FreeCalypso > hg > fc-magnetite
view src/cs/services/Audio/audio_structs_i.h @ 502:b4dd8c7e84ce
OSL: os_tim_ir.c compiles
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Sun, 24 Jun 2018 23:58:05 +0000 |
parents | 945cf7f506b2 |
children |
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/********************************************************************************/ /* */ /* File Name: audio_structs_i.h */ /* */ /* Purpose: This file contains constants, data type, and data */ /* structures that are used by the AUDIO's task. */ /* */ /* Note: */ /* None. */ /* */ /* Revision History: */ /* 11 May 01 Francois Mazard - Stephanie Gerthoux Create */ /* */ /* (C) Copyright 2001 by Texas Instruments Incorporated, All Rights Reserved. */ /* */ /********************************************************************************/ #include "rv/rv_defined_swe.h" #ifdef RVM_AUDIO_MAIN_SWE #ifndef _AUDIO_STRUCTS_I_ #define _AUDIO_STRUCTS_I_ #ifndef _WINDOWS #include "config/sys.cfg" #include "config/chipset.cfg" #endif #include "l1_confg.h" #include "rvm/rvm_gen.h" #include "audio/audio_features_i.h" #include "audio/audio_ffs_i.h" #include "audio/audio_const_i.h" #include "ffs/ffs_api.h" #ifdef __cplusplus extern "C" { #endif /****************************** AUDIO'S ENVIRONMENT *****************************/ /* Define a structure used to store all information related to the AUDIO's task */ /* & memory bank identifiers. */ #if (KEYBEEP) typedef struct { UINT8 state; /* keybeep state */ T_RVF_ADDR_ID task_id; /* keybeep task_id */ T_RV_RETURN return_path; /* return path of the function that previously start the keybeep */ } T_AUDIO_KEYBEEP_VAR; #endif /* #if (KEYBEEP) */ #if (TONE) typedef struct { UINT8 state; /* tones state */ T_RVF_ADDR_ID task_id; /* tones task_id */ T_RV_RETURN return_path; /* return path of the function that previously start the tones */ } T_AUDIO_TONES_VAR; #endif #if (MELODY_E1) typedef struct { UINT8 state; /* melody state */ T_RVF_ADDR_ID task_id; /* melody task_id */ char melody_name[AUDIO_PATH_NAME_MAX_SIZE]; /* name and path of the word to enroll */ BOOLEAN loopback; T_RV_RETURN return_path; /* return path of the function that previously start the melody */ } T_AUDIO_MELODY_E1_VAR; #endif #if (MELODY_E2) typedef struct { UINT8 state; /* melody state */ T_RVF_ADDR_ID task_id; /* melody task_id */ char melody_name[AUDIO_PATH_NAME_MAX_SIZE]; /* name of the melody E2 */ BOOLEAN loopback; T_RV_RETURN return_path; /* return path of the function that previously start the melody */ } T_AUDIO_MELODY_E2_VAR; typedef struct { BOOLEAN file_downloaded; UINT8 nb_of_instruments; char instrument_file_name[AUDIO_PATH_NAME_MAX_SIZE]; } T_AUDIO_MELODY_E2_LOAD_FILE_VAR; typedef struct { INT8 id; /* id of the melody in the .lsi file*/ char melody_name[AUDIO_PATH_NAME_MAX_SIZE]; /* name of the melody E2 */ } T_AUDIO_MELODY_E2_ID_NAME; #endif #if (VOICE_MEMO) typedef struct { UINT8 state; /* voice memo state */ T_RVF_ADDR_ID task_id; /* voice memo task_id */ UINT32 recorded_size; /* voice memo recorded size */ T_RV_RETURN return_path; /* return path of the function that previously start the voice memo */ void *p_l1_send_message; /* address to the message to send to the L1 */ } T_AUDIO_VOICE_MEMO_RECORD_VAR; typedef struct { UINT8 state; /* voice memo state */ T_RVF_ADDR_ID task_id; /* voice memo task_id */ T_RV_RETURN return_path; /* return path of the function that previously start the voice memo */ } T_AUDIO_VOICE_MEMO_PLAY_VAR; #endif #if (L1_VOICE_MEMO_AMR) typedef struct { UINT8 state; /* voice memo state */ T_RV_RETURN return_path; /* return path of the function that previously start the voice memo */ UINT8 channel_id; #if (AUDIO_NEW_FFS_MANAGER) T_FFS_FD ffs_fd; #endif #if (AUDIO_RAM_MANAGER) UINT8 *audio_ram_fd; #endif } T_AUDIO_VOICE_MEMO_AMR_RECORD_TO_MEM_VAR; typedef struct { UINT8 state; /* voice memo state */ T_RV_RETURN return_path; /* return path of the function that previously start the voice memo */ UINT8 channel_id; #if (AUDIO_NEW_FFS_MANAGER) T_FFS_FD ffs_fd; #endif #if (AUDIO_RAM_MANAGER) UINT8 *audio_ram_fd; UINT16 audio_ram_size; #endif } T_AUDIO_VOICE_MEMO_AMR_PLAY_FROM_MEM_VAR; #endif #if (MELODY_E1) || (MELODY_E2) || (VOICE_MEMO) typedef struct { UINT8 *p_start_pointer; UINT8 *p_stop_pointer; UINT16 size; } T_AUDIO_FFS_BUFFER_INFO; typedef struct { /* validity of the session: */ /* 0: this session isn't started */ /* 1: this session is running */ BOOLEAN valid_channel; /* file descriptor */ T_FFS_FD audio_ffs_fd; /*initial size requested before to start the L1 */ UINT16 size; /* loop mode is used or not during this session */ BOOLEAN loop_mode; /* mode of the session: */ /* 0: FLASH to RAM download */ /* 1: RAM to FLASH download */ BOOLEAN session_mode; UINT8 session_id; } T_AUDIO_FFS_SESSION_REQ; typedef struct { /* index of the next buffer will be used by the L1 */ UINT8 index_l1; /* index of the current buffer used by the FFS */ UINT8 index_ffs; T_AUDIO_FFS_BUFFER_INFO buffer[AUDIO_MAX_FFS_BUFFER_PER_SESSION]; /* state of the cust_get_pointer function */ UINT8 cust_get_pointer_state; } T_AUDIO_FFS_SESSION_INFO; typedef struct { /* Request of the current session */ T_AUDIO_FFS_SESSION_REQ session_req; /* information of the current session */ T_AUDIO_FFS_SESSION_INFO session_info; } T_AUDIO_FFS_SESSION; #endif #if (AUDIO_MEM_MANAGER) typedef struct { // file or RAM buffer descriptor #if (AUDIO_NEW_FFS_MANAGER) T_FFS_FD audio_ffs_fd; #endif #if (AUDIO_RAM_MANAGER) UINT8 *audio_ram_fd; UINT16 audio_ram_size; #endif // size of temporary RAM buffers (8-bit unit) UINT16 size; // session_id and channel_id to identify feature UINT8 session_id; UINT8 channel_id; } T_AUDIO_MEM_SESSION_REQ; typedef struct { UINT8 state; // state machine UINT8 size_left; // sample split between 2 RAM buffers UINT8 previous_type; // last sample type processed UINT32 recorded_size; /* voice memo recorded size */ BOOL stop_req_allowed;// TRUE first then FALSE } T_AUDIO_MEM_SESSION_INFO; typedef struct { /* Request of the current session */ T_AUDIO_MEM_SESSION_REQ session_req; /* information of the current session */ T_AUDIO_MEM_SESSION_INFO session_info; } T_AUDIO_MEM_SESSION; #endif #if (MELODY_E1) || (MELODY_E2) || (VOICE_MEMO) typedef struct { UINT8 *p_start_pointer; UINT16 size; } T_AUDIO_DRIVER_BUFFER_INFO; typedef struct { UINT16 size; // initial size requested before to start the L1 UINT8 nb_buffer; // nb buffer UINT8 session_id; void *p_l1_send_message; /* address to the message to send to the L1 */ T_RV_RETURN return_path; } T_AUDIO_DRIVER_SESSION_REQ; typedef struct { UINT8 index_l1; // index of the next buffer will be used by the L1 UINT8 index_appli; // index of the current buffer used by the FFS T_AUDIO_DRIVER_BUFFER_INFO *buffer; // pointers on temporary RAM buffers UINT8 state; UINT8 play_api_state;// only play UINT8 stop_request;// 0 first then 1 when stop request } T_AUDIO_DRIVER_SESSION_INFO; typedef struct { /* Request of the current session */ T_AUDIO_DRIVER_SESSION_REQ session_req; /* information of the current session */ T_AUDIO_DRIVER_SESSION_INFO session_info; } T_AUDIO_DRIVER_SESSION; #endif #if (SPEECH_RECO) typedef struct { /* enroll speech reco state */ UINT8 state; /* voice sample file descriptor */ T_FFS_FD voice_ffs_fd; /* speech reco sample file descriptor */ T_FFS_FD sr_ffs_fd; /* task_id */ UINT16 task_id; /* Speech buffer address */ void *p_speech_address; /* return path of the function that previously start the sppeech reco */ T_RV_RETURN return_path; } T_AUDIO_SR_ENROLL_VAR; typedef struct { /* update speech reco state */ UINT8 state; /* task_id */ UINT16 task_id; /* Speech buffer address */ void *p_speech_address; /* Temporary model buffer address */ void *p_model_address; /* vocabulary size */ UINT8 vocabulary_size; /* model index to update */ UINT8 model_index; /* flag to mention if the speech must be recorded */ BOOL record_speech; /* return path of the function that previously start the sppeech reco */ T_RV_RETURN return_path; /* pointer to the vocabulary database */ void *p_database; } T_AUDIO_SR_UPDATE_VAR; typedef struct { /* update speech reco state */ UINT8 state; /* task_id */ UINT16 task_id; /* vocabulary size */ UINT8 vocabulary_size; /* return path of the function that previously start the sppeech reco */ T_RV_RETURN return_path; /* pointer to the vocabulary database */ void *p_database; } T_AUDIO_SR_RECO_VAR; typedef struct { /* speech reco enroll variables */ T_AUDIO_SR_ENROLL_VAR sr_enroll; T_AUDIO_SR_UPDATE_VAR sr_update; T_AUDIO_SR_RECO_VAR sr_reco; } T_AUDIO_SPEECH_RECO_VAR; #endif #if (L1_MIDI==1) typedef struct { UINT8 state; // midi state T_RV_RETURN return_path; // return path of the function that previously started midi UINT8 channel_id; UINT16 size; T_FFS_FD ffs_fd; BOOL stop_req_allowed; #ifdef _WINDOWS UINT8 l1_state; INT16 counter; #endif } T_AUDIO_MIDI_VAR; #endif /* audio configuration variable */ typedef struct { /* full access write state */ UINT8 state; /* Number of message to receive */ UINT8 number_of_message; /* address to the data buffer */ void *buffer; /* flag to know if the data buffer need to be deallocate or not */ BOOLEAN deallocate_buffer; /* return path of the function that previously start the full access write */ T_RV_RETURN return_path; } T_AUDIO_FULL_ACCESS_WRITE_VAR; typedef struct { /* state of the audio mode load state machine */ UINT8 state; /* Number of message to receive */ UINT8 number_of_message; /* pointer to the RAM buffer */ T_AUDIO_MODE *p_audio_mode; /* return path */ T_RV_RETURN return_path; } T_AUDIO_MODE_LOAD_VAR; typedef struct { char audio_volume_path_name[AUDIO_PATH_NAME_MAX_SIZE]; } T_AUDIO_VOLUME_VAR; typedef struct { T_AUDIO_FULL_ACCESS_WRITE_VAR full_access_write_var; T_AUDIO_MODE_LOAD_VAR audio_mode_load_var; T_AUDIO_VOLUME_VAR audio_volume_var; } T_AUDIO_MODE_VAR; typedef struct { T_RVF_ADDR_ID addrId; /* AUDIO address ID. */ T_RVF_ADDR_ID audio_ffs_addrId; /* AUDIO FFS manager address ID. */ T_RVF_MB_ID mb_internal; /* AUDIO internal memory bank. */ T_RVF_MB_ID mb_external; /* AUDIO external memory bank. */ T_RVF_MB_ID mb_audio_ffs; /* AUDIO FFS memory bank */ T_RVM_RETURN (*callBackFct) (T_RVM_NAME SWEntName, T_RVM_RETURN errorCause, T_RVM_ERROR_TYPE errorType, T_RVM_STRING errorMsg); BOOLEAN message_processed; #if (KEYBEEP) /* Keybeep global variable */ T_AUDIO_KEYBEEP_VAR keybeep; #endif #if (TONE) /* Tones global variable */ T_AUDIO_TONES_VAR tones; #endif #if (MELODY_E1) /* Melody_E1 global variable */ BOOLEAN melody_E1_mode; T_AUDIO_MELODY_E1_VAR melody_E1_0; T_AUDIO_MELODY_E1_VAR melody_E1_1; #endif #if (MELODY_E2) /* Melody_E2 global variable */ BOOLEAN melody_E2_mode; T_AUDIO_MELODY_E2_VAR melody_E2_0; T_AUDIO_MELODY_E2_VAR melody_E2_1; T_AUDIO_MELODY_E2_LOAD_FILE_VAR melody_E2_load_file_instruments; #endif #if (VOICE_MEMO) /* Voice Memo global variable */ T_AUDIO_VOICE_MEMO_PLAY_VAR vm_play; T_AUDIO_VOICE_MEMO_RECORD_VAR vm_record; #endif #if (L1_VOICE_MEMO_AMR) /* Voice Memo global variable */ T_AUDIO_VOICE_MEMO_AMR_RECORD_TO_MEM_VAR audio_vm_amr_record; T_AUDIO_VOICE_MEMO_AMR_PLAY_FROM_MEM_VAR audio_vm_amr_play; #endif #if (SPEECH_RECO) /* Speech reco global variable */ T_AUDIO_SPEECH_RECO_VAR speech_reco; #endif #if (L1_MIDI==1) // Midi global variable T_AUDIO_MIDI_VAR midi; #endif /* audio mode variable */ T_AUDIO_MODE_VAR audio_mode_var; #if (MELODY_E1) ||(MELODY_E2) || (VOICE_MEMO) /* Audio FFS global variable */ T_AUDIO_FFS_SESSION audio_ffs_session[AUDIO_FFS_MAX_CHANNEL]; #endif #if (AUDIO_MEM_MANAGER) T_AUDIO_MEM_SESSION audio_mem_session[AUDIO_MEM_MAX_CHANNEL]; #endif #if (MELODY_E1) ||(MELODY_E2) || (VOICE_MEMO) || (L1_VOICE_MEMO_AMR) /* Audio FFS global variable */ T_AUDIO_DRIVER_SESSION audio_driver_session[AUDIO_DRIVER_MAX_CHANNEL]; #endif } T_AUDIO_ENV_CTRL_BLK; #ifdef __cplusplus } #endif #endif /* _AUDIO_STRUCTS_I_ */ #endif /* #ifdef RVM_AUDIO_MAIN_SWE */