FreeCalypso > hg > fc-tourmaline
view src/g23m-fad/ra/ra_tra.c @ 273:5caa86ee2cfa
enable L1_NEW_AEC in l1_confg.h (bold change)
The AEC function implemented in DSP ROM 3606 on the Calypso silicon
we work with is the one that corresponds to L1_NEW_AEC; the same holds
for DSP 34 and even for DSP 33 with more recent patch versions.
However, TI shipped their TCS211 reference fw with L1_NEW_AEC set to 0,
thus driving AEC the old way if anyone tried to enable it, either via
AT%Nxxxx or via the audio mode facility. As a result, the fw would
try to control features which no longer exist in the DSP (long vs short
echo and the old echo suppression level bits), while providing no way
to tune the 8 new parameter words added to the DSP's NDB page.
The only sensible solution is to bite the bullet and enable L1_NEW_AEC
in L1 config, with fallout propagating into RiViera Audio Service
T_AUDIO_AEC_CFG structure and into /aud/*.cfg binary file format.
The latter fallout will be addressed in further code changes.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Thu, 29 Jul 2021 18:32:40 +0000 |
| parents | fa8dc04885d8 |
| children |
line wrap: on
line source
/* +----------------------------------------------------------------------------- | Project : GSM-F&D (8411) | Modul : RA_TRA +----------------------------------------------------------------------------- | 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 the transparent data model | for the component RA of the mobile station +----------------------------------------------------------------------------- */ #ifndef RA_TRA_C #define RA_TRA_C #endif #define ENTITY_RA /*==== INCLUDES ===================================================*/ #include "typedefs.h" #include "vsi.h" #include "macdef.h" #include "pconst.cdg" #include "custom.h" #include "gsm.h" #include "cnf_ra.h" #include "prim.h" #include "pei.h" #include "tok.h" #include "ccdapi.h" #include "ra.h" /*==== CONST ======================================================*/ /*==== TYPES ======================================================*/ /*==== VARIABLES ==================================================*/ /*==== FUNCTIONS ==================================================*/ /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_init | +--------------------------------------------------------------------+ PURPOSE : initialize the transparent mode data */ GLOBAL void tra_init (UBYTE tra_rate) { T_TRA *dtra = ra_data->tra; TRACE_FUNCTION("tra_init()"); dtra->ul_data_pending = FALSE; dtra->ul_signals_pending = FALSE; dtra->ul_break_pending = FALSE; dtra->break_pos = 0; dtra->break_len = 0; dtra->overspeed = 0; dtra->ul_status = 0; dtra->ul_sa = 0; dtra->ul_sb = 0; dtra->ul_x = 0; dtra->dl_sa.pos = ST_SA; /* DSR */ dtra->dl_sa.last = 0xFF; dtra->dl_sa.timer = 0L; #ifdef _SIMULATION_ /* according to GSM-TS07.01 */ dtra->dl_sa.delay_OFF_ON = 0L; dtra->dl_sa.delay_ON_OFF = 0L; #else /* to avoid spurious data at the beginning of the call */ dtra->dl_sa.delay_OFF_ON = 5000L; dtra->dl_sa.delay_ON_OFF = 1000L; #endif dtra->dl_sb.pos = ST_SB; /* DCD */ dtra->dl_sb.last = 0xFF; dtra->dl_sb.timer = 0L; dtra->dl_sb.delay_OFF_ON = 200L; dtra->dl_sb.delay_ON_OFF = 5000L; dtra->dl_x.pos = ST_X; /* CTS */ dtra->dl_x.last = 0xFF; dtra->dl_x.timer = 0L; dtra->dl_x.delay_OFF_ON = 1000L; dtra->dl_x.delay_ON_OFF = 1000L; ra_data->ra_data_ind.status = ST_SA + ST_SB + ST_X; ra_data->ra_data_ind.fr_type = FR_TRANS; ra_data->ra_data_ind.sdu.o_buf = 0; ra_data->ra_data_ind.sdu.l_buf = 0; ra_data->ra_ready_ind[0].req_frames = 0; /* used, if not all data sent yet */ dtra->ready_ind_idx = 1; switch (tra_rate) { case TRA_FULLRATE_14400: ra_data->ra_ready_ind[1].req_frames = RAU_DATA_14400; break; case TRA_FULLRATE_4800: ra_data->ra_ready_ind[1].req_frames = RAU_DATA_4800; break; case TRA_HALFRATE_4800: case TRA_FULLRATE_2400: ra_data->ra_ready_ind[1].req_frames = RAU_DATA_2400; break; case TRA_HALFRATE_2400: ra_data->ra_ready_ind[1].req_frames = RAU_DATA_1200; break; default: ra_data->ra_ready_ind[1].req_frames = RAU_DATA_9600; break; } cl_set_frame_desc_0(&dtra->ul_frame_desc, NULL, 0); hCommMMI = vsi_c_open ( VSI_CALLER ACI_NAME ); hCommTRA = vsi_c_open ( VSI_CALLER TRA_NAME ); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_idle | +--------------------------------------------------------------------+ PURPOSE : IDLE processing fpr uplink and downlink transparent mode */ GLOBAL void tra_idle(void) { TRACE_FUNCTION("tra_idle()"); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_ul_null | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_ul_null(void) { TRACE_FUNCTION("tra_ul_null()"); if (ra_data->activated) { /* * setup the communication parameters */ shm_set_dsp_value (conf_b_itc, V_ITC_DATA); shm_set_dsp_value (test_b_t_dl_debug, 0); switch (ra_data->nsb) { case 1: shm_set_dsp_value (conf_b_nsb, V_NSB_ONE_STOP); break; case 2: shm_set_dsp_value (conf_b_nsb, V_NSB_TWO_STOP); break; default: break; } switch (ra_data->ndb) { case 7: shm_set_dsp_value (conf_b_ndb, V_NDMSK_B_7_DBITS); break; case 8: shm_set_dsp_value (conf_b_ndb, V_NDMSK_B_8_DBITS); break; default: break; } switch (ra_data->user_rate) { case URA_300: shm_set_dsp_value (conf_b_ur, V_UR_300); break; case URA_1200: shm_set_dsp_value (conf_b_ur, V_UR_1200); break; case URA_2400: shm_set_dsp_value (conf_b_ur, V_UR_2400); break; case URA_4800: shm_set_dsp_value (conf_b_ur, V_UR_4800); break; case URA_9600: /* hack for 14400: */ if (ra_data->tra_rate EQ TRA_FULLRATE_14400) { shm_set_dsp_value (conf_b_ur, V_UR_14400); } else { shm_set_dsp_value (conf_b_ur, V_UR_9600); } break; case URA_1200_75: shm_set_dsp_value (conf_b_ur, V_UR_1200_75); break; case URA_14400: shm_set_dsp_value (conf_b_ur, V_UR_14400); break; default: break; } shm_set_dsp_value (conf_b_ce, V_CE_TRANSP); switch (ra_data->tra_rate) { case TRA_FULLRATE_14400: case TRA_FULLRATE_9600: case TRA_FULLRATE_4800: case TRA_FULLRATE_2400: shm_set_dsp_value (conf_b_ct, V_CT_FR); ra_data->cycle_time = 20; break; case TRA_HALFRATE_4800: case TRA_HALFRATE_2400: shm_set_dsp_value (conf_b_ct, V_CT_HR); ra_data->cycle_time = 40; break; default: break; } /* * set uplink buffer empty to empty values and no break */ shm_set_dsp_value (rau_byte_cnt, 2); shm_set_dsp_value (rau_break_len, 0); shm_set_dsp_value (rau_break_pos, 0); /* * start initialisation process in F&D L1 */ shm_set_dsp_value (act_b_init, 1); shm_set_dsp_value (act_b_syncul, 1); shm_set_dsp_value (act_b_syncdl, 1); INIT_STATE (KER, TRA_INIT_L1); #ifdef HO_WORKAROUND /* tra_ul_null */ _act_d_ra_conf = *ra_data->shm.shm_addr[d_ra_conf]; TRACE_EVENT("d_ra_conf saved"); #endif } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_ul_init_l1 | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_ul_init_l1(void) { TRACE_FUNCTION("tra_ul_init_l1()"); if (shm_get_dsp_value (act_b_init) EQ 0) { /* * L1 F&D initialzed * start ul/dl synchronisation */ SET_STATE (KER, TRA_SYNCH_TCH_START); } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_dl_sync_tch_start | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_dl_sync_tch_start(void) { TRACE_FUNCTION("tra_dl_sync_tch_start()"); if (shm_get_dsp_value (statd_b_syncdet) EQ 1) { /* * Start a pseudo timer with 500 ms. * The value is decremented by cycle_time * each time the L1 calls the dll_data_ul function. */ TRACE_EVENT("SYNC_TIMER: start"); ra_data->sync_timer = 500L; shm_set_dsp_value (rad_byte_cnt, 2); SET_STATE (KER, TRA_SYNCH_TCH_FOUND); } } LOCAL void set_ul_status(T_TRA *tra) { shm_set_dsp_value (statu_b_sa, tra->ul_sa); shm_set_dsp_value (statu_b_sb, tra->ul_sb); shm_set_dsp_value (statu_b_x, tra->ul_x); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_ul_sync_tch_found | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_ul_sync_tch_found(void) { TRACE_FUNCTION("tra_ul_sync_tch_found()"); if (TimeOut(&ra_data->sync_timer) NEQ TRUE) return; /* * timeout of the sync timer - reset the sync-detection flags */ TRACE_EVENT("SYNC_TIMER: time out"); shm_set_dsp_value (act_b_syncul, 0); shm_set_dsp_value (act_b_syncdl, 0); if (ra_data->tra_rate NEQ TRA_FULLRATE_14400) { ra_data->sync_timer = 10000L; /* 10 secs timeout */ SET_STATE (KER, TRA_WAIT_SYNC_LOST); } else { SET_STATE (KER, TRA_DATA_TRANS_PRE1); #ifdef HO_WORKAROUND /* tra_ul_sync_tch_found */ if (*ra_data->shm.shm_addr[d_ra_conf] NEQ _act_d_ra_conf) { *ra_data->shm.shm_addr[d_ra_conf] = _act_d_ra_conf; /* tra_dl_data_trans */ TRACE_EVENT("HO_REFRESH tra_ul_sync_tch_found"); } #endif } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_dl_wait_sync_lost | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_dl_wait_sync_lost(void) { BOOL timeout; TRACE_FUNCTION("tra_dl_wait_sync_lost()"); timeout = TimeOut(&ra_data->sync_timer); if (timeout EQ TRUE) { TRACE_EVENT("SYNC_TIMER: statd_b_syncdet remains HIGH"); } if (shm_get_dsp_value (statd_b_syncdet) EQ 0 OR timeout EQ TRUE) { /* * sync detection finished -> enter the data transmission state * send ra_activate_cnf -> ACI */ SET_STATE (KER, TRA_DATA_TRANS_PRE1); set_ul_status(ra_data->tra); #ifdef HO_WORKAROUND /* tra_dl_wait_sync_lost */ if (*ra_data->shm.shm_addr[d_ra_conf] NEQ _act_d_ra_conf) { *ra_data->shm.shm_addr[d_ra_conf] = _act_d_ra_conf; /* tra_dl_data_trans */ TRACE_EVENT("HO_REFRESH tra_dl_wait_sync_lost"); } #endif } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_ul_data_trans | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_ul_data_trans(void) { T_TRA *dtra = ra_data->tra; TRACE_FUNCTION("tra_ul_data_trans()"); if (dtra->ul_signals_pending) { /* * handle sa, sb, x signals */ set_ul_status(dtra); shm_set_dsp_value (act_b_ovspul, dtra->overspeed); } if (dtra->ul_data_pending) { USHORT offs, new_offs; offs = shm_get_dsp_value (rau_byte_cnt); if (offs > 0) { offs -= 2; if (dtra->ul_break_pending) { shm_set_dsp_value (rau_break_pos, dtra->break_pos); shm_set_dsp_value (rau_break_len, dtra->break_len); } else { shm_set_dsp_value (rau_break_pos, 0); shm_set_dsp_value (rau_break_len, 0); } new_offs = shm_set_dsp_buffer(&dtra->ul_frame_desc, ra_data->shm.shm_addr[adr_rau_data]+wof_rau_data, offs, (USHORT)(ra_data->ra_ready_ind[1].req_frames - offs)); if (new_offs NEQ offs) { shm_set_dsp_value (rau_byte_cnt, (USHORT)(new_offs+2)); } if (dtra->ul_frame_desc.Len[0] EQ 0) { dtra->ul_data_pending = FALSE; dtra->ready_ind_idx = 1; } else { dtra->ul_frame_desc.Adr[0] += (new_offs-offs); } } } if (!dtra->ul_data_pending OR dtra->ul_signals_pending) { if (dtra->ul_signals_pending AND !dtra->ul_data_pending) { dtra->ready_ind_idx = 1; } if (dtra->data_req_rec) /* send only if RA_DATA_REQ received */ { l1i_ra_ready_ind(hCommTRA, dtra->ready_ind_idx); dtra->data_req_rec = FALSE; dtra->ready_ind_idx = 0; dtra->ul_signals_pending = FALSE; } } } LOCAL UBYTE check_status_bit(T_STATUS_BIT *status) { if (status->last NEQ status->current) { status->last = status->current; if (status->current) /* current status bit is OFF */ { if (status->delay_ON_OFF) { status->timer = status->delay_ON_OFF; /* start ON to OFF timer */ return 2+1; } else { ra_data->ra_data_ind.status |= status->pos; /* status bit OFF */ return 4+1; } } else /* current status bit is ON */ { if (status->delay_OFF_ON) { status->timer = status->delay_OFF_ON; /* start OFF to ON timer */ return 2+0; } else { ra_data->ra_data_ind.status &= ~status->pos; /* status bit ON */ return 4+0; } } } else /* status->last EQ status->current */ { if (TimeOut(&status->timer) EQ TRUE) { if (status->current) /* current status bit is OFF */ { ra_data->ra_data_ind.status |= status->pos; /* filtered status bit OFF */ return 4+1; } else { ra_data->ra_data_ind.status &= ~status->pos; /* filtered status bit ON */ return 4+0; } } } return 0; } LOCAL BOOL get_dl_status_bits(void) { T_TRA *dtra = ra_data->tra; BOOL dl_status_changed = FALSE; UBYTE ret; /*** status bit SA ***/ dtra->dl_sa.current = (UBYTE)shm_get_dsp_value(statd_b_sa); ret = check_status_bit(&dtra->dl_sa); if (ret > 3) dl_status_changed = TRUE; #ifdef TRACE_RA_TRA_STATUS switch (ret) { case 2: TRACE_EVENT("SA bit timer started 1 -> 0"); break; case 3: TRACE_EVENT("SA bit timer started 0 -> 1"); break; case 4: TRACE_EVENT("CT107-DSR=ON"); break; case 5: TRACE_EVENT("CT107-DSR=OFF"); break; } #endif if (!(ra_data->ra_data_ind.status & ST_SA)) /* DSR EQ ON */ { /*** perform filtering of status bit SB ***/ dtra->dl_sb.current = (UBYTE)shm_get_dsp_value(statd_b_sb); ret = check_status_bit(&dtra->dl_sb); if (ret > 3) dl_status_changed = TRUE; #ifdef TRACE_RA_TRA_STATUS switch (ret) { case 2: TRACE_EVENT("SB bit timer started 1 -> 0"); break; case 3: TRACE_EVENT("SB bit timer started 0 -> 1"); break; case 4: TRACE_EVENT("CT109-DCD=ON"); break; case 5: TRACE_EVENT("CT109-DCD=OFF"); break; } #endif /*** perform filtering of status bit X ***/ dtra->dl_x.current = (UBYTE)shm_get_dsp_value(statd_b_x); ret = check_status_bit(&dtra->dl_x); if (ret > 3) dl_status_changed = TRUE; #ifdef TRACE_RA_TRA_STATUS switch (ret) { case 2: TRACE_EVENT("X bit timer started 1 -> 0"); break; case 3: TRACE_EVENT("X bit timer started 0 -> 1"); break; case 4: TRACE_EVENT("CT106-CTS=ON"); break; case 5: TRACE_EVENT("CT106-CTS=OFF"); break; } #endif } else if (dl_status_changed EQ TRUE) /* DSR EQ OFF */ { ra_data->ra_data_ind.status |= ST_SB + ST_X; dtra->dl_sb.last = 0xFF; dtra->dl_x.last = 0xFF; #ifdef TRACE_RA_TRA_STATUS TRACE_EVENT("CT106-CTS=OFF"); TRACE_EVENT("CT109-DCD=OFF"); #endif } /* * overwrite the downlink CTS bit; * allows UART the reception of escape sequence always; * no matter what the current call state may be ra_data->ra_data_ind.status &= ~ST_X; */ return dl_status_changed; } LOCAL U8 get_frame_descriptor(U8 bytes_to_read) { T_TRA *dtra = ra_data->tra; #ifdef _SIMULATION_ dtra->dl_pFD = cl_ribu_get_new_frame_desc(ra_data->dl_ribu); #else dtra->dl_pFD = tra_get_next_FrameDesc(); #endif if (NULL EQ dtra->dl_pFD) { /*Race condition where there is a data from L1 and call is released parallely*/ TRACE_EVENT("Call is Released when data arrived or Ribu write index is invalid"); /*return as if no data is read from L1.*/ return 0; } if (bytes_to_read) { dtra->dl_pFD->len = MAX_TRANS_BUFFER; return (shm_get_dsp_buffer_new(ra_data->shm.shm_addr[adr_rad_data]+wof_rad_data, bytes_to_read, dtra->dl_pFD)); } else { dtra->dl_pFD->len = 0; return 0; } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_dl_wait_for_connect | +--------------------------------------------------------------------+ PURPOSE : wait for all filtered status bits set to 0 */ GLOBAL void tra_dl_wait_for_connect(void) { TRACE_FUNCTION("tra_dl_wait_for_connect()"); #ifdef HO_WORKAROUND /* tra_dl_wait_for_connect */ if (*ra_data->shm.shm_addr[d_ra_conf] NEQ _act_d_ra_conf) { *ra_data->shm.shm_addr[d_ra_conf] = _act_d_ra_conf; /* tra_dl_data_trans */ TRACE_EVENT("HO_REFRESH tra_dl_data_trans"); } #endif get_dl_status_bits(); if ((UBYTE)(ra_data->ra_data_ind.status AND (ST_SA + ST_SB + ST_X)) EQ 0) { l1i_ra_activate_cnf(); SET_STATE (KER, TRA_DATA_TRANS_PRE2); } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_dl_wait_for_uart | +--------------------------------------------------------------------+ PURPOSE : wait for DTI connection to UART */ GLOBAL void tra_dl_wait_for_uart(void) { TRACE_FUNCTION("tra_dl_wait_for_uart()"); get_dl_status_bits(); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_dl_got_uart | +--------------------------------------------------------------------+ PURPOSE : send the current downlink status bits to UART */ GLOBAL void tra_dl_got_uart(void) { TRACE_FUNCTION("tra_dl_got_uart()"); get_dl_status_bits(); get_frame_descriptor(0); l1i_ra_data_ind(hCommTRA); SET_STATE (KER, TRA_DATA_TRANS); } LOCAL void get_dl_bytes(UBYTE bytes_to_read) { T_TRA *dtra = ra_data->tra; UBYTE bytes_read; bytes_read = get_frame_descriptor(bytes_to_read); shm_set_dsp_value (rad_byte_cnt, 2); /* confirm read operation */ if ( bytes_read EQ 0 ){ /*We couldn't read the data, in get_frame_descriptor() there is a possibiliy we get NULL frame description (race condition) hence no data is read. In this case we should not access dtra->dl_pFD pointer and as well donot indicate ra_data_ind, hence return. */ return; } if (ra_data->ra_data_ind.status & ST_SA OR ra_data->ra_data_ind.status & ST_SB) { /* DSR is OFF OR DCD is OFF */ dtra->dl_pFD->len = 0; #ifdef TRACE_RA_TRA_DATA TRACE_EVENT_P1("DATA_IND - len=0:%c", *dtra->dl_pFD->buf); #endif } else { dtra->dl_pFD->len = bytes_read; #ifdef TRACE_RA_TRA_DATA TRACE_EVENT_P2("DATA_IND - len=%d:%c", bytes_read, *dtra->dl_pFD->buf); #endif } l1i_ra_data_ind(hCommTRA); } LOCAL BOOL dl_break_detected(BOOL *dl_status_changed, UBYTE *bytes_to_read) /* BREAK handling */ { T_TRA *dtra = ra_data->tra; UBYTE brklen; UBYTE brkpos; UBYTE bytes_read; if ((brklen = (UBYTE)shm_get_dsp_value(rad_break_len)) > 0) { TRACE_EVENT_P1("RA_BREAK_IND-brklen=%d", brklen); /*** handling of 0xff break over multiple frames not implemented yet ***/ if ((brkpos = (UBYTE)shm_get_dsp_value(rad_break_pos)) > 0) { TRACE_EVENT_P1("brkpos=%d", brkpos); /* * If the position > 0 read out the data until the break occurs. */ if (*bytes_to_read > 0) { TRACE_EVENT_P1("bytes_to_read=%d", *bytes_to_read); bytes_read = get_frame_descriptor(brkpos); bytes_to_read -= bytes_read; dtra->dl_pFD->len = bytes_read; TRACE_EVENT ("DATA_IND - break handling"); dtra->dl_pFD->len = 0; l1i_ra_data_ind(hCommTRA); } } shm_set_dsp_value (rad_byte_cnt, 2); /* confirm read operation */ #ifdef HO_WORKAROUND /* tra_dl_data_trans - "BREAK" */ /* enforce new DSR status bit filtering time */ dtra->dl_sa.delay_OFF_ON = 1000L; dtra->dl_sa.delay_ON_OFF = 0L; dtra->dl_sa.last = 0xFF; dtra->dl_sb.last = 0xFF; dtra->dl_x.last = 0xFF; ra_data->ra_data_ind.status = ST_SA + ST_SB + ST_X; *dl_status_changed = TRUE; #else dtra->ra_break_ind.break_len = brklen; l1i_ra_break_ind(); #endif if (*dl_status_changed EQ TRUE) { get_frame_descriptor(0); l1i_ra_data_ind(hCommTRA); } return TRUE; } /* brklen > 0 */ return FALSE; } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_TRA | | STATE : code ROUTINE : tra_dl_data_trans | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void tra_dl_data_trans(void) { UBYTE bytes_to_read; BOOL dl_status_changed; TRACE_FUNCTION("tra_dl_data_trans()"); #ifdef HO_WORKAROUND /* tra_dl_data_trans */ if (*ra_data->shm.shm_addr[d_ra_conf] NEQ _act_d_ra_conf) { *ra_data->shm.shm_addr[d_ra_conf] = _act_d_ra_conf; /* tra_dl_data_trans */ TRACE_EVENT("HO_REFRESH tra_dl_data_trans"); } #endif dl_status_changed = get_dl_status_bits(); /*** read out the received downlink data ***/ bytes_to_read = shm_get_dsp_value (rad_byte_cnt); if (bytes_to_read > 0) { bytes_to_read -= 2; /* ignore header */ if (dl_break_detected(&dl_status_changed, &bytes_to_read)) return; if (bytes_to_read > 0 AND bytes_to_read <= MAX_TRANS_BUFFER) { get_dl_bytes(bytes_to_read); } else /* NO bytes_to_read */ { if (dl_status_changed EQ TRUE) { get_frame_descriptor(0); l1i_ra_data_ind(hCommTRA); } } } else /* NO bytes_to_read -- will never happen */ { if (dl_status_changed EQ TRUE) { get_frame_descriptor(0); l1i_ra_data_ind(hCommTRA); } } }