FreeCalypso > hg > fc-tourmaline
view src/g23m-fad/fad/fad_rcvp.c @ 281:a75eefbf8be4
Phone boot with PWON: weed out short button presses
Every standard end user phone has a design provision, most naturally
implemented in firmware, whereby the PWON button effects a boot only
if it is held down long enough - short presses of this PWON button
are detected, assumed to be spurious and cause the fw to power back off
instead of proceeding with boot. The present change introduces this
standard function in FreeCalypso.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Fri, 24 Sep 2021 02:03:08 +0000 |
parents | fa8dc04885d8 |
children |
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/* +----------------------------------------------------------------------------- | Project : GSM-F&D (8411) | Modul : FAD_RCVP +----------------------------------------------------------------------------- | 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 functions for processing | of incomming primitives for the component | Fax Adaptation 3.45 of the mobile station +----------------------------------------------------------------------------- */ #ifndef FAD_RCVP_C #define FAD_RCVP_C #endif #define ENTITY_FAD /*==== INCLUDES ===================================================*/ #include <string.h> #include "typedefs.h" #include "vsi.h" #include "macdef.h" #include "pconst.cdg" #include "custom.h" #include "gsm.h" #include "cnf_fad.h" #include "mon_fad.h" #include "prim.h" #include "pei.h" #include "tok.h" #include "ccdapi.h" #include "fad.h" /*==== CONST =======================================================*/ /*==== TYPES =======================================================*/ /*==== VAR EXPORT ==================================================*/ /*==== VAR LOCAL ===================================================*/ /*==== FUNCTIONS ===================================================*/ LOCAL void AlignByte(UBYTE *byte) { const USHORT tbl[] = { 0x7E00, /* 01111110 00000000 */ 0x00FC, /* 00000000 11111100 */ 0x01F8, /* 00000001 11111000 */ 0x03F0, /* 00000011 11110000 */ 0x07E0, /* 00000111 11100000 */ 0x0FC0, /* 00001111 11000000 */ 0x1F80, /* 00011111 10000000 */ 0x3F00, /* 00111111 00000000 */ }; UBYTE i; T_RCV *Rcv = &fad_data->rcv; if (Rcv->FlagFound EQ 0) /* initialization */ Rcv->AlignWord = *byte; Rcv->AlignWord <<= 8; Rcv->AlignWord += *byte; if (Rcv->FlagFound < FLAGFOUND_MIN) { for (i = 0; i < 8; i++) { if (tbl[i] EQ (Rcv->AlignWord & tbl[i]) AND ((UBYTE)(Rcv->AlignWord >> i) EQ HDLC_FLAG)) { if (Rcv->AlignShift NEQ i) { Rcv->AlignShift = i; Rcv->FlagFound = 0; } Rcv->FlagFound++; break; } } } if (Rcv->FlagFound EQ FLAGFOUND_MIN) *byte = (UBYTE)(Rcv->AlignWord >> Rcv->AlignShift); } LOCAL void align_ra_data_ind(T_FD *pFD) { USHORT i; for (i = 0; i < pFD->len >> 1; i++) { AlignByte(&pFD->buf[2*i+1]); } } #ifdef _TARGET_ void switch_ra_detect_req(UBYTE detect) { T_RA_DETECT_REQ ra_detect_req; ra_detect_req.detect = detect; l1i_ra_detect_req (&ra_detect_req); } #endif /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : FAD_RCVP | | STATE : code ROUTINE : rcv_ra_data_ind | +--------------------------------------------------------------------+ PURPOSE : Process primitive RA_DATA_IND received from RA. */ GLOBAL void rcv_ra_data_ind (T_RA_DATA_IND *ra_data_ind) { T_RCV *rcv = &fad_data->rcv; UBYTE frame_type; T_FD *pFD; TRACE_FUNCTION ("rcv_ra_data_ind()"); if (GET_STATE(KER) EQ KER_NULL) return; #ifdef _SIMULATION_ PACCESS(ra_data_ind); if (GET_STATE(KER) NEQ KER_NULL) { pFD = cl_ribu_get_new_frame_desc(fad_data->rbm.ribu); pFD->type = ra_data_ind->fr_type; pFD->len = ra_data_ind->sdu.l_buf >> 3; memcpy(pFD->buf, ra_data_ind->sdu.buf, pFD->len); } PFREE (ra_data_ind); #endif if (fad_data->rbm.ribu->idx.filled > 1) TRACE_EVENT_P3("rbm: filled=%d; wi=%d; ri=%d", fad_data->rbm.ribu->idx.filled, fad_data->rbm.ribu->idx.wi, fad_data->rbm.ribu->idx.ri); pFD = cl_ribu_get(fad_data->rbm.ribu); if (pFD->type EQ FR_STATUS) { #if defined TRACE_FAD_DL_STATUS || defined _SIMULATION_ { char buf[14] = "RS:0x ->0x "; BYTE2HEXSTR(*(pFD->buf+1), &buf[5]); align_ra_data_ind(pFD); BYTE2HEXSTR(*(pFD->buf+1), &buf[11]); TRACE_EVENT(buf); } #else align_ra_data_ind(pFD); #endif } frame_type = rcv_FrameType(pFD); switch (GET_STATE (RCV)) { case SYNC_RCV: switch (frame_type) { case FT_PREAMBLE: rcv->bytes_expect = PREAMBLE_BYTES_TI_EXP; rcv->bytes_expect -= pFD->len; SET_STATE (RCV, PREAM_RCV); if (!rcv->data_in_rbm) { sig_rcv_ker_preamble_ind(); #ifdef _SIMULATION_ TRACE_EVENT ("BCS-TRA:first PREAMBLE FLAG rcvd"); #endif } else { rcv->preamble_pending = TRUE; #ifdef _SIMULATION_ TRACE_EVENT ("BCS-TRA:first PREAM FLAG rcvd (p)"); #endif } break; case FR_TRAIN: SET_STATE (RCV, TRAIN_RCV); /* * set READY flag to send first DATA to T30 */ rcv->t30_req_frames = TRUE; sig_rcv_ker_train_ind(); break; case FT_TRAIN_RESPONSE: sig_rcv_ker_status_ind(); break; default: break; } break; /* case SYNC_RCV: */ case PREAM_RCV: if (frame_type EQ FR_STATUS) { if (rcv->bytes_expect <= pFD->len) { rcv->bytes_expect = 0; SET_STATE (RCVSUB, SUB_PREAMBLE); #ifdef _SIMULATION_ TRACE_EVENT ("BCS-TRA:PREAM time elapsed"); #endif SET_STATE (RCV, BCS_RCV); } else rcv->bytes_expect -= pFD->len; } break; /* case PREAM_RCV: */ case BCS_RCV: switch (GET_STATE (RCVSUB)) { case SUB_IDLE: if (frame_type EQ FR_SYNC) { if (!rcv->data_in_rbm) { sig_rcv_ker_bcs_ind(rcv->hdlc, rcv->hdlc_len); #ifdef _SIMULATION_ TRACE_EVENT ("BCS-TRA:SYNC rec - HDLC compl"); #endif } else { rcv->bcs_pending = TRUE; #ifdef _SIMULATION_ TRACE_EVENT ("BCS-TRA:SYNC rec - HDLC compl (p)"); #endif } rcv_ResetFormatter(); SET_STATE (RCV, SYNC_RCV); } break; case SUB_DATA: switch (frame_type) { case FR_SYNC: sig_rcv_ker_bcs_ind (rcv->hdlc, rcv->hdlc_len); #ifdef _SIMULATION_ TRACE_EVENT ("BCS-TRA:SYNC rec - HDLC compl"); #endif rcv_ResetFormatter (); SET_STATE (RCV, SYNC_RCV); break; case FR_STATUS: if (rcv->hdlc_len + pFD->len > HDLC_LEN) { SET_STATE (RCVSUB, SUB_IDLE); TRACE_EVENT ("BCS-TRA:HDLC frame too long !!!"); break; } rcv_SetHdlcFrame(pFD, &rcv->hdlc[rcv->hdlc_len], &rcv->hdlc_len); break; default: /* discard non-HDLC data */ break; } break; default: break; } break; /* case BCS_RCV: */ case TCF_RCV: switch (GET_STATE (RCVSUB)) { case SUB_IDLE: if (frame_type NEQ FR_SYNC) { rcv->bytes_expect = snd_DurationToBytes (fad_data->snd.trans_rate, TIME_TCF_RCV); rcv->bytes_expect -= pFD->len; rcv->bytes_rcvd = 0; rcv->bytes_good = 0; SET_STATE (RCVSUB, SUB_TCF); TRACE_EVENT("SET_STATE (RCVSUB, SUB_TCF)"); } break; case SUB_TCF: if (frame_type EQ FR_SYNC) { #ifdef BMI_TCF_WORKAROUND if (rcv->bytes_rcvd < rcv->bytes_expect) /* ignore TCF frames which are destroyed by BMI */ break; #endif sig_rcv_ker_tcf_ind(); rcv_ResetFormatter(); TRACE_EVENT ("MSG-TRA: rec TCF compl (too short)"); SET_STATE (RCV, SYNC_RCV); } else if (frame_type EQ FR_STATUS) { rcv_ResetFormatter(); TRACE_EVENT ("MSG-TRA: rec FR_STATUS during SUB_TCF"); SET_STATE (KER, IDLE); SET_STATE (RCV, SYNC_RCV); } else /* frame_type NEQ FR_SYNC */ { rcv->bytes_rcvd += pFD->len; if (rcv->bytes_expect <= pFD->len) { rcv->bytes_expect = 0; SET_STATE (RCVSUB, SUB_POST_TCF); } else rcv->bytes_expect -= pFD->len; rcv_SetErrorRatio(pFD); } break; case SUB_POST_TCF: if (frame_type EQ FR_SYNC) { sig_rcv_ker_tcf_ind(); rcv_ResetFormatter(); TRACE_EVENT ("MSG-TRA:rec TCF compl"); SET_STATE (RCV, SYNC_RCV); } else { while (fad_data->rbm.ribu->idx.filled) { cl_ribu_read_index(&fad_data->rbm.ribu->idx); #ifdef _SIMULATION_ TRACE_EVENT_P3("ribu: f=%2d - w=%2d - r=%2d - SUB_POST_TCF", fad_data->rbm.ribu->idx.filled, fad_data->rbm.ribu->idx.wi, fad_data->rbm.ribu->idx.ri); #endif } } break; default: rcv_ResetFormatter (); SET_STATE (RCV, SYNC_RCV); sig_rcv_ker_error_ind (ERR_FAD_SUB_TCF); break; } break; /* case TCF_RCV: */ case TRAIN_RCV: switch (frame_type) { case FR_T4DATA: { #ifdef _TARGET_ switch_ra_detect_req(DET_NO_STATUS); #else /* * handling of first frame restored */ rcv->train_flg = FALSE; rcv->data_incoming = TRUE; if (!rcv_StoreMsgData (pFD, &rcv->prim_ready)) { rcv->t30_req_frames = FALSE; rcv_ResetFormatter (); SET_STATE (RCV, SYNC_RCV); sig_rcv_ker_error_ind (ERR_OVERFLOW_BCS_RCV); break; } rcv->data_in_rbm = TRUE; /* check if T30 READY flag set */ if (rcv->t30_req_frames) sig_ker_rcv_ready_req (); #endif TRACE_EVENT ("MSG-TRA:TRAIN compl"); rcv->data_incoming = TRUE; rcv->bytes_expect = REPEAT_FOREVER; rcv->train_flg = TRUE; /*???*/ SET_STATE (RCV, MSG_RCV); sig_rcv_ker_train_end_ind (); /* first MSG data received: resume sending SYNCS */ break; } default: break; } break; /* case TRAIN_RCV: */ case MSG_RCV: switch (frame_type) { case FR_SYNC: if (rcv->train_flg EQ FALSE) /*???*/ { #ifdef _TARGET_ switch_ra_detect_req(DET_STATUS); #endif TRACE_EVENT ("MSG-TRA:DATA compl"); rcv->data_incoming = FALSE; if (!fad_data->ker.forward_data) { rcv->t30_req_frames = FALSE; sig_rcv_ker_msg_ind (NULL); } if (rcv->t30_req_frames) rcv_SetFinalBuffer (); SET_STATE (RCV, SYNC_RCV); rcv_ResetFormatter (); } break; case FR_T4DATA: rcv->train_flg = FALSE; if (!rcv_StoreMsgData (pFD, &rcv->prim_ready)) { rcv->t30_req_frames = FALSE; rcv_ResetFormatter (); SET_STATE (RCV, SYNC_RCV); sig_rcv_ker_error_ind (ERR_OVERFLOW_BCS_RCV); break; } rcv->data_in_rbm = TRUE; if (rcv->t30_req_frames) /* check if T30 READY flag set */ sig_ker_rcv_ready_req (); break; default: break; } break; /* case MSG_RCV: */ default: break; } } #ifdef _TARGET_ /* +----------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : FAD_RCVP | | STATE : code ROUTINE : fad_rcv_GetDestDescriptor | +----------------------------------------------------------------------+ PURPOSE : WRAPPER: Get frame descriptor for Layer 1 (TI) */ GLOBAL T_FD *fad_rbm_get_next_FrameDesc(void) { return (cl_ribu_get_new_frame_desc(fad_data->rbm.ribu)); } #endif