FreeCalypso > hg > fc-tourmaline
view src/g23m-gsm/ss/ss_em.h @ 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 | fa8dc04885d8 |
| children |
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/* +----------------------------------------------------------------------------- | Project : | Modul : +----------------------------------------------------------------------------- | Copyright 2002 Texas Instruments Berlin, AG | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments Berlin, AG | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments Berlin, AG. +----------------------------------------------------------------------------- | Purpose : Engineering Mode (EM) Declarations + Macros | +----------------------------------------------------------------------------- */ #ifndef SS_EM_H #define SS_EM_H #ifdef FF_EM_MODE /* * Ring buffer is by one bigger than max. number of prims, because it * needs always one termination entry. * To optimize the buffersize, the data is packed in the buffer as follows: * type, length, value * Value is the combination of the additional parameters as defined in 8443.601, coded as UBYTE. */ #define EM_SS_BUFFER_SIZE 31 /* * EM_MAX_SS_EVENTS defines maximum number of event traces for the engineering mode. * The number is increased by one to ensure that the event numbers defined in the * corresponding document are the same as in the sources. */ #define EM_MAX_SS_EVENTS 11 /* * The offset is used to indicate the source entity the event trace is from. * L1/ALR = 0x00, DL = 0x2D, RR = 0x37, MM = 0x5F, CC = 0x78, SS = 0xAF, SMS = 0xBE, SIM = E1 */ #define SS_OFFSET 0xAF /* * Type is combination of entity index(upper nibble) plus event number(lower nibble). * Bit 8 7 6 5 4 3 2 1 * | entity | event number | */ #define SS_V_1 (1 + SS_OFFSET) #define SS_V_2 (2 + SS_OFFSET) #define SS_V_3 (3 + SS_OFFSET) #define SS_V_4 (4 + SS_OFFSET) #define SS_V_5 (5 + SS_OFFSET) #define SS_V_6 (6 + SS_OFFSET) #define SS_V_7 (7 + SS_OFFSET) #define SS_V_8 (8 + SS_OFFSET) #define SS_V_9 (9 + SS_OFFSET) #define SS_V_10 (10+ SS_OFFSET) /* Event tracing flags for EM */ EXTERN BOOL ss_v[EM_MAX_SS_EVENTS]; /* -- Functions ----*/ /* * suppl. services primitives Engineering Mode * Bitmask for the event tracing */ EXTERN void ss_em_ss_event_req (T_EM_SS_EVENT_REQ *em_ss_event_req); GLOBAL void em_init_ss_event_trace (void); /* * If all entities are linked into one module this definitions * prefixes all this functions with the enity name */ #ifdef OPTION_MULTITHREAD #define em_write_buffer_3 _ENTITY_PREFIXED(em_write_buffer_3) #define check_write_index _ENTITY_PREFIXED(check_write_index) #endif EXTERN UBYTE em_write_buffer_3 (UBYTE event_no, UBYTE value); EXTERN UBYTE check_write_index (UBYTE n); /*---------------Event Macros ----------*/ #define MM_EM_MM_CONNECTION_STARTED\ /* MM connection started */\ if (ss_v[1])\ {\ ss_v[1] = em_write_buffer_3 (SS_V_1 , ss_data->ti);\ } /* ss_v[1] */ #define MM_EM_MM_CONNECTION_ESTABLISHED\ /* MM connection established */\ if (ss_v[2])\ {\ ss_v[2] = em_write_buffer_3 (SS_V_2 , ss_data->ti);\ } /* ss_v[2] */ #define MM_EM_MM_CONNECTION_FAILED\ /* MM connection failed */\ if (ss_v[3])\ {\ ss_v[3] = em_write_buffer_3 (SS_V_3 , ss_data->ti);\ } /* ss_v[3] */ #define MM_EM_MM_CONNECTION_ABORTED\ /* MM connection aborted */\ if (ss_v[4])\ {\ ss_v[4] = em_write_buffer_3 (SS_V_4 , ss_data->ti);\ } /* ss_v[4] */ #define MM_EM_MM_CONNECTION_RELEASED\ /* MM connection released */\ if (ss_v[5])\ {\ ss_v[5] = em_write_buffer_3 (SS_V_5 , ss_data->ti);\ } /* ss_v[5] */ #define MM_EM_REGISTER_MESSAGE_RECEIVED\ /* Register message received */\ if (ss_v[6])\ {\ ss_v[6] = em_write_buffer_3 (SS_V_6 , ss_data->ti);\ } /* ss_v[6] */ #define MM_EM_FACILITY_MESSAGE_SENT\ /* Facility message send */\ if (ss_v[7])\ {\ ss_v[7] = em_write_buffer_3 (SS_V_7 , ss_data->ti);\ } /* ss_v[7] */ #define MM_EM_FACILITY_MESSAGE_RECEIVED\ /* Facility message received */\ if (ss_v[8])\ {\ ss_v[8] = em_write_buffer_3 (SS_V_8 , ss_data->ti);\ } /* ss_v[8] */ #define MM_EM_MM_RELEASE_COMPLETE_SENT\ /* Release complete sent */\ if (ss_v[9])\ {\ ss_v[9] = em_write_buffer_3 (SS_V_9 , ss_data->ti);\ } /* ss_v[9] */ #define MM_EM_MM_RELEASE_COMPLETE_RECEIVED\ /* Release complete received */\ if (ss_v[10])\ {\ ss_v[10] = em_write_buffer_3 (SS_V_10, ss_data->ti);\ } /* ss_v[10] */ #else /*FF_EM_MODE not defined*/ #define MM_EM_MM_CONNECTION_STARTED /*Event 1*/ #define MM_EM_MM_CONNECTION_ESTABLISHED /*Event 2*/ #define MM_EM_MM_CONNECTION_FAILED /*Event 3*/ #define MM_EM_MM_CONNECTION_ABORTED /*Event 4*/ #define MM_EM_MM_CONNECTION_RELEASED /*Event 5*/ #define MM_EM_REGISTER_MESSAGE_RECEIVED /*Event 6*/ #define MM_EM_FACILITY_MESSAGE_SENT /*Event 7*/ #define MM_EM_FACILITY_MESSAGE_RECEIVED /*Event 8*/ #define MM_EM_MM_RELEASE_COMPLETE_SENT /*Event 9*/ #define MM_EM_MM_RELEASE_COMPLETE_RECEIVED /*Event 10*/ #endif /*FF_EM_MODE*/ #endif /* SS_EM_H */