ref: 7cd466427902c631c810aeffd7879bb183542b07
dir: /silk/silk_dec_API.c/
/***********************************************************************
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are permitted provided that the following conditions are met:
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- Redistributions in binary form must reproduce the above copyright
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BY THIS LICENSE. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
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***********************************************************************/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "silk_API.h"
#include "silk_main.h"
/************************/
/* Decoder Super Struct */
/************************/
typedef struct {
silk_decoder_state channel_state[ DECODER_NUM_CHANNELS ];
stereo_dec_state sStereo;
opus_int nChannelsAPI;
opus_int nChannelsInternal;
} silk_decoder;
/*********************/
/* Decoder functions */
/*********************/
opus_int silk_Get_Decoder_Size( opus_int32 *decSizeBytes )
{
opus_int ret = SILK_NO_ERROR;
*decSizeBytes = sizeof( silk_decoder );
return ret;
}
/* Reset decoder state */
opus_int silk_InitDecoder(
void* decState /* I/O: State */
)
{
opus_int n, ret = SILK_NO_ERROR;
silk_decoder_state *channel_state = ((silk_decoder *)decState)->channel_state;
for( n = 0; n < DECODER_NUM_CHANNELS; n++ ) {
ret = silk_init_decoder( &channel_state[ n ] );
}
return ret;
}
/* Decode a frame */
opus_int silk_Decode(
void* decState, /* I/O: State */
silk_DecControlStruct* decControl, /* I/O: Control Structure */
opus_int lostFlag, /* I: 0: no loss, 1 loss, 2 decode FEC */
opus_int newPacketFlag, /* I: Indicates first decoder call for this packet */
ec_dec *psRangeDec, /* I/O Compressor data structure */
opus_int16 *samplesOut, /* O: Decoded output speech vector */
opus_int32 *nSamplesOut /* O: Number of samples decoded */
)
{
opus_int i, n, prev_fs_kHz, decode_only_middle = 0, ret = SILK_NO_ERROR;
opus_int32 nSamplesOutDec, LBRR_symbol;
opus_int16 samplesOut1_tmp[ 2 ][ MAX_FS_KHZ * MAX_FRAME_LENGTH_MS + 2 ];
opus_int16 samplesOut2_tmp[ MAX_API_FS_KHZ * MAX_FRAME_LENGTH_MS ];
opus_int MS_pred_Q13[ 2 ] = { 0 };
opus_int16 *resample_out_ptr;
silk_decoder *psDec = ( silk_decoder * )decState;
silk_decoder_state *channel_state = psDec->channel_state;
/**********************************/
/* Test if first frame in payload */
/**********************************/
if( newPacketFlag ) {
for( n = 0; n < decControl->nChannelsInternal; n++ ) {
channel_state[ n ].nFramesDecoded = 0; /* Used to count frames in packet */
}
}
/* Save previous sample frequency */
prev_fs_kHz = channel_state[ 0 ].fs_kHz;
/* If Mono -> Stereo transition in bitstream: init state of second channel */
if( decControl->nChannelsInternal > psDec->nChannelsInternal ) {
ret += silk_init_decoder( &channel_state[ 1 ] );
if( psDec->nChannelsAPI == 2 ) {
SKP_memcpy( &channel_state[ 1 ].resampler_state, &channel_state[ 0 ].resampler_state, sizeof( silk_resampler_state_struct ) );
}
}
for( n = 0; n < decControl->nChannelsInternal; n++ ) {
if( channel_state[ n ].nFramesDecoded == 0 ) {
opus_int fs_kHz_dec;
if( decControl->payloadSize_ms == 0 ) {
/* Assuming packet loss, use 10 ms */
channel_state[ n ].nFramesPerPacket = 1;
channel_state[ n ].nb_subfr = 2;
} else if( decControl->payloadSize_ms == 10 ) {
channel_state[ n ].nFramesPerPacket = 1;
channel_state[ n ].nb_subfr = 2;
} else if( decControl->payloadSize_ms == 20 ) {
channel_state[ n ].nFramesPerPacket = 1;
channel_state[ n ].nb_subfr = 4;
} else if( decControl->payloadSize_ms == 40 ) {
channel_state[ n ].nFramesPerPacket = 2;
channel_state[ n ].nb_subfr = 4;
} else if( decControl->payloadSize_ms == 60 ) {
channel_state[ n ].nFramesPerPacket = 3;
channel_state[ n ].nb_subfr = 4;
} else {
SKP_assert( 0 );
return SILK_DEC_INVALID_FRAME_SIZE;
}
fs_kHz_dec = ( decControl->internalSampleRate >> 10 ) + 1;
if( fs_kHz_dec != 8 && fs_kHz_dec != 12 && fs_kHz_dec != 16 ) {
SKP_assert( 0 );
return SILK_DEC_INVALID_SAMPLING_FREQUENCY;
}
silk_decoder_set_fs( &channel_state[ n ], fs_kHz_dec );
}
}
/* Initialize resampler when switching internal or external sampling frequency */
if( prev_fs_kHz != channel_state[ 0 ].fs_kHz || channel_state[ 0 ].prev_API_sampleRate != decControl->API_sampleRate ) {
ret = silk_resampler_init( &channel_state[ 0 ].resampler_state, SKP_SMULBB( channel_state[ 0 ].fs_kHz, 1000 ), decControl->API_sampleRate );
if( decControl->nChannelsAPI == 2 && decControl->nChannelsInternal == 2 ) {
SKP_memcpy( &channel_state[ 1 ].resampler_state, &channel_state[ 0 ].resampler_state, sizeof( silk_resampler_state_struct ) );
}
}
channel_state[ 0 ].prev_API_sampleRate = decControl->API_sampleRate;
if( decControl->nChannelsAPI == 2 && decControl->nChannelsInternal == 2 && ( psDec->nChannelsAPI == 1 || psDec->nChannelsInternal == 1 ) ) {
SKP_memset( psDec->sStereo.pred_prev_Q13, 0, sizeof( psDec->sStereo.pred_prev_Q13 ) );
SKP_memset( psDec->sStereo.sSide, 0, sizeof( psDec->sStereo.sSide ) );
}
psDec->nChannelsAPI = decControl->nChannelsAPI;
psDec->nChannelsInternal = decControl->nChannelsInternal;
if( decControl->API_sampleRate > MAX_API_FS_KHZ * 1000 || decControl->API_sampleRate < 8000 ) {
ret = SILK_DEC_INVALID_SAMPLING_FREQUENCY;
return( ret );
}
if( lostFlag != FLAG_PACKET_LOST && channel_state[ 0 ].nFramesDecoded == 0 ) {
/* First decoder call for this payload */
/* Decode VAD flags and LBRR flag */
for( n = 0; n < decControl->nChannelsInternal; n++ ) {
for( i = 0; i < channel_state[ n ].nFramesPerPacket; i++ ) {
channel_state[ n ].VAD_flags[ i ] = ec_dec_bit_logp(psRangeDec, 1);
}
channel_state[ n ].LBRR_flag = ec_dec_bit_logp(psRangeDec, 1);
}
/* Decode LBRR flags */
for( n = 0; n < decControl->nChannelsInternal; n++ ) {
SKP_memset( channel_state[ n ].LBRR_flags, 0, sizeof( channel_state[ n ].LBRR_flags ) );
if( channel_state[ n ].LBRR_flag ) {
if( channel_state[ n ].nFramesPerPacket == 1 ) {
channel_state[ n ].LBRR_flags[ 0 ] = 1;
} else {
LBRR_symbol = ec_dec_icdf( psRangeDec, silk_LBRR_flags_iCDF_ptr[ channel_state[ n ].nFramesPerPacket - 2 ], 8 ) + 1;
for( i = 0; i < channel_state[ n ].nFramesPerPacket; i++ ) {
channel_state[ n ].LBRR_flags[ i ] = SKP_RSHIFT( LBRR_symbol, i ) & 1;
}
}
}
}
if( lostFlag == FLAG_DECODE_NORMAL ) {
/* Regular decoding: skip all LBRR data */
for( i = 0; i < channel_state[ 0 ].nFramesPerPacket; i++ ) {
for( n = 0; n < decControl->nChannelsInternal; n++ ) {
if( channel_state[ n ].LBRR_flags[ i ] ) {
opus_int pulses[ MAX_FRAME_LENGTH ];
if( decControl->nChannelsInternal == 2 && n == 0 ) {
silk_stereo_decode_pred( psRangeDec, &decode_only_middle, MS_pred_Q13 );
}
silk_decode_indices( &channel_state[ n ], psRangeDec, i, 1 );
silk_decode_pulses( psRangeDec, pulses, channel_state[ n ].indices.signalType,
channel_state[ n ].indices.quantOffsetType, channel_state[ n ].frame_length );
}
}
}
}
}
/* Get MS predictor index */
if( decControl->nChannelsInternal == 2 ) {
if( lostFlag == FLAG_DECODE_NORMAL ||
( lostFlag == FLAG_DECODE_LBRR && channel_state[ 0 ].LBRR_flags[ channel_state[ 0 ].nFramesDecoded ] == 1 ) )
{
silk_stereo_decode_pred( psRangeDec, &decode_only_middle, MS_pred_Q13 );
} else {
for( n = 0; n < 2; n++ ) {
MS_pred_Q13[n] = psDec->sStereo.pred_prev_Q13[n];
}
}
}
/* Call decoder for one frame */
for( n = 0; n < decControl->nChannelsInternal; n++ ) {
if( n == 0 || decode_only_middle == 0 ) {
ret += silk_decode_frame( &channel_state[ n ], psRangeDec, &samplesOut1_tmp[ n ][ 2 ], &nSamplesOutDec, lostFlag );
} else {
SKP_memset( &samplesOut1_tmp[ n ][ 2 ], 0, nSamplesOutDec * sizeof( opus_int16 ) );
}
}
if( decControl->nChannelsAPI == 2 && decControl->nChannelsInternal == 2 ) {
/* Convert Mid/Side to Left/Right */
silk_stereo_MS_to_LR( &psDec->sStereo, samplesOut1_tmp[ 0 ], samplesOut1_tmp[ 1 ], MS_pred_Q13, channel_state[ 0 ].fs_kHz, nSamplesOutDec );
} else {
/* Buffering */
SKP_memcpy( samplesOut1_tmp[ 0 ], psDec->sStereo.sMid, 2 * sizeof( opus_int16 ) );
SKP_memcpy( psDec->sStereo.sMid, &samplesOut1_tmp[ 0 ][ nSamplesOutDec ], 2 * sizeof( opus_int16 ) );
}
/* Number of output samples */
*nSamplesOut = SKP_DIV32( nSamplesOutDec * decControl->API_sampleRate, SKP_SMULBB( channel_state[ 0 ].fs_kHz, 1000 ) );
/* Set up pointers to temp buffers */
if( decControl->nChannelsAPI == 2 ) {
resample_out_ptr = samplesOut2_tmp;
} else {
resample_out_ptr = samplesOut;
}
for( n = 0; n < SKP_min( decControl->nChannelsAPI, decControl->nChannelsInternal ); n++ ) {
/* Resample decoded signal to API_sampleRate */
ret += silk_resampler( &channel_state[ n ].resampler_state, resample_out_ptr, &samplesOut1_tmp[ n ][ 1 ], nSamplesOutDec );
/* Interleave if stereo output and stereo stream */
if( decControl->nChannelsAPI == 2 && decControl->nChannelsInternal == 2 ) {
for( i = 0; i < *nSamplesOut; i++ ) {
samplesOut[ n + 2 * i ] = resample_out_ptr[ i ];
}
}
}
/* Create two channel output from mono stream */
if( decControl->nChannelsAPI == 2 && decControl->nChannelsInternal == 1 ) {
for( i = 0; i < *nSamplesOut; i++ ) {
samplesOut[ 0 + 2 * i ] = samplesOut[ 1 + 2 * i ] = resample_out_ptr[ i ];
}
}
return ret;
}
/* Getting table of contents for a packet */
opus_int silk_get_TOC(
const opus_uint8 *payload, /* I Payload data */
const opus_int nBytesIn, /* I: Number of input bytes */
const opus_int nFramesPerPayload, /* I: Number of SILK frames per payload */
silk_TOC_struct *Silk_TOC /* O: Type of content */
)
{
opus_int i, flags, ret = SILK_NO_ERROR;
if( nBytesIn < 1 ) {
return -1;
}
if( nFramesPerPayload < 0 || nFramesPerPayload > 3 ) {
return -1;
}
SKP_memset( Silk_TOC, 0, sizeof( Silk_TOC ) );
/* For stereo, extract the flags for the mid channel */
flags = SKP_RSHIFT( payload[ 0 ], 7 - nFramesPerPayload ) & ( SKP_LSHIFT( 1, nFramesPerPayload + 1 ) - 1 );
Silk_TOC->inbandFECFlag = flags & 1;
for( i = nFramesPerPayload - 1; i >= 0 ; i-- ) {
flags = SKP_RSHIFT( flags, 1 );
Silk_TOC->VADFlags[ i ] = flags & 1;
Silk_TOC->VADFlag |= flags & 1;
}
return ret;
}