FreeCalypso > hg > fc-tourmaline
view src/cs/layer1/audio_include/l1audio_msgty.h @ 275:79cfefc1e2b4
audio mode load: gracefully handle mode files of wrong AEC version
Unfortunately our change of enabling L1_NEW_AEC (which is necessary
in order to bring our Calypso ARM fw into match with the underlying
DSP reality) brings along a change in the audio mode file binary
format and file size - all those new tunable AEC parameters do need
to be stored somewhere, after all. But we already have existing
mode files in the old format, and setting AEC config to garbage when
loading old audio modes (which is what would happen without the
present change) is not an appealing proposition.
The solution implemented in the present change is as follows: the
audio mode loading code checks the file size, and if it differs
from the active version of T_AUDIO_MODE, the T_AUDIO_AEC_CFG structure
is cleared - set to the default (disabled AEC) for the compiled type
of AEC. We got lucky in that this varying T_AUDIO_AEC_CFG structure
sits at the end of T_AUDIO_MODE!
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Fri, 30 Jul 2021 02:55:48 +0000 |
| parents | 4e78acac3d88 |
| children |
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/************* Revision Controle System Header ************* * GSM Layer 1 software * L1AUDIO_MSGTY.H * * Filename l1audio_msgty.h * Copyright 2003 (C) Texas Instruments * ************* Revision Controle System Header *************/ #if (AUDIO_TASK == 1) #if (OP_RIV_AUDIO == 1) #include "rv_general.h" #endif #if (KEYBEEP) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD16 d_k_x1_kt0; UWORD16 d_k_x1_kt1; UWORD16 d_dur_kb; } T_MMI_KEYBEEP_REQ; #endif #if (TONE) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD16 d_k_x1_t0; UWORD16 d_k_x1_t1; UWORD16 d_k_x1_t2; UWORD16 d_pe_rep; UWORD16 d_pe_off; UWORD16 d_se_off; UWORD16 d_bu_off; UWORD16 d_t0_on; UWORD16 d_t0_off; UWORD16 d_t1_on; UWORD16 d_t1_off; UWORD16 d_t2_on; UWORD16 d_t2_off; } T_MMI_TONE_REQ; #endif #if (MELODY_E1) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 session_id; BOOL loopback; UWORD16 oscillator_used_bitmap; } T_MMI_MELODY_REQ; #endif #if (VOICE_MEMO) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 session_id; } T_MMI_VM_PLAY_REQ; typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 session_id; UWORD32 maximum_size; BOOL dtx_used; UWORD16 record_coeff_dl; UWORD16 record_coeff_ul; UWORD16 d_k_x1_t0; UWORD16 d_k_x1_t1; UWORD16 d_k_x1_t2; UWORD16 d_pe_rep; UWORD16 d_pe_off; UWORD16 d_se_off; UWORD16 d_bu_off; UWORD16 d_t0_on; UWORD16 d_t0_off; UWORD16 d_t1_on; UWORD16 d_t1_off; UWORD16 d_t2_on; UWORD16 d_t2_off; } T_MMI_VM_RECORD_REQ; typedef struct { UWORD32 recorded_size; } T_L1_VM_RECORD_CON; #if (OP_RIV_AUDIO == 1) typedef struct { T_RV_HDR header; UWORD32 recorded_size; } T_MMI_VM_RECORD_CON; #else typedef T_L1_VM_RECORD_CON T_MMI_VM_RECORD_CON; #endif #endif #if (L1_VOICE_MEMO_AMR) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 session_id; } T_MMI_VM_AMR_PLAY_REQ; typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 session_id; UWORD32 maximum_size; BOOL dtx_used; UWORD16 record_coeff_ul; UWORD8 amr_vocoder; } T_MMI_VM_AMR_RECORD_REQ; typedef struct { UWORD32 recorded_size; } T_L1_VM_AMR_RECORD_CON; #if (OP_RIV_AUDIO == 1) typedef struct { T_RV_HDR header; UWORD32 recorded_size; } T_MMI_VM_AMR_RECORD_CON; #else typedef T_L1_VM_AMR_RECORD_CON T_MMI_VM_AMR_RECORD_CON; #endif #endif #if (OP_RIV_AUDIO == 1) #if (L1_AUDIO_DRIVER == 1) typedef struct { UWORD8 channel_id; UWORD16 *p_buffer; } T_L1_AUDIO_DRIVER_IND; #endif #endif #if (SPEECH_RECO) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 database_id; UWORD8 word_index; BOOL speech; UWORD16 *speech_address; } T_MMI_SR_ENROLL_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 error_id; } T_MMI_SR_ENROLL_STOP_CON; #if (OP_RIV_AUDIO == 1) typedef struct { UWORD8 error_id; } T_L1_SR_ENROLL_STOP_CON; #else typedef T_MMI_SR_ENROLL_STOP_CON T_L1_SR_ENROLL_STOP_CON; #endif typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 database_id; UWORD8 word_index; BOOL speech; UWORD16 *speech_address; } T_MMI_SR_UPDATE_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 error_id; } T_MMI_SR_UPDATE_STOP_CON; #if (OP_RIV_AUDIO == 1) typedef struct { UWORD8 error_id; } T_L1_SR_UPDATE_STOP_CON; #else typedef T_MMI_SR_UPDATE_STOP_CON T_L1_SR_UPDATE_STOP_CON; #endif typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 database_id; UWORD8 vocabulary_size; } T_MMI_SR_RECO_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 error_id; UWORD16 best_word_index; UWORD32 best_word_score; UWORD16 second_best_word_index; UWORD32 second_best_word_score; UWORD16 third_best_word_index; UWORD32 third_best_word_score; UWORD16 fourth_best_word_index; UWORD32 fourth_best_word_score; UWORD16 d_sr_db_level; UWORD16 d_sr_db_noise; UWORD16 d_sr_model_size; } T_MMI_SR_RECO_STOP_CON; typedef struct { UWORD8 error_id; } T_L1_SR_RECO_STOP_CON; #if (OP_RIV_AUDIO == 1) typedef struct { UWORD8 error_id; UWORD16 best_word_index; UWORD32 best_word_score; UWORD16 second_best_word_index; UWORD32 second_best_word_score; UWORD16 third_best_word_index; UWORD32 third_best_word_score; UWORD16 fourth_best_word_index; UWORD32 fourth_best_word_score; UWORD16 d_sr_db_level; UWORD16 d_sr_db_noise; UWORD16 d_sr_model_size; } T_L1_SR_RECO_STOP_IND; #else typedef T_MMI_SR_RECO_STOP_CON T_L1_SR_RECO_STOP_IND; #endif typedef T_L1_SR_RECO_STOP_CON T_L1_SR_PROCESSING_STOP_CON; typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 database_id; UWORD8 word_index; UWORD16 *model_address; BOOL speech; UWORD16 *speech_address; UWORD8 vocabulary_size; } T_MMI_SR_UPDATE_CHECK_REQ; typedef T_MMI_SR_RECO_STOP_CON T_MMI_SR_UPDATE_CHECK_STOP_CON; // Background message type typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 database_id; UWORD8 model_index; API *model_RAM_address; BOOL speech; UWORD16 *start_buffer; UWORD16 *stop_buffer; UWORD16 *start_address; UWORD16 *stop_address; } T_L1_SRBACK_SAVE_DATA_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 database_id; UWORD8 model_index; API *model_RAM_address; BOOL CTO_enable; } T_L1_SRBACK_LOAD_MODEL_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif API *model_RAM_address_input; UWORD16 *model_RAM_address_output; } T_L1_SRBACK_TEMP_SAVE_DATA_REQ; #endif #if (AEC) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD16 aec_control; #if (L1_NEW_AEC) UWORD16 cont_filter; UWORD16 granularity_att; UWORD16 coef_smooth; UWORD16 es_level_max; UWORD16 fact_vad; UWORD16 thrs_abs; UWORD16 fact_asd_fil; UWORD16 fact_asd_mut; #endif } T_MMI_AEC_REQ; #if (L1_NEW_AEC) typedef struct { UWORD16 es_level; UWORD32 far_end_pow; UWORD32 far_end_noise; } T_L1_AEC_IND; #endif #endif #if (FIR) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif BOOL fir_loop; UWORD8 update_fir; UWORD16 *fir_ul_coefficient; UWORD16 *fir_dl_coefficient; } T_MMI_AUDIO_FIR_REQ; #endif #if (AUDIO_MODE) typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif #if (OP_RIV_AUDIO == 1) UWORD8 audio_mode; #else UWORD16 audio_mode; #endif } T_MMI_AUDIO_MODE; #endif #if (MELODY_E2) typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 melody_id; UWORD8 number_of_instrument; UWORD8 waves_table_id[SC_AUDIO_MELODY_E2_MAX_NUMBER_OF_INSTRUMENT]; } T_L1_BACK_MELODY_E2_LOAD_INSTRUMENT_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 melody_id; } T_L1_BACK_MELODY_E2_LOAD_INSTRUMENT_CON; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 melody_id; UWORD8 number_of_instrument; } T_L1_BACK_MELODY_E2_UNLOAD_INSTRUMENT_REQ; typedef struct { #if (OP_RIV_AUDIO == 1) T_RV_HDR header; #endif UWORD8 melody_id; } T_L1_BACK_MELODY_E2_UNLOAD_INSTRUMENT_CON; typedef struct { #if (defined _WINDOWS && (OP_RIV_AUDIO == 1)) T_RV_HDR header; #endif UWORD8 session_id; BOOL loopback; } T_MMI_MELODY_E2_REQ; #endif #if (L1_CPORT == 1) typedef struct { UWORD16 configuration; UWORD16 ctrl; UWORD8 cpcfr1; UWORD8 cpcfr2; UWORD8 cpcfr3; UWORD8 cpcfr4; UWORD8 cptctl; UWORD8 cpttaddr; UWORD16 cptdat; UWORD16 cptvs; } T_MMI_CPORT_CONFIGURE_REQ; typedef struct { UWORD16 register_id; UWORD16 register_value; } T_L1_CPORT_CONFIGURE_CON; #if (OP_RIV_AUDIO == 1) typedef struct { T_RV_HDR header; UWORD8 register_id; UWORD16 register_value; } T_MMI_CPORT_CONFIGURE_CON; #else typedef T_L1_CPORT_CONFIGURE_CON T_MMI_CPORT_CONFIGURE_CON; #endif #endif #endif // AUDIO_TASK