FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_app/lcc/lcc_env.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 | 945cf7f506b2 |
| children |
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/****************************************************************************** * Power Task (pwr) * Design and coding by Svend Kristian Lindholm, skl@ti.com * * Environment (Riviera) functions * * $Id: pwr_env.c 1.2 Wed, 20 Aug 2003 12:54:50 +0200 skl $ * ******************************************************************************/ #include "lcc/lcc.h" #include "lcc/lcc_env.h" #include "lcc/lcc_task.h" #include "lcc/lcc_trace.h" #include "lcc/lcc_handle_timers.h" #include "rv/rv_defined_swe.h" #include "rvm/rvm_priorities.h" #include "rvm/rvm_api.h" #include "rvm/rvm_use_id_list.h" #include <string.h> #include "abb/abb.h" /* Define a pointer to the PWR environment control block */ T_PWR_CTRL_BLOCK *pwr_ctrl = NULL; /* Define a pointer to the PWR configuration block */ T_PWR_CFG_BLOCK *pwr_cfg = NULL; // Function Prototypes T_RVM_RETURN pwr_init(void); T_RVM_RETURN pwr_start(void); T_RVM_RETURN pwr_stop(T_RV_HDR *msg); T_RVM_RETURN pwr_kill (void); void ttr(unsigned trmask, char *format, ...); void str(unsigned mask, char *string); T_RVM_RETURN pwr_task_init (void); /* Define global pointer to the error function */ static T_RVM_RETURN (*pwr_error_ft) (T_RVM_NAME swe_name, T_RVM_RETURN error_cause, T_RVM_ERROR_TYPE error_type, T_RVM_STRING error_msg); // Handle timers #include "lcc/lcc_handle_timers.c" T_RVM_RETURN lcc_get_info (T_RVM_INFO_SWE *infoSWE) { #if 1 ttw(ttr(TTrEnv, "lcc_get_info(%d):" NL, 0)); #endif /* SWE info */ /* TYPE3 : Blocking by using FFS */ infoSWE->swe_type = RVM_SWE_TYPE_3; infoSWE->type_info.type3.swe_use_id = LCC_USE_ID; infoSWE->type_info.type3.stack_size = LCC_STACK_SIZE; infoSWE->type_info.type3.priority = RVM_LCC_TASK_PRIORITY; infoSWE->type_info.type3.version = LCC_TASK_VERSION; memcpy( infoSWE->type_info.type3.swe_name, "LCC", sizeof("LCC") ); /* Set the return path */ infoSWE->type_info.type3.return_path.callback_func = NULL; infoSWE->type_info.type3.return_path.addr_id = 0; /* memory bank info */ infoSWE->type_info.type3.nb_mem_bank = 1; memcpy ((UINT8 *) infoSWE->type_info.type3.mem_bank[0].bank_name, "LCC_PRIM", 9); infoSWE->type_info.type3.mem_bank[0].initial_params.size = LCC_MB_PRIM_SIZE; infoSWE->type_info.type3.mem_bank[0].initial_params.watermark = LCC_MB_PRIM_WATERMARK; /* Linked SW entities : FIXME: LCC needs SPI & FFS */ infoSWE->type_info.type3.nb_linked_swe = 0; /* generic functions */ infoSWE->type_info.type3.set_info = pwr_set_info; infoSWE->type_info.type3.init = pwr_init; infoSWE->type_info.type3.start = pwr_start; infoSWE->type_info.type3.stop = pwr_stop; infoSWE->type_info.type3.kill = pwr_kill; return RV_OK; } T_RVM_RETURN pwr_set_info(T_RVF_ADDR_ID addr_id, T_RV_RETURN return_path[], T_RVF_MB_ID mbId[], T_RVM_RETURN (*callBackFct) (T_RVM_NAME SWEntName, T_RVM_RETURN errorCause, T_RVM_ERROR_TYPE errorType, T_RVM_STRING errorMsg)) { T_RVF_MB_STATUS mb_status; ttw(ttr(TTrEnv, "pwr_set_info(%d)" NL, addr_id)); ttw(ttr(TTrEnvLow, " mbId[0] = %d" NL, mbId[0])); mb_status = rvf_get_buf(mbId[0],sizeof(T_PWR_CTRL_BLOCK),(void **) &pwr_ctrl); if (mb_status == RVF_RED) { ttr(TTrFatal, "LCC FATAL: no memory: %d" NL, addr_id); return (RVM_MEMORY_ERR); } memset(&pwr_ctrl->state, 0xBA, sizeof(T_PWR_CTRL_BLOCK)); mb_status = rvf_get_buf(mbId[0],sizeof(T_PWR_CFG_BLOCK),(void **) &pwr_cfg); if (mb_status == RVF_RED) { ttr(TTrFatal, "LCC FATAL: no memory: %d" NL, addr_id); return (RVM_MEMORY_ERR); } memset(&pwr_cfg->cal.i2v , 0xBA, sizeof(T_PWR_CFG_BLOCK)); /* store the pointer to the error function */ pwr_error_ft = callBackFct ; /* Store the addr id */ pwr_ctrl->addr_id = addr_id; /* Store the memory bank id */ pwr_ctrl->prim_id = mbId[0]; /* Battery & charging related initialisation */ // State initialisation pwr_ctrl->state = CAL; // Create timers (Initialize...) pwr_create_timer(&pwr_ctrl->time_begin_T0); pwr_create_timer(&pwr_ctrl->time_begin_T1); pwr_create_timer(&pwr_ctrl->time_begin_T2); pwr_create_timer(&pwr_ctrl->time_begin_T3); pwr_create_timer(&pwr_ctrl->time_begin_T4); pwr_create_timer(&pwr_ctrl->time_begin_mod_cycle); pwr_create_timer(&pwr_ctrl->time_begin_mmi_rep); /* Flags initialisation and other state related init */ // Calibration configuration file not read pwr_ctrl->flag_cal_cfg_read = 0; // Charger configuration file not read pwr_ctrl->flag_chg_cfg_read = 0; // Default configuration id used pwr_cfg->data.cfg_id = '1'; // Number of battery identification measurements reported pwr_ctrl->count_bat_type = 0; pwr_ctrl->count_chg_type = 0; // Precharge PRE state - Applies only for 3.2V < Vbat < 3.6V pwr_ctrl->flag_prechg_started = 0; // Charger Interrupts are disabled from the start pwr_ctrl->flag_chg_int_disabled = 1; // First time in INI state pwr_ctrl->flag_ini_virgo = 0; // Default charger type is UNREGULATED // Meaning charger interrupts will not be enabled pwr_cfg->chg.type = UNREGULATED; // Unplug default is that charger is unplugged (0) memset(&pwr_ctrl->chg_unplug_vec , 0x0, CONSECUTIVE_CHG_UNPLUGS); pwr_ctrl->index = 0; // MMI hasn't registered pwr_ctrl->flag_mmi_registered = 0; // Init of plug/unplug state machine - from default the charger is not plugged pwr_ctrl->flag_chg_prev_plugged = 0; return RV_OK; } T_RVM_RETURN pwr_init(void) { T_RVM_RETURN error; // Mask off the charger interrupts (plug/unplug) - in case it was a linear charger // Don't want to get killed in a vast number of interrupts... ABB_Write_Register_on_page(PAGE0, ITMASK, CHARGER_IT_MSK); pwr_ttr_init(0xff000000); pwr_ctrl->tmask = 0xff000000; ttw(ttr(TTrEnv, "pwr_init(%d)" NL, 0)); return RV_OK; } T_RVM_RETURN pwr_start(void) { T_RVM_RETURN error; ttw(ttr(TTrEnv, "pwr_start(%d)" NL, 0)); pwr_task(); ttw(ttr(TTrEnv, "pwr_start(%d)" NL, 0xFF)); return RV_OK; } T_RVM_RETURN pwr_stop(T_RV_HDR *msg) { ttw(ttr(TTrEnv, "pwr_stop(%d)" NL, 0)); return RV_OK; } T_RVM_RETURN pwr_kill (void) { T_RVM_RETURN error; ttw(ttr(TTrEnv, "pwr_kill(%d)" NL, 0)); /* free all memory buffer previously allocated */ rvf_free_buf ((void *) pwr_ctrl); rvf_free_buf ((void *) pwr_cfg); ttw(ttr(TTrEnv, "pwr_kill(%d)" NL, 0xFF)); return RV_OK; }