a 10 bit | |
2462 */ | |
2463 out_stk_data->stk_length = (i*10+7)/8; | |
2464 return 1; | |
2465 } | |
2466 /* | |
2467 * channel is available | |
2468 * then use basic CCD function to add to bitstream | |
2469 */ | |
2470 value = ncell_list[i] >> 8; | |
2471 ccd_codeByte (out_stk_data->stk_parameter, (USHORT)(i*10), 2, value); | |
2472 value = ncell_list[i] & 0xFF; | |
2473 ccd_codeByte (out_stk_data->stk_parameter, (USHORT)(i*10+2), 8, value); | |
2474 } | |
2475 /* | |
2476 * if no end indicator has been found | |
2477 * and all parameters are channels | |
2478 * calculate length in bytes | |
2479 * number of channels a 10 bit. | |
2480 */ | |
2481 out_stk_data->stk_length = (i*10+7)/8; | |
2482 return 1; | |
2483 #if !defined (_SIMULATION_) | |
2484 default: | |
2485 return 0; | |
2486 } | |
2487 #endif /* _SIMULATION_ */ | |
2488 } | |
2489 | |
2490 | |
2491 #if defined(_SIMULATION_FFS_) | |
2492 | |
2493 /* | |
2494 +--------------------------------------------------------------------+ | |
2495 | PROJECT : GSM-PS (6103) MODULE : RR_CSF | | |
2496 | STATE : code ROUTINE : rr_csf_ffs_init | | |
2497 +--------------------------------------------------------------------+ | |
2498 | |
2499 PURPOSE : | |
2500 | |
2501 */ | |
2502 | |
2503 LOCAL const char rr_white_list_name[] = "/gsm/l3/rr_white_list"; | |
2504 LOCAL const char rr_black_list_name[] = "/gsm/l3/rr_black_list"; | |
2505 LOCAL const char rr_lower_rxlev_thr_name[] = "/gsm/l3/rr_lower_rxlev_thr"; | |
2506 LOCAL const char rr_medium_rxlev_thr_name[] = "/gsm/l3/rr_medium_rxlev_thr"; | |
2507 LOCAL const char rr_upper_rxlev_thr_name[] = "/gsm/l3/rr_upper_rxlev_thr"; | |
2508 LOCAL const char rr_shield_mcc_name[] = "/gsm/l3/shield"; | |
2509 | |
2510 GLOBAL void rr_csf_ffs_init(void) | |
2511 { | |
2512 TRACE_FUNCTION ("rr_csf_ffs_init()"); | |
2513 | |
2514 /* If MM has to create the directories for FFS, there is no point | |
2515 * in carry on with the initialisation | |
2516 */ | |
2517 rr_csf_check_ffs_dirs(); | |
2518 | |
2519 /* Read white list from FFS */ | |
2520 rr_csf_read_white_list(); | |
2521 | |
2522 /* Read Black List from FFS */ | |
2523 rr_csf_read_black_list(); | |
2524 | |
2525 /* Read RXlevel thresholds from FFS */ | |
2526 rr_csf_read_rxlev_thr(); | |
2527 } | |
2528 | |
2529 | |
2530 /* | |
2531 +------------------------------------------------------------------+ | |
2532 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2533 | STATE : code ROUTINE : rr_csf_write_white_list | | |
2534 +------------------------------------------------------------------+ | |
2535 | |
2536 PURPOSE : This function writes the White list information to FFS. | |
2537 CSI-LLD - 4.1.2.2.4 | |
2538 */ | |
2539 | |
2540 GLOBAL void rr_csf_write_white_list(T_CS_WHITE_LIST *white_list) | |
2541 { | |
2542 TRACE_FUNCTION ("rr_csf_write_white_list()"); | |
2543 | |
2544 #if defined(_SIMULATION_) | |
2545 memcpy(&win_white_list,white_list,sizeof(T_CS_WHITE_LIST)); | |
2546 #else | |
2547 rr_csf_check_ffs_dirs(); | |
2548 rr_csf_handle_ffs_write_result(ffs_file_write(rr_white_list_name, | |
2549 white_list, | |
2550 sizeof(T_CS_WHITE_LIST), | |
2551 FFS_O_CREATE | FFS_O_RDWR)); | |
2552 #endif | |
2553 | |
2554 TRACE_EVENT("White List written to FFS"); | |
2555 } | |
2556 | |
2557 /* | |
2558 +-----------------------------------------------------------------+ | |
2559 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2560 | STATE : code ROUTINE : rr_csf_read_white_list | | |
2561 +-----------------------------------------------------------------+ | |
2562 | |
2563 PURPOSE : This function read the White list information from FFS. | |
2564 CSI-LLD - 4.1.2.2.5 | |
2565 */ | |
2566 | |
2567 GLOBAL void rr_csf_read_white_list(void) | |
2568 { | |
2569 GET_INSTANCE_DATA; | |
2570 TRACE_FUNCTION ("rr_csf_read_white_list()"); | |
2571 | |
2572 TRACE_EVENT("Read White List from FFS"); | |
2573 | |
2574 #if defined(_SIMULATION_) | |
2575 memcpy(&rr_data->cs_data.white_list,&win_white_list,sizeof(T_CS_WHITE_LIST)); | |
2576 #else | |
2577 rr_csf_check_ffs_dirs(); | |
2578 if(!rr_csf_handle_ffs_read_result(ffs_file_read(rr_white_list_name, | |
2579 &rr_data->cs_data.white_list, | |
2580 sizeof(T_CS_WHITE_LIST)))) | |
2581 { | |
2582 /* In case of read error, reset the White List */ | |
2583 cs_clear_white_list(CLR_WHITE_LIST_RAM); | |
2584 } | |
2585 #endif | |
2586 } | |
2587 | |
2588 /* | |
2589 +-----------------------------------------------------------------------+ | |
2590 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2591 | STATE : code ROUTINE : rr_csf_write_black_list | | |
2592 +-----------------------------------------------------------------------+ | |
2593 | |
2594 PURPOSE : This function wirtes "Black List" information to FFS. | |
2595 In case of windows simulation environment, "Black List" is | |
2596 stored to simulated FFS area. | |
2597 This function is called during switch off. | |
2598 CSI-LLD section:4.1.1.5.3 | |
2599 */ | |
2600 | |
2601 GLOBAL void rr_csf_write_black_list(T_LIST *black_list) | |
2602 { | |
2603 TRACE_FUNCTION ("rr_csf_write_black_list()"); | |
2604 | |
2605 #if defined(_SIMULATION_) | |
2606 memcpy(&win_black_list[0],black_list,MAX_REGIONS*sizeof(T_LIST)); | |
2607 #else | |
2608 rr_csf_check_ffs_dirs(); | |
2609 rr_csf_handle_ffs_write_result(ffs_file_write (rr_black_list_name, | |
2610 black_list, | |
2611 MAX_REGIONS*sizeof(T_LIST), | |
2612 FFS_O_CREATE | FFS_O_RDWR)); | |
2613 #endif | |
2614 | |
2615 TRACE_EVENT("Black List written to FFS"); | |
2616 } | |
2617 | |
2618 | |
2619 /* | |
2620 +------------------------------------------------------------------------+ | |
2621 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2622 | STATE : code ROUTINE : rr_csf_read_black_list | | |
2623 +------------------------------------------------------------------------+ | |
2624 | |
2625 PURPOSE : This function copies "Black List" information from FFS to RR | |
2626 internal "Black List" data structures. In case of windows | |
2627 simulation environment, "Black List" is read from simulated FFS | |
2628 area. This function is called after power on | |
2629 Cell Selection Improvements-LLD section:4.1.1.5.4 | |
2630 */ | |
2631 | |
2632 GLOBAL void rr_csf_read_black_list(void) | |
2633 { | |
2634 GET_INSTANCE_DATA; | |
2635 TRACE_FUNCTION ("rr_csf_read_black_list()"); | |
2636 | |
2637 TRACE_EVENT("Read Black List from FFS"); | |
2638 | |
2639 #if defined(_SIMULATION_) | |
2640 memcpy(&rr_data->cs_data.black_list.list[0],&win_black_list[0], | |
2641 MAX_REGIONS*sizeof(T_LIST)); | |
2642 #else | |
2643 rr_csf_check_ffs_dirs(); | |
2644 if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_black_list_name, | |
2645 &rr_data->cs_data.black_list.list[0], | |
2646 MAX_REGIONS*sizeof(T_LIST)))) | |
2647 { | |
2648 /* In case of read error, reset the Black List */ | |
2649 cs_clear_black_list(CLR_BLACK_LIST_RAM); | |
2650 } | |
2651 #endif | |
2652 } | |
2653 | |
2654 /* | |
2655 +-----------------------------------------------------------------------+ | |
2656 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2657 | STATE : code ROUTINE : rr_csf_write_rxlev_thr | | |
2658 +-----------------------------------------------------------------------+ | |
2659 | |
2660 PURPOSE : This function wirtes "RXLevel Threshold" information to FFS. | |
2661 In case of windows simulation environment, "RXLevel Threshold" is | |
2662 stored to simulated FFS area. | |
2663 This function is called during dynamic configuration. | |
2664 */ | |
2665 | |
2666 GLOBAL void rr_csf_write_rxlev_thr(UBYTE rxt, SHORT valno, char* val[MAX_NUM_BANDS]) | |
2667 { | |
2668 GET_INSTANCE_DATA; | |
2669 UBYTE i, rxlev_thr_val; | |
2670 UBYTE *rxlev_thr = NULL; | |
2671 #if defined(_SIMULATION_) | |
2672 UBYTE *win_rxlev_thr = NULL; | |
2673 #endif | |
2674 const char *rxlev_thr_name, *rxlev_thr_string; | |
2675 rxlev_thr_name = NULL; | |
2676 rxlev_thr_string = NULL; | |
2677 TRACE_FUNCTION ("rr_csf_write_rxlev_thr()"); | |
2678 | |
2679 switch(rxt) | |
2680 { | |
2681 case U_RXT: rxlev_thr_string = "Upper"; | |
2682 rxlev_thr = &rr_data->dyn_config.upper_rxlev_thr[0]; | |
2683 rxlev_thr_name = &rr_upper_rxlev_thr_name[0]; | |
2684 #if defined(_SIMULATION_) | |
2685 win_rxlev_thr = &win_upper_rxlev_thr[0]; | |
2686 #endif | |
2687 break; | |
2688 case M_RXT: rxlev_thr_string = "Medium"; | |
2689 rxlev_thr = &rr_data->dyn_config.medium_rxlev_thr[0]; | |
2690 rxlev_thr_name = &rr_medium_rxlev_thr_name[0]; | |
2691 #if defined(_SIMULATION_) | |
2692 win_rxlev_thr = &win_medium_rxlev_thr[0]; | |
2693 #endif | |
2694 break; | |
2695 case L_RXT: rxlev_thr_string = "Lower"; | |
2696 rxlev_thr = &rr_data->dyn_config.lower_rxlev_thr[0]; | |
2697 rxlev_thr_name = &rr_lower_rxlev_thr_name[0]; | |
2698 #if defined(_SIMULATION_) | |
2699 win_rxlev_thr = &win_lower_rxlev_thr[0]; | |
2700 #endif | |
2701 break; | |
2702 default: | |
2703 return; | |
2704 } | |
2705 | |
2706 for( i=0 ; i<valno ; i++ ) | |
2707 { | |
2708 rxlev_thr_val = atoi(val[i]); | |
2709 if( rxlev_thr_val > 0 AND rxlev_thr_val <= 63 ) | |
2710 { | |
2711 rxlev_thr[i] = rxlev_thr_val; | |
2712 } | |
2713 else | |
2714 { | |
2715 TRACE_ERROR ("[PEI_CONFIG]: RxLev Threshold(0-63)-Incorrect Range"); | |
2716 } | |
2717 } | |
2718 #if defined(_SIMULATION_) | |
2719 memcpy(win_rxlev_thr,rxlev_thr,MAX_NUM_BANDS*sizeof(UBYTE)); | |
2720 #else | |
2721 rr_csf_check_ffs_dirs(); | |
2722 rr_csf_handle_ffs_write_result(ffs_file_write(rxlev_thr_name, | |
2723 rxlev_thr, | |
2724 MAX_NUM_BANDS*sizeof(UBYTE), | |
2725 FFS_O_CREATE | FFS_O_RDWR)); | |
2726 #endif | |
2727 TRACE_EVENT_P6("%s RxLev Threshold written to FFS: GSM 850=%d, PGSM 900=%d, DCS 1800=%d, PCS 1900=%d, EGSM=%d", | |
2728 rxlev_thr_string, rxlev_thr[B_GSM_850], rxlev_thr[B_GSM_900], | |
2729 rxlev_thr[B_DCS_1800], rxlev_thr[B_PCS_1900], rxlev_thr[B_E_GSM] ); | |
2730 | |
2731 } | |
2732 | |
2733 /* | |
2734 +------------------------------------------------------------------------+ | |
2735 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2736 | STATE : code ROUTINE : rr_csf_read_rxlev_thr | | |
2737 +------------------------------------------------------------------------+ | |
2738 | |
2739 PURPOSE : This function copies "RXLevel Threshold" information from FFS to RR | |
2740 internal "RXLevel Threshold" arrays. In case of windows | |
2741 simulation environment, "RXLevel Threshold" is read from simulated FFS | |
2742 area. This function is called after power on | |
2743 */ | |
2744 | |
2745 GLOBAL void rr_csf_read_rxlev_thr(void) | |
2746 { | |
2747 | |
2748 UBYTE x; | |
2749 GET_INSTANCE_DATA; | |
2750 TRACE_FUNCTION ("rr_csf_read_rxlev_thr()"); | |
2751 | |
2752 TRACE_EVENT("Read RXLevel thresholds from FFS"); | |
2753 | |
2754 #if defined(_SIMULATION_) | |
2755 memcpy(rr_data->dyn_config.lower_rxlev_thr,win_lower_rxlev_thr, | |
2756 MAX_NUM_BANDS*sizeof(UBYTE)); | |
2757 memcpy(rr_data->dyn_config.medium_rxlev_thr,win_medium_rxlev_thr, | |
2758 MAX_NUM_BANDS*sizeof(UBYTE)); | |
2759 memcpy(rr_data->dyn_config.upper_rxlev_thr,win_upper_rxlev_thr, | |
2760 MAX_NUM_BANDS*sizeof(UBYTE)); | |
2761 #else | |
2762 rr_csf_check_ffs_dirs(); | |
2763 if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_lower_rxlev_thr_name, | |
2764 rr_data->dyn_config.lower_rxlev_thr, | |
2765 MAX_NUM_BANDS*sizeof(UBYTE)))) | |
2766 { | |
2767 for( x=0 ; x<MAX_NUM_BANDS ; x++ ) | |
2768 { | |
2769 rr_data->dyn_config.lower_rxlev_thr[x] = LOWER_RXLEV_THRESHOLD; | |
2770 } | |
2771 rr_data->dyn_config.lower_rxlev_thr[B_GSM_850] = LOWER_RXLEV_THRESHOLD_850; | |
2772 } | |
2773 if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_medium_rxlev_thr_name, | |
2774 rr_data->dyn_config.medium_rxlev_thr, | |
2775 MAX_NUM_BANDS*sizeof(UBYTE)))) | |
2776 { | |
2777 for( x=0 ; x<MAX_NUM_BANDS ; x++ ) | |
2778 { | |
2779 rr_data->dyn_config.medium_rxlev_thr[x] = MEDIUM_RXLEV_THRESHOLD; | |
2780 } | |
2781 } | |
2782 if(!rr_csf_handle_ffs_read_result(ffs_file_read (rr_upper_rxlev_thr_name, | |
2783 rr_data->dyn_config.upper_rxlev_thr, | |
2784 MAX_NUM_BANDS*sizeof(UBYTE)))) | |
2785 { | |
2786 for( x=0 ; x<MAX_NUM_BANDS ; x++ ) | |
2787 { | |
2788 rr_data->dyn_config.upper_rxlev_thr[x] = UPPER_RXLEV_THRESHOLD; | |
2789 } | |
2790 } | |
2791 #endif | |
2792 } | |
2793 | |
2794 /* | |
2795 +-----------------------------------------------------------------------+ | |
2796 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2797 | STATE : code ROUTINE : rr_csf_write_mcc_shield_to_ffs| | |
2798 +-----------------------------------------------------------------------+ | |
2799 | |
2800 PURPOSE : This function writes the mcc shield values to FFS | |
2801 */ | |
2802 | |
2803 GLOBAL void rr_csf_write_mcc_shield_to_ffs(void) | |
2804 { | |
2805 GET_INSTANCE_DATA; | |
2806 UBYTE count; | |
2807 TRACE_FUNCTION ("rr_csf_write_mcc_shield_to_ffs()"); | |
2808 | |
2809 rr_csf_check_ffs_dirs(); | |
2810 rr_csf_handle_ffs_write_result(ffs_file_write (rr_shield_mcc_name, | |
2811 &rr_data->dyn_config.mcc_shield, | |
2812 sizeof(T_shield_mcc), | |
2813 FFS_O_CREATE | FFS_O_RDWR)); | |
2814 for(count=0;count<MAX_MCC_SHIELD;count++) | |
2815 { | |
2816 TRACE_EVENT_P5 ( "Shield MCC=%d%d%d enabled=[%d]index=[%d]", | |
2817 rr_data->dyn_config.mcc_shield.mcc[count][0], | |
2818 rr_data->dyn_config.mcc_shield.mcc[count][1], | |
2819 rr_data->dyn_config.mcc_shield.mcc[count][2], | |
2820 rr_data->dyn_config.mcc_shield.enabled, | |
2821 rr_data->dyn_config.mcc_shield.index); | |
2822 } | |
2823 } | |
2824 /* | |
2825 +--------------------------------------------------------------------+ | |
2826 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2827 | STATE : code ROUTINE : rr_csf_mcc_present | | |
2828 +--------------------------------------------------------------------+ | |
2829 | |
2830 PURPOSE : This function is used to find mcc already present or not | |
2831 */ | |
2832 | |
2833 GLOBAL UBYTE rr_csf_mcc_present(UBYTE* mcc_value) | |
2834 { | |
2835 GET_INSTANCE_DATA; | |
2836 U8 count = 0; | |
2837 for(count = 0;count<MAX_MCC_SHIELD;count++) | |
2838 { | |
2839 if((memcmp(rr_data->dyn_config.mcc_shield.mcc[count],mcc_value,SIZE_MCC)EQ 0)) | |
2840 { | |
2841 return TRUE; | |
2842 } | |
2843 } | |
2844 return FALSE; | |
2845 } | |
2846 | |
2847 | |
2848 /* | |
2849 +-----------------------------------------------------------------------+ | |
2850 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2851 | STATE : code ROUTINE : rr_csf_handle_ffs_read_result | | |
2852 +-----------------------------------------------------------------------+ | |
2853 | |
2854 PURPOSE : This function checks the status from FFS and returns | |
2855 TRUE if there is no error and FALSE if there is | |
2856 */ | |
2857 LOCAL BOOL rr_csf_handle_ffs_read_result(T_FFS_SIZE status_read) | |
2858 { | |
2859 if(status_read>0) | |
2860 { | |
2861 TRACE_EVENT ("FFS Read OK"); | |
2862 return TRUE; | |
2863 } | |
2864 else | |
2865 { | |
2866 TRACE_EVENT_P1("FFS Read ERROR - %x", status_read); | |
2867 return FALSE; | |
2868 } | |
2869 } | |
2870 | |
2871 /* | |
2872 +------------------------------------------------------------------------+ | |
2873 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2874 | STATE : code ROUTINE : rr_csf_handle_ffs_write_result | | |
2875 +------------------------------------------------------------------------+ | |
2876 | |
2877 PURPOSE : This function checks the status from FFS and returns | |
2878 TRUE if there is no error and FALSE if there is | |
2879 */ | |
2880 LOCAL BOOL rr_csf_handle_ffs_write_result(T_FFS_RET status_write) | |
2881 { | |
2882 if(status_write >= EFFS_OK) | |
2883 { | |
2884 TRACE_EVENT("FFS Write OK"); | |
2885 if(status_write) | |
2886 TRACE_EVENT_P1 ("Bytes written: %d",status_write); | |
2887 | |
2888 return(TRUE); | |
2889 } | |
2890 else | |
2891 { | |
2892 TRACE_EVENT_P1 ("FFS Write Error - Status: %x",status_write); | |
2893 return(FALSE); | |
2894 } | |
2895 } | |
2896 | |
2897 /* | |
2898 +--------------------------------------------------------------------+ | |
2899 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2900 | STATE : code ROUTINE : rr_csf_check_ffs_dirs | | |
2901 +--------------------------------------------------------------------+ | |
2902 | |
2903 PURPOSE : This routine creates the /gsm/l3 directory for the last used | |
2904 sc arfcn in the FFS. The return result indicates whether either | |
2905 directories existed or not. There is no error handling. | |
2906 */ | |
2907 | |
2908 LOCAL void rr_csf_check_ffs_dirs( void ) | |
2909 { | |
2910 const char gsm_name[] = "/gsm"; | |
2911 const char gsm_l3_name[] = "/gsm/l3"; | |
2912 | |
2913 rr_csf_create_ffs_dirs(gsm_name); | |
2914 rr_csf_create_ffs_dirs(gsm_l3_name); | |
2915 } | |
2916 | |
2917 /* | |
2918 +--------------------------------------------------------------------+ | |
2919 | PROJECT : GSM-PS (6147) MODULE : RR_CSF | | |
2920 | STATE : code ROUTINE : rr_csf_create_ffs_dirs | | |
2921 +--------------------------------------------------------------------+ | |
2922 | |
2923 PURPOSE : This routine calls the ffs_mkdir() routine to create a | |
2924 specified directory. It returns whether the directory | |
2925 existed or not prior to creation. | |
2926 */ | |
2927 LOCAL void rr_csf_create_ffs_dirs(const char *dir_name) | |
2928 { | |
2929 T_FFS_RET status; | |
2930 | |
2931 status=ffs_mkdir(dir_name); | |
2932 switch(status) | |
2933 { | |
2934 case EFFS_EXISTS: | |
2935 case EFFS_OK: | |
2936 break; | |
2937 | |
2938 default: /*Error*/ | |
2939 TRACE_EVENT_P1("Create Dir error - %x",status); | |
2940 break; | |
2941 } | |
2942 } | |
2943 #endif /* _SIMULATION_FFS_ */ | |
2944 | |
2945 #endif |