FreeCalypso > hg > fc-magnetite
view src/aci2/alr/alr_rach.c @ 662:8cd8fd15a095
SIM speed enhancement re-enabled and made configurable
TI's original code supported SIM speed enhancement, but Openmoko had it
disabled, and OM's disabling of speed enhancement somehow caused certain
SIM cards to start working which didn't work before (OM's bug #666).
Because our FC community is much smaller in year 2020 than OM's community
was in their day, we are not able to find one of those #666-affected SIMs,
thus the real issue they had encountered remains elusive. Thus our
solution is to re-enable SIM speed enhancement and simply wait for if
and when someone runs into a #666-affected SIM once again. We provide
a SIM_allow_speed_enhancement global variable that allows SIM speed
enhancement to be enabled or disabled per session, and an /etc/SIM_spenh
file in FFS that allows it to enabled or disabled on a non-volatile
basis. SIM speed enhancement is now enabled by default.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sun, 24 May 2020 05:02:28 +0000 |
| parents | 93999a60b835 |
| children |
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/* +----------------------------------------------------------------------------- | Project : GSM-PS | Modul : ALR_RACH +----------------------------------------------------------------------------- | Copyright 2002 Texas Instruments Berlin, AG | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments Berlin, AG | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments Berlin, AG. +----------------------------------------------------------------------------- | Purpose : This Modul defines the SDL process RACH_Control. +----------------------------------------------------------------------------- */ #ifndef ALR_RACH_C #define ALR_RACH_C #define ENTITY_PL /*==== INCLUDES ===================================================*/ #include <string.h> #include <stdlib.h> #include <ctype.h> #include "typedefs.h" #include "pconst.cdg" #include "mconst.cdg" #include "message.h" #include "ccdapi.h" #include "vsi.h" #include "custom.h" #include "gsm.h" #include "prim.h" #include "cnf_alr.h" #include "mon_alr.h" #include "pei.h" #include "tok.h" #include "pcm.h" #ifdef GPRS #include "alr_gprs.h" #endif #include "alr.h" #include "alr_em.h" /*==== EXPORT =====================================================*/ /*==== PRIVAT =====================================================*/ /*==== VARIABLES ==================================================*/ #if defined (WIN32) #define TRACING #endif #if defined (TRACING) #define ALR_TRACE_RACH(a) ALR_TRACE(a) #else #define ALR_TRACE_RACH(a) #endif #if defined (TRACING) #define ALR_TRACE_RACH_CLASS(x) TRACE_EVENT_P1 ("class %d",x) #define ALR_TRACE_RACH_POWER(p) TRACE_EVENT_P1 ("configured power = %d", p) #else #define ALR_TRACE_RACH_CLASS(x) #define ALR_TRACE_RACH_POWER(p) #endif /*==== FUNCTIONS ==================================================*/ /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : rach_init | +--------------------------------------------------------------------+ PURPOSE : Initialize RACH Control Process. */ GLOBAL void rach_init (void) { alr_data->state[STATE_RA] = RA_NULL; } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : rach_configure_class | +--------------------------------------------------------------------+ PURPOSE : Process signal rach_configure_class from SDL process Main_Control. */ GLOBAL void rach_configure_class (UBYTE ms_class, UBYTE dcs_class) { /* * +1 because of interface difference between RR and TI */ alr_data->rach_data.ms_class = (UBYTE)(ms_class + 1); alr_data->rach_data.dcs_class = (UBYTE)(dcs_class + 1); ALR_TRACE_RACH_CLASS (alr_data->rach_data.ms_class); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : rach_configure_power | +--------------------------------------------------------------------+ PURPOSE : Process signal rach_configure_power from SDL process Main_Control. */ GLOBAL void rach_configure_power (UBYTE power) { ALR_TRACE_RACH_POWER(power); alr_data->rach_data.max_tx_pwr_ccch = power; } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : rach_stop | +--------------------------------------------------------------------+ PURPOSE : Process signal rach_stop from SDL process Main_Control. */ GLOBAL void rach_stop (void) { switch (GET_STATE (STATE_RA)) { case RA_ACTIVE: ma_rach_stop_ra_req (); /*lint -fallthrough*/ case RA_LISTEN_TO_CCCH: SET_STATE (STATE_RA, RA_NULL); break; default: break; } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : rach_random_req | +--------------------------------------------------------------------+ PURPOSE : Process signal rach_random_req from SDL process Main_Control. */ GLOBAL void rach_random_req (T_MPH_RANDOM_ACCESS_REQ *random_req) { switch (GET_STATE (STATE_RA)) { case RA_NULL: if (random_req->send_mode.no NEQ 0) { PALLOC (ra_req, MPHC_RA_REQ); ALR_EM_START_CONNECTION_ESTABLISHMENT; /* * Start Random Burst Sending */ memcpy (alr_data->rach_data.delta, random_req->send_mode.delta, sizeof (alr_data->rach_data.delta)); memcpy (alr_data->rach_data.channel_request, random_req->send_mode.rach, sizeof (alr_data->rach_data.channel_request)); alr_data->rach_data.max_bursts = random_req->send_mode.no; alr_data->rach_data.c_burst = 0; /* * power limitation */ ra_req->txpwr = cut_power_value (alr_data->rach_data.max_tx_pwr_ccch, NULL); ra_req->powerclass_gsm = alr_data->rach_data.ms_class; ra_req->powerclass_dcs = alr_data->rach_data.dcs_class; /* * Modification: Add 1 to the time of RR !!!! */ ra_req->rand = (UBYTE)(alr_data->rach_data.delta[alr_data->rach_data.c_burst]+1); ra_req->channel_request = alr_data->rach_data.channel_request[alr_data->rach_data.c_burst++]; SET_STATE (STATE_RA, RA_ACTIVE); ma_rach_ra_req (ra_req); } break; case RA_ACTIVE: if (random_req->send_mode.no EQ 0) { ALR_EM_STOP_CONNECTION_ESTABLISHMENT; SET_STATE (STATE_RA, RA_LISTEN_TO_CCCH); ma_rach_stop_ra_req (); } else { /*stop to be safe */ ma_rach_stop_ra_req (); { PALLOC (ra_req, MPHC_RA_REQ); ALR_EM_START_CONNECTION_ESTABLISHMENT; /* * Start Random Burst Sending */ memcpy (alr_data->rach_data.delta, random_req->send_mode.delta, sizeof (alr_data->rach_data.delta)); memcpy (alr_data->rach_data.channel_request, random_req->send_mode.rach, sizeof (alr_data->rach_data.channel_request)); alr_data->rach_data.max_bursts = random_req->send_mode.no; alr_data->rach_data.c_burst = 0; /* * power limitation */ ra_req->txpwr = cut_power_value (alr_data->rach_data.max_tx_pwr_ccch, NULL); ra_req->powerclass_gsm = alr_data->rach_data.ms_class; ra_req->powerclass_dcs = alr_data->rach_data.dcs_class; /* * Modification: Add 1 to the time of RR !!!! */ ra_req->rand = (UBYTE)(alr_data->rach_data.delta[alr_data->rach_data.c_burst]+1); ra_req->channel_request = alr_data->rach_data.channel_request[alr_data->rach_data.c_burst++]; SET_STATE (STATE_RA, RA_ACTIVE); ma_rach_ra_req (ra_req); } /*PALLOC*/ } /* if */ break; default: break; } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : rach_ra_cnf | +--------------------------------------------------------------------+ PURPOSE : Process signal rach_ra_cnf from SDL process Main_Control. */ GLOBAL void rach_ra_cnf (T_MPHC_RA_CON *ra_cnf) { UBYTE c_burst = alr_data->rach_data.c_burst-1; /* confirmed index */ switch (GET_STATE (STATE_RA)) { case RA_ACTIVE: { PALLOC (random_cnf, MPH_RANDOM_ACCESS_CNF); ra_cnf->fn %= 42432L; #ifdef GPRS alr_data->rach_data.t1[c_burst] = random_cnf->frame_no.t1= (UBYTE)((ra_cnf->fn / 1326) % 32); alr_data->rach_data.t2[c_burst] = random_cnf->frame_no.t2= (UBYTE)(ra_cnf->fn % 26); alr_data->rach_data.t3[c_burst] = random_cnf->frame_no.t3= (UBYTE)(ra_cnf->fn % 51); #else random_cnf->frame_no.t1= (UBYTE)((ra_cnf->fn / 1326) % 32); random_cnf->frame_no.t2= (UBYTE)(ra_cnf->fn % 26); random_cnf->frame_no.t3= (UBYTE)(ra_cnf->fn % 51); #endif ma_rach_random_cnf (random_cnf); c_burst++; /* next index */ if (c_burst >= alr_data->rach_data.max_bursts) {/* last index ? */ SET_STATE (STATE_RA, RA_LISTEN_TO_CCCH); ma_rach_stop_ra_req (); #if !defined(TNNN_WITH_TIMER) ma_fake_rr_report(); #endif /* !TNNN_WITH_TIMER */ } else { PALLOC (ra_req, MPHC_RA_REQ); /* * power limitation */ ra_req->txpwr = cut_power_value (alr_data->rach_data.max_tx_pwr_ccch, NULL); ra_req->powerclass_gsm = alr_data->rach_data.ms_class; ra_req->powerclass_dcs = alr_data->rach_data.dcs_class; /* * Modification: Add 1 to the time of RR !!!! */ ra_req->rand = (UBYTE)(alr_data->rach_data.delta[c_burst]+1); ra_req->channel_request = alr_data->rach_data.channel_request[c_burst]; ma_rach_ra_req (ra_req); alr_data->rach_data.c_burst++; /* the next index */ } break; } default: break; } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (6103) MODULE : ALR_RACH | | STATE : code ROUTINE : cut_power_value | +--------------------------------------------------------------------+ PURPOSE : Cut the nominal maximum output power to the associated power class. (Reference for the tables with the associated power classes, control levels and nominal output power is 3GPP TS 05.05, 4.1) */ GLOBAL UBYTE cut_power_value (UBYTE power, T_MPH_DEDICATED_REQ *mph_dedicated_req) { UBYTE new_power = power; UBYTE sc_band; if(mph_dedicated_req == NULL) { sc_band = alr_data->sc_band; } else { if(mph_dedicated_req->ch_type.h) sc_band = get_band(mph_dedicated_req->ch_type.ma[0]); else sc_band = get_band(mph_dedicated_req->ch_type.arfcn); } switch (sc_band) { case BAND_GSM_900: case BAND_E_GSM: case BAND_GSM_850: switch (alr_data->rach_data.ms_class) { case POW_CLASS_1: /* doesn´t exist */ case POW_CLASS_2: /* power class 2, 8W, 39 dBm, level 0..2 */ /* highest level allowed => no cut necessary */ break; case POW_CLASS_3: /* power class 3, 5W, 37 dBm, level 3 */ if (new_power < 3) new_power = 3; break; case POW_CLASS_4: /* power class 4, 2W, 33 dBm, level 5 */ if (new_power < 5) new_power = 5; break; case POW_CLASS_5: /* power class 5, 0.8W, 29 dBm, level 7 */ if (new_power < 7) new_power = 7; break; } break; case BAND_DCS_1800: switch (alr_data->rach_data.dcs_class) { case POW_CLASS_1: /* power class 1, 1W, 30 dBm, level 0 */ if (new_power > 28) new_power = 0; break; case POW_CLASS_2: /* power class 2, 0.25W, 24 dBm, level 3 */ if (!INRANGE (3, new_power, 28)) new_power = 3; break; case POW_CLASS_3: /* power class 3, 4W, 36 dBm , level 29 */ /* highest level allowed => no cut necessary */ break; } break; case BAND_PCS_1900: switch (alr_data->rach_data.dcs_class) { case POW_CLASS_1: /* power class 1, 1W, 30 dBm, level 0 */ if (!INRANGE (0, new_power, 15)) new_power = 0; break; case POW_CLASS_2: /* power class 2, 0.25W, 24 dBm, level 3 */ if (!INRANGE (3, new_power, 15)) new_power = 3; break; default: case POW_CLASS_3: /* power class 3, 2W, 33 dBm , level 30 */ /* highest level allowed => no cut necessary */ break; } break; } return new_power; } #endif