FreeCalypso > hg > fc-tourmaline
view src/cs/services/cst/cst_csf.c @ 221:5bf097aeaad7
LLS: when turning off all LEDs on boot, skip LED-C
Having LLS turn off LED-A and LED-B on boot is normally unnecessary
(they should already be off in Iota), but it is harmless, hence this
logic is kept for robustness. However, having LLS read-modify-write
the BCICTL2 register (to turn off LED-C) creates a potential race
condition with FCHG writes to this register, especially in the case
when baseband switch-on is caused by VCHG and charging is expected
to start right away. Furthermore, control of the charging LED itself
(on those hw targets that have it) is the responsibility of the FCHG
SWE, hence LLS should leave it alone.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Mon, 26 Apr 2021 21:55:13 +0000 |
| parents | 4e78acac3d88 |
| children | fa22012c4a39 |
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/* +-------------------------------------------------------------------+ | PROJECT: GSM-F&D (8411) $Workfile:: cst_csf.c $| | $Author:: Be $ CONDAT GmbH $Revision:: 7 $| | CREATED: 01.02.99 $Modtime:: 1.12.99 13:16 $| | STATE : code | +--------------------------------------------------------------------+ MODULE : CST_CSF PURPOSE : This Modul defines the custom specific functionalitys for the entity CST. */ #ifndef CST_CSF_C #define CST_CSF_C #endif #include "config/swconfig.cfg" #include "config/board.cfg" #define ENTITY_CST /*==== INCLUDES ===================================================*/ #include <string.h> #include "typedefs.h" #include "vsi.h" #include "gsm.h" #include "p_cst.h" #include "cst/cst.h" /*==== CONSTANTS ==================================================*/ /*==== TYPES ======================================================*/ /*==== EXPORT =====================================================*/ /*==== VARIABLES ==================================================*/ LOCAL USHORT ADC_CONVERSIONS[9]; /*==== FUNCTIONS ==================================================*/ #ifdef ALR extern void madc_hex_2_physical (USHORT *adc_hex, USHORT *adc_phy); #endif #if (BOARD==34) extern inline unsigned char GC_GetAdcInfo(void); #endif /* +--------------------------------------------------------------------+ | PROJECT : XXX MODULE : CST_CSF | | STATE : code ROUTINE : csf_adc_start | +--------------------------------------------------------------------+ PURPOSE : This function sends a primitive to L1A to activate the ADC */ GLOBAL void csf_adc_start (UBYTE tx_flag, UBYTE traffic_period, UBYTE idle_period) { // This structure and the #define have to be implemented in the MMI. // This is a temporary location for test !!!!!!! // TO BE REMOVED BY USER typedef struct { UBYTE tx_flag; UBYTE traffic_period; UBYTE idle_period; } T_MMI_ADC_REQ; #define MMI_ADC_REQ (111) PALLOC(adc_req, MMI_ADC_REQ); adc_req->tx_flag = tx_flag; adc_req->traffic_period = traffic_period; adc_req->idle_period = idle_period; PSENDX (L1, adc_req); } /* +--------------------------------------------------------------------+ | PROJECT : XXX MODULE : CST_CSF | | STATE : code ROUTINE : csf_adc_process | +--------------------------------------------------------------------+ PURPOSE : This function processes ADC results. It stores 10 consecutive results in an array. */ GLOBAL void csf_adc_process (T_CST_ADC_IND *adc_results) { #ifdef ALR volatile USHORT adc_converted[9]; #endif #ifdef ALR /* convert adc value into physical values */ madc_hex_2_physical (adc_results->adc_values, (USHORT*) adc_converted); ADC_CONVERSIONS[0] = adc_converted[0]; /* Battery Voltage */ ADC_CONVERSIONS[1] = adc_converted[1]; /* Charger Voltage */ ADC_CONVERSIONS[2] = adc_converted[2]; /* I Charger */ ADC_CONVERSIONS[3] = adc_converted[3]; /* I Charger */ ADC_CONVERSIONS[4] = adc_converted[4]; /* Battery Type */ ADC_CONVERSIONS[5] = adc_converted[5]; /* Battery Temperature */ ADC_CONVERSIONS[6] = adc_converted[6]; /* RF temperature */ ADC_CONVERSIONS[7] = adc_converted[7]; /* Touch Screen X */ ADC_CONVERSIONS[8] = adc_converted[8]; /* Touch Screen Y */ #else ADC_CONVERSIONS[0] = adc_results->adc_values[0]; ADC_CONVERSIONS[1] = adc_results->adc_values[1]; ADC_CONVERSIONS[2] = adc_results->adc_values[2]; ADC_CONVERSIONS[3] = adc_results->adc_values[3]; ADC_CONVERSIONS[4] = adc_results->adc_values[4]; #endif // WCS Patch :Avenger 2 uses adc index 5 to store battery informations bit field #if (BOARD == 34) ADC_CONVERSIONS[5] = GC_GetAdcInfo(); #endif PFREE (adc_results); } /* +--------------------------------------------------------------------+ | PROJECT : XXX MODULE : CST_CSF | | STATE : code ROUTINE : csf_aec_enable | +--------------------------------------------------------------------+ PURPOSE : This function sends a primitive to L1A to activate the AEC */ GLOBAL void csf_aec_enable (USHORT aec_ctrl_reg) { // This structure and the #define have to be implemented in the MMI. // This is a temporary location for test !!!!!!! // TO BE REMOVED BY USER typedef struct { USHORT aec_control; } T_MMI_AEC_REQ; #define MMI_AEC_REQ ( ( ( 0x18 ) << 8 ) | 40 ) PALLOC(aec_req, MMI_AEC_REQ); aec_req->aec_control = aec_ctrl_reg; PSENDX (L1, aec_req); } /* Returns the ADC conversions results array */ GLOBAL USHORT * csf_return_adc (void) { return &(ADC_CONVERSIONS[0]); } #ifdef ALR /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (8403) MODULE : CST_CSF | | STATE : code ROUTINE : csf_vm_record | +--------------------------------------------------------------------+ PURPOSE : activate the Voice Memo recording process for a ten seconds duration */ GLOBAL void csf_vm_record (CHAR *output, UBYTE vm_flash_index) { // Dummy function } /* +--------------------------------------------------------------------+ | PROJECT : GSM-PS (8403) MODULE : CST_CSF | | STATE : code ROUTINE : csf_vm_play | +--------------------------------------------------------------------+ PURPOSE : activate the Voice Memo playing process */ GLOBAL void csf_vm_play (CHAR *output, UBYTE vm_flash_index) { // Dummy function } #endif