/* ========================================================================= */
void AFE_Chip_Event_Handler( void *data )
{
kal_int16 v_lowest, a_lowest;
#if ( defined( __CENTRALIZED_SLEEP_MANAGER__ )&& defined( MTK_SLEEP_ENABLE ))
//Be careful.Before Locking SleepMode, to access DSP sherrif tasks much time. So access DSP must be after SetFlag
// because the event will happen whenever AP call related function
L1Audio_SetFlag( afe.aud_id );
#endif
SearchPathWorkingFlag(&v_lowest, &a_lowest);
_digitOnly_update_digital_gain(v_lowest, a_lowest);
// mic digital gain related
/* no hw mute exit, so remove it
if(afe.mic_mute){
// AM_DSP_SetSpeechUplinkSwAgcGain(); AM_DSP_SetSpeechUplinkDigitalGain(0);
}else {
*/
if(AM_IsBluetoothOn()) { // for the case of bluetooth use
AM_DSP_SetSpeechUplinkSwAgcGain(0); // make agc gain as 0 under bt mode
} else {
AM_DSP_SetSpeechUplinkSwAgcGain(afe.digitOnly_mic_volume);
}
/*
}
*/
#if ( defined( __CENTRALIZED_SLEEP_MANAGER__ )&& defined( MTK_SLEEP_ENABLE ))
L1Audio_ClearFlag( afe.aud_id );
#endif
}
void Del_PcmEx_Start(void (*pcmNway_dl_hdlr)(void), void (*pcmNway_ul_hdlr)(void),
uint32 cfgUL1, uint32 cfgUL2, uint32 cfgUL3, uint32 cfgUL4, uint32 cfgDL)
{
uint32 I;
kal_bool flag;
// prevent re-entry!!
ASSERT(PNW_STATE_IDLE == pcmEx.state);
pcmEx.aud_id = L1Audio_GetAudioID();
L1Audio_SetFlag( pcmEx.aud_id ); /*Be careful.Before Locking SleepMode, to access DSP sherrif tasks much time. So access DSP must be after SetFlag*/
// band and am type setting
pcmEx.bandInfo = PCMEX_BAND_DYNAMIC;
pcmEx.am_type = AM_PCMEX_TYPE_DEDICATION;
// pcmEx.dspPcmExMicLen = 0;
// pcmEx.dspPcmExSpkLen = 0;
pcmEx.cfgUL1 = cfgUL1;
pcmEx.cfgUL2 = cfgUL2;
pcmEx.cfgUL3 = cfgUL3;
pcmEx.cfgUL4 = cfgUL4;
pcmEx.cfgDL = cfgDL;
pcmEx.pnw_dl_hdlr = pcmNway_dl_hdlr;
pcmEx.pnw_ul_hdlr = pcmNway_ul_hdlr;
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_DL,(L1Audio_EventHandler)pcmEx_hisrDlHdlr, 0);
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_UL,(L1Audio_EventHandler)pcmEx_hisrUlHdlr, 0);
// check DSP state and turn on
ASSERT(SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF) && SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF));
AM_PCM_EX_On(pcmEx.am_type, (uint32)(&pcmEx));//to config pnw
SAL_PcmEx_SetStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
SAL_PcmEx_SetStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
// wait for ready
for(I = 0; ;I ++){
kal_bool is_ready = true;
if( (pcmEx.cfgDL & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if( (pcmEx.cfgUL1 & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if(is_ready)
break;
#ifndef L1D_TEST
ASSERT(I < 22); // wait 200ms
kal_sleep_task(2);
#endif
}
pcmEx.state = PNW_STATE_RUN;
/* the end of configure the SAL */
}
static void dtmf_mcu_Init(kal_uint16 uSampleRate)
{
kal_uint32 uIntBufSize=0, uPcmBufSize=0, uTotalBufferSize=0;
kal_uint8 *pAllocBuf;
DTMF_SR uSr=0;
memset(&DTMF_SW, 0, sizeof(DTMF_SW));
DTMF_SW.uSampleRate = uSampleRate;
switch (DTMF_SW.uSampleRate)
{
case 8000:
uSr = DTMF_8K;
break;
case 11025:
uSr = DTMF_11K;
break;
case 12000:
uSr = DTMF_12K;
break;
case 16000:
uSr = DTMF_16K;
break;
case 22050:
uSr = DTMF_22K;
break;
case 24000:
uSr = DTMF_24K;
break;
case 32000:
uSr = DTMF_32K;
break;
case 44100:
uSr = DTMF_44K;
break;
case 48000:
uSr = DTMF_48K;
break;
default:
ASSERT(0);
break;
}
DTMF_GetBufferSize(&uIntBufSize, &uPcmBufSize, uSr, DTMF_MONO);
uTotalBufferSize = uIntBufSize + uPcmBufSize * DTMF_BUFFERED_FRAME_NUMBER;
kal_trace( TRACE_GROUP_AUD_PLAYBACK, MCU_DTMF_INIT, uSampleRate, uPcmBufSize, uTotalBufferSize);
pAllocBuf = (kal_uint8 *)audio_alloc_mem(uTotalBufferSize);
ASSERT(pAllocBuf);
ASSERT(uIntBufSize);
ASSERT(uPcmBufSize);
DTMF_SW.uFrameByte = uPcmBufSize;
DTMF_SW.RingBuffer.rb_base = (kal_uint8*)pAllocBuf;
DTMF_SW.RingBuffer.rb_size = uPcmBufSize * DTMF_BUFFERED_FRAME_NUMBER;
DTMF_SW.RingBuffer.write = uPcmBufSize * uPreSilenceLength; //fill a silence to prevent pop up noise
DTMF_SW.RingBuffer.read=0;
pAllocBuf += uPcmBufSize * DTMF_BUFFERED_FRAME_NUMBER;
DTMF_SW.pHandle = DTMF_Init( (void *)pAllocBuf, DTMF_CONTINUOUS, uSr, DTMF_MONO);
ASSERT(DTMF_SW.pHandle);
DTMF_SW.uAudId = L1Audio_GetAudioID();
L1Audio_SetFlag( DTMF_SW.uAudId );
L1Audio_SetEventHandler( DTMF_SW.uAudId, dtmf_mcu_Process );
}
uint32 EXT_BGSND_Start(void (*offHdr)(void),
void (*DLHisr)(void), //move data from src -> ext
void (*ULHisr)(void), //move data from src -> ext
kal_int8 DLSNDGain,
kal_int8 ULSNDGain /*,
void (*EventHandler)(void)*/)
{
int i, j;
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] Enter");
ASSERT(!(NULL==DLHisr && NULL==ULHisr));
ASSERT(NULL!=offHdr); //without this, we cannot stop DSP BGSND
for(i=0; i<MAX_SIZE_EXT_BGSND_SRC; i++){
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] debug1 i=%d", i);
if(!Ext_BGSnd.is_used[i]){
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] debug2 i=%d", i);
EXT_BGSND_SRC_T *pSrc = &Ext_BGSnd.src[i];
pSrc->Hdr[BGSND_DL_PROCESS] = DLHisr;
pSrc->Hdr[BGSND_UL_PROCESS] = ULHisr;
pSrc->offHdr = offHdr;
for(j=0; j<MAX_NUM_BGSND_PROCESS; j++){//TODO temp solution
pSrc->state[j] = EXT_SRC_STATE_RUN;
//pSrc->fSph[j] = true; //TODO
//pSrc->gain[j] = 7; //TODO
// buffer reset
memset(pSrc->buffer[j], 0, sizeof(kal_uint16)*EXT_BGSND_SRC_BUF_SIZE);
pSrc->bufSize[j] = EXT_BGSND_SRC_BUF_SIZE;
pSrc->bufRead[j] = 0;
pSrc->bufWrite[j] = EXT_BGSND_BUF_PTR_DIFF;
}
if(AM_IsSpeechOn() || AM_IsVoIPOn()){
EXT_BGSND_ConfigMixer(i, true, DLSNDGain, BGSND_DL_PROCESS);
EXT_BGSND_ConfigMixer(i, true, ULSNDGain, BGSND_UL_PROCESS);
}else{
EXT_BGSND_ConfigMixer(i, false, DLSNDGain, BGSND_DL_PROCESS);
EXT_BGSND_ConfigMixer(i, false, ULSNDGain, BGSND_UL_PROCESS);
}
Ext_BGSnd.is_used[i] = true;
if( 0 == Ext_BGSnd.num_src_used++){
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] selected_src_id=%d num_src_used=%d", i, Ext_BGSnd.num_src_used);
// lock DSP for sherif writing.
L1Audio_SetFlag( Ext_BGSnd.aud_id ); // REIMIND: Before Locking SleepMode, to access DSP sherrif tasks much time. So access DSP must be after SetFlag1
DSP_BGSND_Start(EXT_BGSND_DLHisr, EXT_BGSND_ULHisr);
}
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] debug3 i=%d", i);
break;
}
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] debug4 i=%d", i);
}
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] debug5 i=%d", i);
ASSERT(i < MAX_SIZE_EXT_BGSND_SRC);
kal_prompt_trace(MOD_L1SP, "[EXT_BGSND_Start] Leave");
return i;
}
/**
The function starts the background sound playback of the media handle.
@bgSnd_hdlr: handler
@ULGainLevel: uplink gain level, from 0~7
@DLGainLevel: downlink gain level, from 0~7
*/
void BGSND_Start(void (*bgSnd_hisrHandler)(void), void (*bgSnd_offHandler)(void),
kal_uint8 ULGainLevel , kal_uint8 DLGainLevel)
{
kal_trace( TRACE_FUNC, L1SND_ENTER_BGSND_START );
// clean up
bgSnd.dspLastSample = 0;
bgSnd.endCount = 0;
// buffer reset
memset(bgSndBuf, 0, sizeof(kal_uint16)*BGSND_BUF_SIZE);
bgSnd.pBuf = bgSndBuf;
bgSnd.bufSize = BGSND_BUF_SIZE;
bgSnd.bufRead = 0;
bgSnd.bufWrite = BGSND_BUF_PTR_DIFF;
// clear hisr flag
bgSnd.isDlHisrCome = false;
bgSnd.isUlHisrCome = false;
// lock DSP for sherif writing.
L1Audio_SetFlag( bgSnd.aud_id ); // REIMIND: Before Locking SleepMode, to access DSP sherrif tasks much time. So access DSP must be after SetFlag1
// L1Audio_SetEventHandler(bgSnd.aud_id, BGSND_eventHandler );
bgSnd.bgSnd_hisrHandler = bgSnd_hisrHandler;
#ifdef DSP_BGS_UP_DOWN_INT_SEPERATE
L1Audio_HookHisrHandler(D2C_SOUND_EFFECT_INT_ID_DL, bgsndDlHisr, 0);
L1Audio_HookHisrHandler(D2C_SOUND_EFFECT_INT_ID_UL, bgsndUlHisr, 0);
#else
L1Audio_HookHisrHandler(D2C_SOUND_EFFECT_INT_ID_DL, bgsndHisr, 0);
#endif
bgSnd.bgSnd_offHandler = bgSnd_offHandler;
// gain setting and update
if(AM_IsSpeechOn()){
BGSND_ConfigULMixer(KAL_TRUE, ULGainLevel);
BGSND_ConfigDLMixer(KAL_TRUE, DLGainLevel);
} else {
BGSND_ConfigULMixer(KAL_FALSE, ULGainLevel);
BGSND_ConfigDLMixer(KAL_FALSE, DLGainLevel);
}
bgsndUpdateMixer();
// Before dynamic download, all application should be off.
// But background sound do not need to dynamic download, so the following is unnecessary.
// KT_StopAndWait();
// turn on.
bgsndOnHandler();
// L1SP_Register_BgsService(bgsndOnHandler, bgsndOffHandler);
bgSnd.state = BGSND_STATE_RUN;
}
void AVB_Open()
{
kal_uint32 uWorkingBuffer;
kal_trace( TRACE_GROUP_SCO, L1AUDIO_AVB_OPEN, AVB.uState);
ASSERT(AVB.uState == AVB_STATE_IDLE);
ASSERT(AVB.uSampleRate);
PcmSink_StartBT(PCMSINK_BT_SCO);
mhdlHookPcmRut();
BLI_GetMemSize(AVB.uSampleRate, AVB.uChannelNumber, AVB_SAMPLE_RATE, AVB_CHANNEL_NUM, &uWorkingBuffer);
uWorkingBuffer = (uWorkingBuffer+3) & ~3;
AVB.pBuffer = (kal_uint16 *)audio_alloc_mem_cacheable(uWorkingBuffer + AVB_DSP_BUFFER_SIZE + AVB_SRC_BUFFER_SIZE);
ASSERT(AVB.pBuffer);
AVB.pBLISRC = BLI_Open(AVB.uSampleRate, AVB.uChannelNumber, AVB_SAMPLE_RATE, AVB_CHANNEL_NUM, ((kal_int8*)AVB.pBuffer)+AVB_DSP_BUFFER_SIZE, audio_alloc_ext_mem_cacheable_simplified);
ASSERT(AVB.pBLISRC);
AVB.PCM.rb_base = ((kal_int8*)AVB.pBuffer)+AVB_DSP_BUFFER_SIZE+uWorkingBuffer;
AVB.PCM.rb_size = AVB_SRC_BUFFER_SIZE;
AVB.PCM.write = 0;
AVB.PCM.read = 0;
AVB.uAudID = L1Audio_GetAudioID();
L1Audio_SetFlag( AVB.uAudID );
L1Audio_SetEventHandler( AVB.uAudID, AVB_Process );
AVB.uState = AVB_STATE_RUNING;
L1Audio_HookHisrHandler( D2C_AUDIO_VIA_8KBT_ID, AVB_HISR, 0);
}
/*****************************************************************************
* FUNCTION
* TONE_Play
* DESCRIPTION
* This function is used to play comfort tones.
*
* PARAMETERS
* tonelist - Tone list
* RETURNS
* None.
* GLOBALS AFFECTED
* None
*****************************************************************************/
void TONE_Play( const L1SP_Tones *tonelist )
{
if( L1Audio_CheckFlag( tone.aud_id ) )
return;
if (tone.state != TONE_STATE_NONE)
return;
if( L1Audio_CheckFlag( keytone.aud_id ) ) {
KT_StopAndWait();
}
L1Audio_SetFlag( tone.aud_id );
tone.tonelist = tonelist;
tone.fc_aud_id = L1Audio_FC_HookHandler( (void *)0, toneMsgHandler, 0, (FC_MEDIA_FORMAT_QTMF<<8)|MEDIA_OPERATE_PLAYBACK );
tone.state = TONE_STATE_IDLE;
tone.isReentrance = false;
tone.seqNum++;
tonePlayOn( 0 );
AM_ToneOn();
}
Media_Status I2S_Open( void ){
#ifdef __I2S_UNIT_TEST__
kal_uint16 sr = Media_I2S_INPUT_MODE_SR_UT;
#else
kal_uint16 sr = Media_I2S_INPUT_MODE_SR;
#endif
#if defined(MT6256) || defined(MT6255) || defined(MT6250) || defined(MT6260)
#if defined(__INTERAL_FM_VIA_I2S__)
kal_uint8 isspkmute = 0;
#endif
#endif
#if defined(__VIBRATION_SPEAKER_SUPPORT__)
VIBR_Vibration_Deactivate();
#endif
PcmSink_TerminateSound();
#if defined(__AUDIO_COMPONENT_SUPPORT__)
Media_SetIsDSPDec(KAL_TRUE); // to bypass sink component
#endif
kal_trace( TRACE_FUNC, L1AUDIO_I2S_ENABLE, ASP_TYPE_I2SBypass, sr );
ASSERT( sr == 32000 || sr == 44100 || sr == 48000 );
ASSERT( I2S_RECORD_STATE_CLOSED == i2s.state);
i2s.is_ON = KAL_TRUE;
i2s.state = I2S_RECORD_STATE_INIT;
i2s.sample_rate = sr;
i2s.aud_id = L1Audio_GetAudioID();
#if defined(__BES_LOUDNESS_ON_I2S__)
AudioPP_Loudness_Registry();
#endif
#if defined(__AUDIO_DSP_LOWPOWER_V2__)
#if defined(MT6256) || defined(MT6255)
if (!APM_IsLoudnessOn())
#endif
#if !(defined(MT6260) && defined(INTERNAL_ANTENNAL_SUPPORT))
AUDLP_Mode(KAL_TRUE, 1);
#endif
if(AUDLP_Check_LowPower_Status())
{
L1Audio_SetFlag_MD2G( i2s.aud_id );
#if defined(MT6250) || defined(MT6260)
AUDLP_Set_ClkSwitchMode(KAL_TRUE);
AUDLP_SW_Trigger_Event_Setting(KAL_TRUE);
AUDLP_SetClkSwitch_26M(KAL_TRUE);
#endif
}
else
L1Audio_SetFlag( i2s.aud_id );
#else
L1Audio_SetFlag( i2s.aud_id );
#endif
ktLock();
KT_StopAndWait();
TONE_StopAndWait();
AM_Force_VBI_END_IN_TASK();
Media_SetSampleRate(sr);
Media_SetAudioFormat(MEDIA_FORMAT_UNKNOWN);
*DSP_AUDIO_CTRL2 |= DP_PCM_R_DIS;
*DSP_AUDIO_FLEXI_CTRL |= (FLEXI_VBI_ENABLE | FLEXI_SD_ENABLE);
#if defined(MT6250) || defined(MT6260)
*I2S_PLAYERROR_INFO = 0;
*I2S_PLAYERROR_CONTROL = 0;
#endif
#if !defined(__CACHED_BASE_DSP__)
DSP_DynamicDownload ( DDID_I2S );
#endif
//should add a parameter to indicate input or output
AFE_TurnOnEDI( 1, 1, L1SP_I2S_INPUT_SCALE >> 1 );
#if defined(__AUDIO_COMPONENT_SUPPORT__)
i2s_sample_rate = i2s.sample_rate;
ASSERT(i2s.ihdl==NULL);
AudioRoute2Drain_Init(&i2s.ihdl, 0);
AudioRoute2Drain_Start(i2s.ihdl);
#endif
//should not turn on output mode and input mode at the same time
if( sr == 32000 )
sr = ASP_FS_32K;
else if ( sr == 44100 )
sr = ASP_FS_44K;
else
sr = ASP_FS_48K;
#if defined(MT6260)
#if defined(__INTERAL_FM_VIA_I2S__)
if(I2S_is_FM())
*HW_MISC_REG |=0x0001;
#endif
#endif
#if defined(__INTERAL_FM_VIA_I2S__)
if(!I2S_is_FM())
#endif
I2S_Input_GPIO_TurnOn();
#if defined(MT6256) || defined(MT6255) || defined(MT6250) || defined(MT6260)
#if defined(__INTERAL_FM_VIA_I2S__)
if(!I2S_is_FM())
{
if(!AFE_IsSpeakerMuted())
{
AFE_MuteSpeaker(L1SP_AUDIO, KAL_TRUE);
isspkmute = 1;
}
}
#endif
#endif
#if defined(MT6250)
L1Audio_HookHisrHandler(DP_D2C_I2S_REC_INT, I2S_DspIntHISR, 0);
#endif
#if defined(__AUDIO_COMPONENT_SUPPORT__) && !defined(MED_MODEM)
PcmSink_DepopMute(400); //depop
#endif
AM_AudioPlaybackOn( ASP_TYPE_I2SBypass, sr );
#if defined(MT6256) || defined(MT6255) || defined(MT6250) || defined(MT6260)
#if defined(__INTERAL_FM_VIA_I2S__)
if(!I2S_is_FM())
{
kal_sleep_task(45);
if(isspkmute)
AFE_MuteSpeaker(L1SP_AUDIO, KAL_FALSE);
}
#endif
#endif
return MEDIA_SUCCESS;
}
void DACA_Start(void (*daca_dl_hdlr)(void), void (*daca_ul_hdlr)(void), DACA_APP_TYPE app_type)
{
uint32 I;
//Sal_PCMEx_Config_t cfg_t;
//cfg_t.idle = false;//initialized;
dacaEx.aud_daca_id = L1Audio_GetAudioID();
L1Audio_SetFlag( dacaEx.aud_daca_id );
L1Audio_HookHisrHandler(DP_D2C_DACA_REQ_DL,(L1Audio_EventHandler)Daca_hisrDlHdlr, 0);
L1Audio_HookHisrHandler(DP_D2C_DACA_REQ_UL,(L1Audio_EventHandler)Daca_hisrUlHdlr, 0);
dacaEx.daca_dl_hdlr = daca_dl_hdlr;
dacaEx.daca_ul_hdlr = daca_ul_hdlr;
dacaEx.app_type = app_type;
if(app_type & DACA_IN_PHONE_CALL){
dacaEx.am_type = AM_PCMEX_TYPE_DACA_DEDICATION;
}else{
dacaEx.am_type = AM_PCMEX_TYPE_DACA_IDLE_WO_ENH;
}
if(app_type & DACA_USE_NB){
dacaEx.frame_size = 160;//PCMNWAY_BAND_INFO_NB;
// cfg_t.band = SAL_PCM_NARROWBAND;
}else{
dacaEx.frame_size = 320;//PCMNWAY_BAND_INFO_WB;
// cfg_t.band = SAL_PCM_WIDEBAND;
}
/* the begining of configure the SAL */
if(app_type & DACA_USE_UL){
SAL_PcmEx_SetStateUL(SAL_PCMEX_TYPE_DACA, SAL_PCMEX_ON);
}
if(app_type & DACA_USE_DL){
SAL_PcmEx_SetStateDL(SAL_PCMEX_TYPE_DACA, SAL_PCMEX_ON);
}
//cfg_t.swi = SAL_PCMEX_SWITCH_ON;
//cfg_t.type = SAL_PCMEX_TYPE_DACA;
//cfg_t.band = (app_type & DACA_USE_NB) ? SAL_PCM_NARROWBAND : SAL_PCM_WIDEBAND;
AM_PCM_EX_On(dacaEx.am_type, &dacaEx);
for(dacaEx.state = DACA_STATE, I = 0; ;I ++){
kal_bool is_ready = true;
if((dacaEx.app_type & DACA_USE_UL) && (!SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_DACA, SAL_PCMEX_RDY)))
is_ready = false;
if((dacaEx.app_type & DACA_USE_DL) && (!SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_DACA, SAL_PCMEX_RDY)))
is_ready = false;
if(is_ready)
break;
ASSERT(I < 22); // wait 200ms
kal_sleep_task(2);
}
/* the end of configure the SAL */
}
/**
@pcmNway_dl_hdlr
@pcmNway_ul_hdlr:
*/
void Idle_PcmEx_Start(void (*pcmNway_dl_hdlr)(void), void (*pcmNway_ul_hdlr)(void),
uint32 cfgUL1, uint32 cfgUL2, uint32 cfgUL3, uint32 cfgUL4, uint32 cfgDL,
PCMEX_BAND band, PCMEX_IDLE_ENH_SETTING enhSetting)
{
uint32 I;
kal_bool flag;
// prevent re-entry!!
ASSERT(PNW_STATE_IDLE == pcmEx.state);
pcmEx.aud_id = L1Audio_GetAudioID();
L1Audio_SetFlag( pcmEx.aud_id ); /*Be careful.Before Locking SleepMode, to access DSP sherrif tasks much time. So access DSP must be after SetFlag*/
// band and am type setting
pcmEx.bandInfo = band;
switch(band){
case PCMEX_BAND_NB:
{
ASSERT(enhSetting != PCMEX_IDLE_ENH_SETTING_NONE);
if(PCMEX_IDLE_ENH_SETTING_DMNR_REC_ONLY_CAL == enhSetting) {
// pcmEx.dspPcmExMicLen = 322; //160*2+2 samples(word)
// pcmEx.dspPcmExSpkLen = -1;
pcmEx.am_type = AM_PCMEX_TYPE_REC_ONLY_CAL;
}
else if (PCMEX_IDLE_ENH_SETTING_DMNR_CAL == enhSetting) {
// pcmEx.dspPcmExMicLen = 322; //160*2+2 samples(word)
// pcmEx.dspPcmExSpkLen = 160;
pcmEx.am_type = AM_PCMEX_TYPE_REC_PLAY_CAL;
} else {
// pcmEx.dspPcmExMicLen = 160;
// pcmEx.dspPcmExSpkLen = 160;
pcmEx.am_type = AM_PCMEX_TYPE_IDLE;
}
}
break;
case PCMEX_BAND_WB:
{
ASSERT(enhSetting != PCMEX_IDLE_ENH_SETTING_NONE);
if(PCMEX_IDLE_ENH_SETTING_DMNR_REC_ONLY_CAL == enhSetting) {
// pcmEx.dspPcmExMicLen = 642; //320*2+2 samples(word)
// pcmEx.dspPcmExSpkLen = -1;
pcmEx.am_type = AM_PCMEX_TYPE_REC_ONLY_CAL;
}
else if (PCMEX_IDLE_ENH_SETTING_DMNR_CAL == enhSetting) {
// pcmEx.dspPcmExMicLen = 642; //320*2+2 samples(word)
// pcmEx.dspPcmExSpkLen = 160;
pcmEx.am_type = AM_PCMEX_TYPE_REC_PLAY_CAL;
} else {
// pcmEx.dspPcmExMicLen = 320;
// pcmEx.dspPcmExSpkLen = 320;
pcmEx.am_type = AM_PCMEX_TYPE_IDLE;
}
}
break;
default: // include PCMEX_BAND_DYNAMIC and PCMEX_BAND_UNSET cases
ASSERT(0);
}
pcmEx.cfgUL1 = cfgUL1;
pcmEx.cfgUL2 = cfgUL2;
pcmEx.cfgUL3 = cfgUL3;
pcmEx.cfgUL4 = cfgUL4;
pcmEx.cfgDL = cfgDL;
pcmEx.pnw_dl_hdlr = pcmNway_dl_hdlr;
pcmEx.pnw_ul_hdlr = pcmNway_ul_hdlr;
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_DL,(L1Audio_EventHandler)pcmEx_hisrDlHdlr, 0);
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_UL,(L1Audio_EventHandler)pcmEx_hisrUlHdlr, 0);
// check DSP state and turn on
ASSERT(SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF) && SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF));
AM_PCM_EX_On(pcmEx.am_type, (uint32)(&pcmEx));//to config pnw
SAL_PcmEx_SetStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
SAL_PcmEx_SetStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
// wait for ready
for(I = 0; ;I ++){
kal_bool is_ready = true;
if( (pcmEx.cfgDL & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if( (pcmEx.cfgUL1 & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if(is_ready)
break;
#ifndef L1D_TEST
ASSERT(I < 22); // wait 200ms
kal_sleep_task(2);
#endif
}
pcmEx.state = PNW_STATE_RUN;
if(PCMEX_IDLE_ENH_SETTING_WITH == enhSetting) {
pcmEx.isEnhOn = true;
SetSpeechEnhancement(true);
}
/* the end of configure the SAL */
}
/* ========================================================================= */
void SPE_CustomProcess_On(kal_uint16 sph_mode, SPE_Par_Struct *SPE_PAR, kal_uint8 *state)
{
#if defined( __VOICE_CHANGER_SUPPORT__ )
SPH_VOICE_CHANGER_MODE mode = 0;
// Apply VCH only in speech
if(!AM_IsSpeechOn())
{
return;
}
if (!VCHIsDcmLoad)
{
DCM_Load(DYNAMIC_CODE_COMPRESS_VCH , 0, 0);
VCHIsDcmLoad = KAL_TRUE;
}
kal_trace( TRACE_GROUP_AUD_SPE_CSUT, SPEECH_VCH_PROCESS, 1, VCHIsDcmLoad);
#endif
spe_custom = audio_alloc_mem_cacheable(sizeof(SPE_CUSTOM_STRUCT));
memset(spe_custom, 0, sizeof(SPE_CUSTOM_STRUCT));
/*Copy the actual parameters to control structure*/
spe_custom->aud_id = L1Audio_GetAudioID();
#if defined(__INTERNAL_SPE_ENGINE__)
{
kal_uint16 i;
kal_uint32 aec_mem_size;
for(i=0;i<16;i++)
spe_custom->Sph_Enh_ctrl.enhance_pars[i] = SPE_PAR->mode_par[i];
for(i=0;i<12;i++)
spe_custom->Sph_Enh_ctrl.enhance_pars[i+16] = SPE_PAR->common_par[i];
aec_mem_size = ENH_API_Get_Memory(&spe_custom->Sph_Enh_ctrl);
if(aec_mem_size > 0) {
spe_custom->working_buffer = audio_alloc_mem_cacheable( aec_mem_size * sizeof(kal_int8) );
memset(spe_custom->working_buffer, 0, aec_mem_size * sizeof(kal_int8));
ENH_API_Alloc(&spe_custom->Sph_Enh_ctrl, (kal_uint32 *)spe_custom->working_buffer);
} else
spe_custom->working_buffer = NULL;
ENH_API_Init(&spe_custom->Sph_Enh_ctrl, SPE_PAR->out_fir, SPE_PAR->in_fir);
}
#elif defined( __VOICE_CHANGER_SUPPORT__ )
spe_custom->working_buffer = audio_alloc_mem_cacheable( PCM_BUFFER_LENGTH*2*sizeof(kal_uint8));
if(spe_custom->working_buffer != NULL)
{
memset(spe_custom->working_buffer, 0, PCM_BUFFER_LENGTH*2*sizeof(kal_uint8));
}
#endif
L1Audio_SetEventHandler(spe_custom->aud_id , spe_custom_task);
L1Audio_SetFlag(spe_custom->aud_id);
spe_custom->state = SPE_STATE_WORKING;
#if defined( __VOICE_CHANGER_SUPPORT__ )
mode = L1SP_GetVoiceChangerMode();
VCHG_Open(8,mode);
#endif
#if 1
PCM4WAY_Start(spe_custom_hisr_hdlr, 0);
#else
/* under construction !*/
/* under construction !*/
/* under construction !*/
#endif
}
/* ------------------------------------------------------------------------------ */
void L1Audio_Task(unsigned argc, void *argv)
{
uint32 retrieved_events;
uint32 I;
uint16 tempID;
l1audio.aud_events = kal_create_event_group("L1Audio");
l1audio.hisr = kal_init_hisr(L1AUDIO_HISR);
GET_SLEEP_HANDLE();
#if ( defined( __CENTRALIZED_SLEEP_MANAGER__ ) && defined(MTK_SLEEP_ENABLE) && !defined(__AUDIO_POWERON_RESET_DSP__) )
l1audio.md2g_pdn_handle = L1D_MD2G_PWD_GetHandle();
l1audio.l1sm_handle = L1SM_IntGetHandle();
#endif
l1audio.runningState = 0;
l1audio.disallowSleepState = 0;
l1audio.dsp_slow_idle_counter = 0;
l1audio.event_flag = 0;
l1audio.id_flag = 0;
l1audio.media_flag = 0;
l1audio.postHisrHandler = (L1Audio_EventHandler)0;
l1audio.sema = kal_create_sem( "Aud_Sema", 1 );
l1audio.hisrMagicFlag = 0;
for( I = 0; I < MAX_HISR_HANDLER; I++ )
l1audio.hisrMagicNo[I] = 0;
tempID = L1Audio_GetAudioID();
L1Audio_SetFlag(tempID);
DSP_DynamicDownload_Init();
#ifndef L1D_TEST
/// Dynamic download for A/V sync
#if defined( DSP_WT_SYN ) && !defined(__AUDIO_COMPONENT_SUPPORT__)
DSP_DynamicDownload( DDID_WAVETABLE );
#endif
#endif
AM_Init();
#if APM_SUPPORT
APM_Init();
#endif
/// AFE_Init will invoke L1Audio_GetAudioID
/// and expect to get the id 0 to make sure
/// it has the highest priority in the event group
AFE_Init();
#if !defined(__SMART_PHONE_MODEM__) && !defined(__L1_STANDALONE__) && !defined( MED_MODEM )
AVsync_Init();
#endif
#if defined(__AUDIO_POWERON_RESET_DSP__)
{
uint32 _savedMask;
_savedMask = SaveAndSetIRQMask();
AFE_Init_status(KAL_TRUE);
AFE_RegisterBackup();
RestoreIRQMask(_savedMask);
}
#endif
L1SP_Init();
ktInit( L1Audio_GetAudioID() );
toneInit( L1Audio_GetAudioID() );
mediaInit( L1Audio_GetAudioID() );
#if defined(VR_CYBERON)
vrsdInit();
#elif defined(VRSI_CYBERON)
vrsiInit();
#endif
toneLoopbackRecInit();
#if ( defined(__BT_A2DP_PROFILE__) || defined(SBC_UNIT_TEST) ) //&& !(APM_SUPPORT)
SBC_Init();
#endif
#if defined(__BES_TS_SUPPORT__)
AudioPP_TS_Init();
#endif
#ifdef __CTM_SUPPORT__
l1ctm_init();
#endif
#ifdef __TWOMICNR_SUPPORT__
Two_Mic_NR_chip_Init();
#endif
#if VMI_SUPPORT || defined(VORTP_UNIT_TEST)
VMI_Init();
#endif
#if VORTP_SUPPORT || defined(VORTP_UNIT_TEST)
VoRTP_Init();
#endif
#if defined(CYBERON_DIC_TTS) || defined(IFLY_TTS) || defined(SINOVOICE_TTS)
ttsInit();
#endif
#if defined( DSP_WT_SYN ) && !defined(__AUDIO_COMPONENT_SUPPORT__)
DSPSYN_HW_Init();
#endif
#if defined( __I2S_INPUT_MODE_SUPPORT__ )
I2S_init();
#endif
#if defined(__VOICE_CHANGER_SUPPORT__)
VCHG_Initialize();
#endif
#if defined(__AUDIO_COMPONENT_SUPPORT__) && !defined(__L1_STANDALONE__) && !defined(MED_MODEM)
// KH : for audio component
ACU_Init();
#endif
#if defined(__CVSD_CODEC_SUPPORT__)
{
extern void BT_SCO_Init(void);
BT_SCO_Init();
}
#endif
memset( &(l1audio.debug_info), 0, sizeof(l1audio.debug_info) );
AFE_TurnOnFIR( L1SP_SPEECH );
AFE_TurnOnFIR( L1SP_VOICE );
L1Audio_ClearFlag(tempID);
L1Audio_FreeAudioID(tempID);
l1audio.isInitiated = KAL_TRUE;
while( 1 ) {
#if VERIFY_DATA_TO_DSP
VERIFY_DATA_TO_DSP_SAVE_DATA();
#endif
kal_retrieve_eg_events(l1audio.aud_events,0xFFFF,KAL_OR_CONSUME,&retrieved_events,KAL_SUSPEND);
l1audio.retrieved_events = retrieved_events;
l1audio.events_l1FN = L1I_GetTimeStamp();
for( I = 0; I < MAX_AUDIO_FUNCTIONS; I++ ) {
if ( l1audio.retrieved_events & (1<<I) ) {
l1audio.evHandler[I]( l1audio.evData[I] );
}
}
//if( (l1audio.runningState & l1audio.disallowSleepState) == 0 )
if( l1audio.runningState == 0 )
SLEEP_UNLOCK();
}
}
/**
@type: please refer to P2W_App_Type.
0 for pcm4way CTM,
1 for pcm2way Voice,
2 for pcm2way Voip,
3 for pcm2Way record only(calibration used),
4 for pcm2Way record&playback(calibration used)
*/
void Extended_PCM2WAY_Start(void (*pcm2way_dl_hdlr)(void), void (*pcm2way_ul_hdlr)(void), uint32 type, uint32 cfgUL, uint32 cfgDL)
{
uint32 I;
kal_bool flag;
// Sal_PCMEx_Config_t cfg_t;
// cfg_t.idle = false;//initialized
pcmEx.aud_id = L1Audio_GetAudioID();
L1Audio_SetFlag( pcmEx.aud_id ); /*Be careful.Before Locking SleepMode, to access DSP sherrif tasks much time. So access DSP must be after SetFlag*/
// for band infomation checking, user should usd PCM2Way_SetFormat() to set format before pcm2way start
ASSERT(pcmEx.bandInfo != PCMNWAY_BAND_INFO_UNSET );
pcmEx.app_type = type;
// TODO:
flag = true; //this flag is used to choose one among multiple options
switch (type) { // type checking and pcm2way application type mapping to am type
//group1 has the similar settings
case P2W_APP_TYPE_UNDER_CALL:
if(flag){pcmEx.am_type = AM_PCMEX_TYPE_DEDICATION;flag=false;}
case P2W_APP_TYPE_WITHOUT_CALL:
if(flag){pcmEx.am_type = AM_PCMEX_TYPE_IDLE_WO_ENH;flag=false;}
case P2W_APP_TYPE_VOIP:
if(flag){pcmEx.am_type = AM_PCMEX_TYPE_IDLE;flag=false;}
if(PCMNWAY_BAND_INFO_WB == PCM2Way_GetBandInfo()){
PCM2WAY_QueryBufSize(P2W_FORMAT_WB_NORMAL, &(pcmEx.u4DspPcmExMicLen), &(pcmEx.u4DspPcmExSpkLen));
} else {
PCM2WAY_QueryBufSize(P2W_FORMAT_NORMAL, &(pcmEx.u4DspPcmExMicLen), &(pcmEx.u4DspPcmExSpkLen));
}
break;
#if defined(__DUAL_MIC_SUPPORT__) || defined(__SMART_PHONE_MODEM__)
//group2 has the similar settings
case P2W_APP_TYPE_REC_ONLY_CAL:
if(flag){pcmEx.am_type = AM_PCMEX_TYPE_REC_ONLY_CAL;flag=false;}
case P2W_APP_TYPE_REC_PLAY_CAL:
if(flag){pcmEx.am_type = AM_PCMEX_TYPE_REC_PLAY_CAL;flag=false;}
if(PCMNWAY_BAND_INFO_NB == PCM2Way_GetBandInfo()){
PCM2WAY_QueryBufSize(P2W_FORMAT_CAL, &(pcmEx.u4DspPcmExMicLen), &(pcmEx.u4DspPcmExSpkLen));
} else if(PCMNWAY_BAND_INFO_WB == PCM2Way_GetBandInfo()){
PCM2WAY_QueryBufSize(P2W_FORMAT_WB_CAL, &(pcmEx.u4DspPcmExMicLen), &(pcmEx.u4DspPcmExSpkLen));
} else {
ASSERT(0); // calibration does NOT support dynamic band setting
}
pcmEx.u4DspPcmExMicLen -= 2; //AGC is put in the sherif instead of buffer
break;
#endif //__DUAL_MIC_SUPPORT__ || defined(__SMART_PHONE_MODEM__)
default:
ASSERT(0);
}
ASSERT(SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF) && SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF));
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_DL,(L1Audio_EventHandler)pcmEx_hisrDlHdlr, 0);
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_UL,(L1Audio_EventHandler)pcmEx_hisrUlHdlr, 0);
pcmEx.pnw_dl_hdlr = pcm2way_dl_hdlr;
pcmEx.pnw_ul_hdlr = pcm2way_ul_hdlr;
pcmEx.state = PCM2WAY_STATE;
pcmEx.cfgUL = cfgUL;
pcmEx.cfgDL = cfgDL;
/* the begining of configure the SAL */
/* the following is the same as the pcm4way. In the future, it'll be merged together */
/*
cfg_t.D2M_ul = cfg_t.M2D_ul = cfg_t.afterEnh_ul = cfg_t.D2M_dl = cfg_t.M2D_dl = cfg_t.afterEnh_dl = false;
if(cfgUL & USE_D2M_PATH){
cfg_t.D2M_ul = true;
}
if(cfgUL & USE_M2D_PATH){
cfg_t.M2D_ul = true;
}
if(cfgUL & DATA_SELECT_AFTER_ENH){
cfg_t.afterEnh_ul = true;
}
if(cfgDL & USE_D2M_PATH){
cfg_t.D2M_dl = true;
}
if(cfgDL & USE_M2D_PATH){
cfg_t.M2D_dl = true;
}
if(cfgDL & DATA_SELECT_AFTER_ENH){
cfg_t.afterEnh_dl = true;
}
cfg_t.swi = SAL_PCMEX_SWITCH_ON;
cfg_t.type = SAL_PCMEX_TYPE_PNW;
if(AM_IsSpeechOn()){
cfg_t.band = SAL_PCM_DYNAMIC;
}else{
if(pcmEx.bandInfo == PCMNWAY_BAND_INFO_WB){
cfg_t.band = SAL_PCM_WIDEBAND;
}else if (pcmEx.bandInfo == PCMNWAY_BAND_INFO_NB){
cfg_t.band = SAL_PCM_NARROWBAND;
}else{ // should never been here
ASSERT(0);
}
}
*/
AM_PCM_EX_On(pcmEx.am_type, (uint32)(&pcmEx));//to config pnw
SAL_PcmEx_SetStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
SAL_PcmEx_SetStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
for(I = 0; ;I ++){
kal_bool is_ready = true;
if( (pcmEx.cfgDL & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if( (pcmEx.cfgUL & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if(is_ready)
break;
#ifndef L1D_TEST
ASSERT(I < 22); // wait 200ms
kal_sleep_task(2);
#endif
}
/* the end of configure the SAL */
}
void Extended_PCM4WAY_Start(void (*pcm4way_dl_hdlr)(void), void (*pcm4way_ul_hdlr)(void), uint32 type, uint32 cfgUL, uint32 cfgDL)
{
uint32 I;
pcmEx.aud_id = L1Audio_GetAudioID();
L1Audio_SetFlag( pcmEx.aud_id );
// mapping the pcm4way applicatoin type to am type, and setup the band informtion.
pcmEx.app_type = type;
switch (type) {
case P4W_APP_CTM:
case P4W_APP_TYPE_UNDER_CALL:
pcmEx.am_type = AM_PCMEX_TYPE_DEDICATION;
pcmEx.bandInfo = PCMNWAY_BAND_INFO_DYNAMIC;
break;
case P4W_APP_TYPE_WITHOUT_CALL:
pcmEx.am_type = AM_PCMEX_TYPE_IDLE_WO_ENH;
pcmEx.bandInfo = PCMNWAY_BAND_INFO_NB;
break;
}
ASSERT(SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF) && SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_OFF));
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_DL,(L1Audio_EventHandler)pcmEx_hisrDlHdlr, 0);
L1Audio_HookHisrHandler(DP_D2C_PCM_EX_UL,(L1Audio_EventHandler)pcmEx_hisrUlHdlr, 0);
pcmEx.pnw_dl_hdlr = pcm4way_dl_hdlr;
pcmEx.pnw_ul_hdlr = pcm4way_ul_hdlr;
pcmEx.state = PCM4WAY_STATE;
pcmEx.cfgDL = cfgDL;
pcmEx.cfgUL = cfgUL;
/* the begining of configure the SAL */
/*
cfg_t.D2M_ul = cfg_t.M2D_ul = cfg_t.afterEnh_ul = cfg_t.D2M_dl = cfg_t.M2D_dl = cfg_t.afterEnh_dl = false;
if(cfgUL & USE_D2M_PATH){
cfg_t.D2M_ul = true;
}
if(cfgUL & USE_M2D_PATH){
cfg_t.M2D_ul = true;
}
if(cfgUL & DATA_SELECT_AFTER_ENH){
cfg_t.afterEnh_ul = true;
}
if(cfgDL & USE_D2M_PATH){
cfg_t.D2M_dl = true;
}
if(cfgDL & USE_M2D_PATH){
cfg_t.M2D_dl = true;
}
if(cfgDL & DATA_SELECT_AFTER_ENH){
cfg_t.afterEnh_dl = true;
}
cfg_t.swi = SAL_PCMEX_SWITCH_ON;
cfg_t.type = SAL_PCMEX_TYPE_PNW;
*/
AM_PCM_EX_On(pcmEx.am_type, (uint32)(&pcmEx));//to config pnw
SAL_PcmEx_SetStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
SAL_PcmEx_SetStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_ON);
for(I = 0; ;I ++){
kal_bool is_ready = true;
if( (pcmEx.cfgDL & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateDL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if( (pcmEx.cfgUL & (USE_D2M_PATH+USE_M2D_PATH)) && (!SAL_PcmEx_CheckStateUL(SAL_PCMEX_TYPE_PNW, SAL_PCMEX_RDY)))
is_ready &= false;
if(is_ready)
break;
#ifndef L1D_TEST
ASSERT(I < 22); // wait 200ms
kal_sleep_task(2);
#endif
}
/* the end of configure the SAL */
}
void KT_Play( uint16 freq1, uint16 freq2, uint16 duration )
{
#if defined(KEYTONE_DEBUG)
uint8 pressed_key;
pressed_key = 0;
switch(freq1) {
case 697:
pressed_key = 1;
break;
case 770:
pressed_key = 4;
break;
case 852:
pressed_key = 7;
break;
case 941:
pressed_key = 10; //*
break;
}
switch(freq2) {
case 1209:
pressed_key += 0;
break;
case 1336:
pressed_key += 1;
break;
case 1477:
pressed_key += 2;
break;
}
//===================================================================
if(pressed_key == 10) // *
KeyFlags = 0x1;
else if(pressed_key == 12) // #
{
if(KeyFlags == 0x3)
{
switch(KeyCommand)
{
case 1:
Key1Event();
break;
case 2:
Key2Event();
break;
case 3:
Key3Event();
break;
case 4:
Key4Event();
break;
case 5:
Key5Event();
break;
case 6:
Key6Event();
break;
case 7:
Key7Event();
break;
case 8:
Key8Event();
break;
case 9:
Key9Event();
break;
default:
ASSERT(false);
}
}
KeyFlags = 0;
}
else
{
if(KeyFlags == 0x1)
{
switch(pressed_key)
{
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
KeyCommand = pressed_key;
KeyFlags = 0x3;
break;
default:
KeyCommand = 0;
KeyFlags = 0;
}
}
else
KeyFlags = 0;
}
#ifdef BT_Loopback_Test
if(pressed_key == 12) // #
KeyFlags1 = 0x11;
else if(pressed_key == 10) // *
{
if(KeyFlags1 == 0x31)
{
switch(KeyCommand1)
{
case 1:
Key11Event();
break;
case 2:
Key12Event();
break;
case 3:
Key13Event();
break;
case 4:
Key14Event();
break;
case 5:
Key15Event();
break;
case 6:
Key16Event();
break;
case 7:
Key17Event();
break;
case 8:
Key18Event();
break;
case 9:
Key19Event();
break;
default:
ASSERT(false);
}
}
KeyFlags1 = 0;
}
else
{
if(KeyFlags1 == 0x11)
{
switch(pressed_key)
{
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
KeyCommand1 = pressed_key;
KeyFlags1 = 0x31;
break;
default:
KeyCommand1 = 0;
KeyFlags1 = 0;
}
}
else
KeyFlags1 = 0;
}
//===================================================================
if(pressed_key == 10) // *
KeyFlags2 = 0x21;
else if(pressed_key == 11) // 0
{
if(KeyFlags2 == 0x32)
{
switch(KeyCommand2)
{
case 1:
Key21Event();
break;
case 2:
Key22Event();
break;
case 3:
Key23Event();
break;
case 4:
Key24Event();
break;
case 5:
Key25Event();
break;
case 6:
Key26Event();
break;
case 7:
Key27Event();
break;
case 8:
Key28Event();
break;
case 9:
Key29Event();
break;
default:
ASSERT(false);
}
}
KeyFlags2 = 0;
}
else
{
if(KeyFlags2 == 0x21)
{
switch(pressed_key)
{
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
KeyCommand2 = pressed_key;
KeyFlags2 = 0x32;
break;
default:
KeyCommand2 = 0;
KeyFlags = 0;
}
}
else
KeyFlags2 = 0;
}
//===================================================================
if(pressed_key == 12) // #
KeyFlags3 = 0x31;
else if(pressed_key == 11) // 0
{
if(KeyFlags3 == 0x33)
{
switch(KeyCommand3)
{
case 1:
Key31Event();
break;
case 2:
Key32Event();
break;
case 3:
Key33Event();
break;
case 4:
Key34Event();
break;
case 5:
Key35Event();
break;
case 6:
Key36Event();
break;
case 7:
Key37Event();
break;
case 8:
Key38Event();
break;
case 9:
Key39Event();
break;
default:
ASSERT(false);
}
}
KeyFlags3 = 0;
}
else
{
if(KeyFlags3 == 0x31)
{
switch(pressed_key)
{
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
KeyCommand3 = pressed_key;
KeyFlags3 = 0x33;
break;
default:
KeyCommand3 = 0;
KeyFlags3 = 0;
}
}
else
KeyFlags3 = 0;
}
return;
#endif // #ifdef BT_Loopback_Test
#endif//#if defined(KEYTONE_DEBUG)
if( keytone.lock > 0 || keytone.volume1 == 0 )
return;
if( mediaKeytoneForbidden() || AM_IsDAIMode() )
return;
if( L1Audio_CheckFlag( keytone.aud_id ) || L1Audio_CheckFlag( tone.aud_id ) )
return;
if (keytone.state != TONE_STATE_NONE)
return;
L1Audio_SetFlag( keytone.aud_id );
#if defined(__GAIN_TABLE_SUPPORT__)
AFE_SetOutputGainControl(L1SP_KEYTONE,keytone.gain);
#else
AFE_SetOutputVolume( L1SP_KEYTONE, keytone.volume1, keytone.digital_gain_index );
#endif
keytone.fc_aud_id = L1Audio_FC_HookHandler( (void *)0, ktMsgHandler, 0, (FC_MEDIA_FORMAT_QTMF<<8)|MEDIA_OPERATE_PLAYBACK );
keytone.state = TONE_STATE_IDLE;
keytone.info->freq1 = freq1;
keytone.info->freq2 = freq2;
keytone.info->freq3 = 0;
keytone.info->freq4 = 0;
if (duration == 0) {
keytone.info->msDur = -1;
} else {
keytone.info->msDur = duration;
}
AM_KeyToneOn();
kal_sleep_task(1);
keytone.state = TONE_STATE_INIT;
keytone.isReentrance = false;
keytone.seqNum++;
/*workaround for SPEECH DSP MAIN/AUX Mode Task in FCORE*/
#ifdef BGSND_ENABLE
if (keytone.sndOffHandler != NULL)
keytone.sndOffHandler( keytone.sndHdl );
#endif
/*workaround for SPEECH DSP MAIN/AUX Mode Task in FCORE*/
L1Audio_FC_TonePlaybackOn(keytone.fc_aud_id, keytone.info);
//AM_KeyToneOn();
}
/*****************************************************************************
* FUNCTION
* gmiWriteToDSP
* DESCRIPTION
* This function is the call-back function of GPT for playing notes.
*****************************************************************************/
static void gmiWriteToDSP( void *data )
{
GMI_Note *note;
uint16 I;
uint32 curtime;
uint32 note_time;
uint32 next_time;
uint16 rb_count_org;
rb_count_org = RB_Count();
curtime = (uint32)(QTMF_COUNTER - gmi.start_time);
next_time = curtime;
while( !RB_Empty() ) {
note = RB_Peek();
note_time = gmi.note_time + note->delta_time;
if( note_time > next_time ) {
next_time = note_time;
}
else if( note_time < curtime ) {
RB_Consume();
gmi.note_time = note_time;
continue;
}
/* search for the first available DSP tone */
for( I = 0; I < MAX_DPRAM_BUFFER; I++ ) {
#if defined(MT6205)
if( QTMF_DURA(I) == 0 && gmi.dsp_time[I] <= note_time ) {
#else
if( QTMF_DURA(I) == 0 ) {
#endif
QTMF_FREQ(I) = Pitch2Frequency[ note->pitch ];
QTMF_AMP(I) = (uint16)note->amplitude;
QTMF_DURA(I) = note->duration << 4;
/* QTMF_DURA(I) = (note->duration << 4) + ((note->timbre >> 3) & 0x0F );
*/
QTMF_TIME(I) = (uint16)note_time + gmi.start_time;
gmi.dsp_time[I] = note_time + note->duration;
if( gmi.end_time < gmi.dsp_time[I] )
gmi.end_time = gmi.dsp_time[I];
RB_Consume();
gmi.note_time = note_time;
break;
}
}
if( I == MAX_DPRAM_BUFFER )
break;
}
switch( gmi.state ) {
case GMI_STATE_INIT:
QTMF_CONTROL = 3;
gmi.state = GMI_STATE_PLAY;
break;
case GMI_STATE_PLAY:
if( rb_count_org >= GMI_RB_SIZE/2 && RB_Count() < GMI_RB_SIZE/2 )
L1Audio_SetEvent( gmi.aud_id, (void*)GMI_NOTE_REQUEST );
if( gmi.eof_flag )
gmi.state = GMI_STATE_DATA_COMPLETE;
break;
case GMI_STATE_DATA_COMPLETE:
if( RB_Empty() ) {
GPTI_StartItem( gmi.gpt, (gmi.end_time - curtime + 5) * 2, gmiTerminate, 0 );
return;
}
break;
}
if( next_time > curtime )
next_time = next_time - curtime;
else
next_time = 1;
GPTI_StartItem( gmi.gpt, next_time, gmiWriteToDSP, 0 );
}
/*****************************************************************************
* FUNCTION
* GMI_Play
* DESCRIPTION
* This function is used to start melody playing.
*
* PARAMETERS
* gmi_handler - a call back function used to be notified an event that
* the end of a song is reached.
*****************************************************************************/
void GMI_Play( void (*gmi_handler)( GMI_Event event ) )
{
int16 I;
if( L1Audio_CheckFlag( gmi.aud_id ) )
return;
if( gmi_handler == 0 )
return;
if( gmi.state != GMI_STATE_IDLE )
return;
L1Audio_SetFlag( gmi.aud_id );
GPTI_StopItem( gmi.gpt );
for( I = 0; I < MAX_DPRAM_BUFFER; I++ ) {
gmi.dsp_time[I] = 0;
QTMF_DURA(I) = 0;
}
gmi.rb_head = 0;
gmi.rb_tail = 0;
gmi.mmi_time = 0;
gmi.start_time = QTMF_COUNTER;
gmi.end_time = 0;
gmi.state = GMI_STATE_INIT;
gmi.note_time = 0;
gmi.eof_flag = false;
gmi.gmi_handler = gmi_handler;
gmi.gmi_handler( GMI_NOTE_REQUEST );
AM_MelodyOn();
gmiWriteToDSP( 0 );
} /* end of gmiPlay */
