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/***********************************************************************
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* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
# ifdef HAVE_CONFIG_H
# include "config.h"
# endif
# include "main_FIX.h"
# include "stack_alloc.h"
# include "tuning_parameters.h"
/* Compute gain to make warped filter coefficients have a zero mean log frequency response on a */
/* non-warped frequency scale. (So that it can be implemented with a minimum-phase monic filter.) */
/* Note: A monic filter is one with the first coefficient equal to 1.0. In Silk we omit the first */
/* coefficient in an array of coefficients, for monic filters. */
static OPUS_INLINE opus_int32 warped_gain ( /* gain in Q16*/
const opus_int32 * coefs_Q24 ,
opus_int lambda_Q16 ,
opus_int order
) {
opus_int i ;
opus_int32 gain_Q24 ;
lambda_Q16 = - lambda_Q16 ;
gain_Q24 = coefs_Q24 [ order - 1 ] ;
for ( i = order - 2 ; i > = 0 ; i - - ) {
gain_Q24 = silk_SMLAWB ( coefs_Q24 [ i ] , gain_Q24 , lambda_Q16 ) ;
}
gain_Q24 = silk_SMLAWB ( SILK_FIX_CONST ( 1.0 , 24 ) , gain_Q24 , - lambda_Q16 ) ;
return silk_INVERSE32_varQ ( gain_Q24 , 40 ) ;
}
/* Convert warped filter coefficients to monic pseudo-warped coefficients and limit maximum */
/* amplitude of monic warped coefficients by using bandwidth expansion on the true coefficients */
static OPUS_INLINE void limit_warped_coefs (
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opus_int32 * coefs_Q24 ,
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opus_int lambda_Q16 ,
opus_int32 limit_Q24 ,
opus_int order
) {
opus_int i , iter , ind = 0 ;
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opus_int32 tmp , maxabs_Q24 , chirp_Q16 , gain_Q16 ;
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opus_int32 nom_Q16 , den_Q24 ;
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opus_int32 limit_Q20 , maxabs_Q20 ;
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/* Convert to monic coefficients */
lambda_Q16 = - lambda_Q16 ;
for ( i = order - 1 ; i > 0 ; i - - ) {
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coefs_Q24 [ i - 1 ] = silk_SMLAWB ( coefs_Q24 [ i - 1 ] , coefs_Q24 [ i ] , lambda_Q16 ) ;
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}
lambda_Q16 = - lambda_Q16 ;
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nom_Q16 = silk_SMLAWB ( SILK_FIX_CONST ( 1.0 , 16 ) , - ( opus_int32 ) lambda_Q16 , lambda_Q16 ) ;
den_Q24 = silk_SMLAWB ( SILK_FIX_CONST ( 1.0 , 24 ) , coefs_Q24 [ 0 ] , lambda_Q16 ) ;
gain_Q16 = silk_DIV32_varQ ( nom_Q16 , den_Q24 , 24 ) ;
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for ( i = 0 ; i < order ; i + + ) {
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coefs_Q24 [ i ] = silk_SMULWW ( gain_Q16 , coefs_Q24 [ i ] ) ;
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}
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limit_Q20 = silk_RSHIFT ( limit_Q24 , 4 ) ;
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for ( iter = 0 ; iter < 10 ; iter + + ) {
/* Find maximum absolute value */
maxabs_Q24 = - 1 ;
for ( i = 0 ; i < order ; i + + ) {
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tmp = silk_abs_int32 ( coefs_Q24 [ i ] ) ;
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if ( tmp > maxabs_Q24 ) {
maxabs_Q24 = tmp ;
ind = i ;
}
}
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/* Use Q20 to avoid any overflow when multiplying by (ind + 1) later. */
maxabs_Q20 = silk_RSHIFT ( maxabs_Q24 , 4 ) ;
if ( maxabs_Q20 < = limit_Q20 ) {
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/* Coefficients are within range - done */
return ;
}
/* Convert back to true warped coefficients */
for ( i = 1 ; i < order ; i + + ) {
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coefs_Q24 [ i - 1 ] = silk_SMLAWB ( coefs_Q24 [ i - 1 ] , coefs_Q24 [ i ] , lambda_Q16 ) ;
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}
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gain_Q16 = silk_INVERSE32_varQ ( gain_Q16 , 32 ) ;
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for ( i = 0 ; i < order ; i + + ) {
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coefs_Q24 [ i ] = silk_SMULWW ( gain_Q16 , coefs_Q24 [ i ] ) ;
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}
/* Apply bandwidth expansion */
chirp_Q16 = SILK_FIX_CONST ( 0.99 , 16 ) - silk_DIV32_varQ (
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silk_SMULWB ( maxabs_Q20 - limit_Q20 , silk_SMLABB ( SILK_FIX_CONST ( 0.8 , 10 ) , SILK_FIX_CONST ( 0.1 , 10 ) , iter ) ) ,
silk_MUL ( maxabs_Q20 , ind + 1 ) , 22 ) ;
silk_bwexpander_32 ( coefs_Q24 , order , chirp_Q16 ) ;
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/* Convert to monic warped coefficients */
lambda_Q16 = - lambda_Q16 ;
for ( i = order - 1 ; i > 0 ; i - - ) {
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coefs_Q24 [ i - 1 ] = silk_SMLAWB ( coefs_Q24 [ i - 1 ] , coefs_Q24 [ i ] , lambda_Q16 ) ;
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}
lambda_Q16 = - lambda_Q16 ;
nom_Q16 = silk_SMLAWB ( SILK_FIX_CONST ( 1.0 , 16 ) , - ( opus_int32 ) lambda_Q16 , lambda_Q16 ) ;
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den_Q24 = silk_SMLAWB ( SILK_FIX_CONST ( 1.0 , 24 ) , coefs_Q24 [ 0 ] , lambda_Q16 ) ;
gain_Q16 = silk_DIV32_varQ ( nom_Q16 , den_Q24 , 24 ) ;
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for ( i = 0 ; i < order ; i + + ) {
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coefs_Q24 [ i ] = silk_SMULWW ( gain_Q16 , coefs_Q24 [ i ] ) ;
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}
}
silk_assert ( 0 ) ;
}
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/* Disable MIPS version until it's updated. */
#if 0 && defined(MIPSr1_ASM)
# include "mips/noise_shape_analysis_FIX_mipsr1.h"
# endif
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/**************************************************************/
/* Compute noise shaping coefficients and initial gain values */
/**************************************************************/
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# ifndef OVERRIDE_silk_noise_shape_analysis_FIX
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void silk_noise_shape_analysis_FIX (
silk_encoder_state_FIX * psEnc , /* I/O Encoder state FIX */
silk_encoder_control_FIX * psEncCtrl , /* I/O Encoder control FIX */
const opus_int16 * pitch_res , /* I LPC residual from pitch analysis */
const opus_int16 * x , /* I Input signal [ frame_length + la_shape ] */
int arch /* I Run-time architecture */
)
{
silk_shape_state_FIX * psShapeSt = & psEnc - > sShape ;
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opus_int k , i , nSamples , nSegs , Qnrg , b_Q14 , warping_Q16 , scale = 0 ;
opus_int32 SNR_adj_dB_Q7 , HarmShapeGain_Q16 , Tilt_Q16 , tmp32 ;
opus_int32 nrg , log_energy_Q7 , log_energy_prev_Q7 , energy_variation_Q7 ;
opus_int32 BWExp_Q16 , gain_mult_Q16 , gain_add_Q16 , strength_Q16 , b_Q8 ;
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opus_int32 auto_corr [ MAX_SHAPE_LPC_ORDER + 1 ] ;
opus_int32 refl_coef_Q16 [ MAX_SHAPE_LPC_ORDER ] ;
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opus_int32 AR_Q24 [ MAX_SHAPE_LPC_ORDER ] ;
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VARDECL ( opus_int16 , x_windowed ) ;
const opus_int16 * x_ptr , * pitch_res_ptr ;
SAVE_STACK ;
/* Point to start of first LPC analysis block */
x_ptr = x - psEnc - > sCmn . la_shape ;
/****************/
/* GAIN CONTROL */
/****************/
SNR_adj_dB_Q7 = psEnc - > sCmn . SNR_dB_Q7 ;
/* Input quality is the average of the quality in the lowest two VAD bands */
psEncCtrl - > input_quality_Q14 = ( opus_int ) silk_RSHIFT ( ( opus_int32 ) psEnc - > sCmn . input_quality_bands_Q15 [ 0 ]
+ psEnc - > sCmn . input_quality_bands_Q15 [ 1 ] , 2 ) ;
/* Coding quality level, between 0.0_Q0 and 1.0_Q0, but in Q14 */
psEncCtrl - > coding_quality_Q14 = silk_RSHIFT ( silk_sigm_Q15 ( silk_RSHIFT_ROUND ( SNR_adj_dB_Q7 -
SILK_FIX_CONST ( 20.0 , 7 ) , 4 ) ) , 1 ) ;
/* Reduce coding SNR during low speech activity */
if ( psEnc - > sCmn . useCBR = = 0 ) {
b_Q8 = SILK_FIX_CONST ( 1.0 , 8 ) - psEnc - > sCmn . speech_activity_Q8 ;
b_Q8 = silk_SMULWB ( silk_LSHIFT ( b_Q8 , 8 ) , b_Q8 ) ;
SNR_adj_dB_Q7 = silk_SMLAWB ( SNR_adj_dB_Q7 ,
silk_SMULBB ( SILK_FIX_CONST ( - BG_SNR_DECR_dB , 7 ) > > ( 4 + 1 ) , b_Q8 ) , /* Q11*/
silk_SMULWB ( SILK_FIX_CONST ( 1.0 , 14 ) + psEncCtrl - > input_quality_Q14 , psEncCtrl - > coding_quality_Q14 ) ) ; /* Q12*/
}
if ( psEnc - > sCmn . indices . signalType = = TYPE_VOICED ) {
/* Reduce gains for periodic signals */
SNR_adj_dB_Q7 = silk_SMLAWB ( SNR_adj_dB_Q7 , SILK_FIX_CONST ( HARM_SNR_INCR_dB , 8 ) , psEnc - > LTPCorr_Q15 ) ;
} else {
/* For unvoiced signals and low-quality input, adjust the quality slower than SNR_dB setting */
SNR_adj_dB_Q7 = silk_SMLAWB ( SNR_adj_dB_Q7 ,
silk_SMLAWB ( SILK_FIX_CONST ( 6.0 , 9 ) , - SILK_FIX_CONST ( 0.4 , 18 ) , psEnc - > sCmn . SNR_dB_Q7 ) ,
SILK_FIX_CONST ( 1.0 , 14 ) - psEncCtrl - > input_quality_Q14 ) ;
}
/*************************/
/* SPARSENESS PROCESSING */
/*************************/
/* Set quantizer offset */
if ( psEnc - > sCmn . indices . signalType = = TYPE_VOICED ) {
/* Initially set to 0; may be overruled in process_gains(..) */
psEnc - > sCmn . indices . quantOffsetType = 0 ;
} else {
/* Sparseness measure, based on relative fluctuations of energy per 2 milliseconds */
nSamples = silk_LSHIFT ( psEnc - > sCmn . fs_kHz , 1 ) ;
energy_variation_Q7 = 0 ;
log_energy_prev_Q7 = 0 ;
pitch_res_ptr = pitch_res ;
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nSegs = silk_SMULBB ( SUB_FRAME_LENGTH_MS , psEnc - > sCmn . nb_subfr ) / 2 ;
for ( k = 0 ; k < nSegs ; k + + ) {
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silk_sum_sqr_shift ( & nrg , & scale , pitch_res_ptr , nSamples ) ;
nrg + = silk_RSHIFT ( nSamples , scale ) ; /* Q(-scale)*/
log_energy_Q7 = silk_lin2log ( nrg ) ;
if ( k > 0 ) {
energy_variation_Q7 + = silk_abs ( log_energy_Q7 - log_energy_prev_Q7 ) ;
}
log_energy_prev_Q7 = log_energy_Q7 ;
pitch_res_ptr + = nSamples ;
}
/* Set quantization offset depending on sparseness measure */
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if ( energy_variation_Q7 > SILK_FIX_CONST ( ENERGY_VARIATION_THRESHOLD_QNT_OFFSET , 7 ) * ( nSegs - 1 ) ) {
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psEnc - > sCmn . indices . quantOffsetType = 0 ;
} else {
psEnc - > sCmn . indices . quantOffsetType = 1 ;
}
}
/*******************************/
/* Control bandwidth expansion */
/*******************************/
/* More BWE for signals with high prediction gain */
strength_Q16 = silk_SMULWB ( psEncCtrl - > predGain_Q16 , SILK_FIX_CONST ( FIND_PITCH_WHITE_NOISE_FRACTION , 16 ) ) ;
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BWExp_Q16 = silk_DIV32_varQ ( SILK_FIX_CONST ( BANDWIDTH_EXPANSION , 16 ) ,
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silk_SMLAWW ( SILK_FIX_CONST ( 1.0 , 16 ) , strength_Q16 , strength_Q16 ) , 16 ) ;
if ( psEnc - > sCmn . warping_Q16 > 0 ) {
/* Slightly more warping in analysis will move quantization noise up in frequency, where it's better masked */
warping_Q16 = silk_SMLAWB ( psEnc - > sCmn . warping_Q16 , ( opus_int32 ) psEncCtrl - > coding_quality_Q14 , SILK_FIX_CONST ( 0.01 , 18 ) ) ;
} else {
warping_Q16 = 0 ;
}
/********************************************/
/* Compute noise shaping AR coefs and gains */
/********************************************/
ALLOC ( x_windowed , psEnc - > sCmn . shapeWinLength , opus_int16 ) ;
for ( k = 0 ; k < psEnc - > sCmn . nb_subfr ; k + + ) {
/* Apply window: sine slope followed by flat part followed by cosine slope */
opus_int shift , slope_part , flat_part ;
flat_part = psEnc - > sCmn . fs_kHz * 3 ;
slope_part = silk_RSHIFT ( psEnc - > sCmn . shapeWinLength - flat_part , 1 ) ;
silk_apply_sine_window ( x_windowed , x_ptr , 1 , slope_part ) ;
shift = slope_part ;
silk_memcpy ( x_windowed + shift , x_ptr + shift , flat_part * sizeof ( opus_int16 ) ) ;
shift + = flat_part ;
silk_apply_sine_window ( x_windowed + shift , x_ptr + shift , 2 , slope_part ) ;
/* Update pointer: next LPC analysis block */
x_ptr + = psEnc - > sCmn . subfr_length ;
if ( psEnc - > sCmn . warping_Q16 > 0 ) {
/* Calculate warped auto correlation */
silk_warped_autocorrelation_FIX ( auto_corr , & scale , x_windowed , warping_Q16 , psEnc - > sCmn . shapeWinLength , psEnc - > sCmn . shapingLPCOrder ) ;
} else {
/* Calculate regular auto correlation */
silk_autocorr ( auto_corr , & scale , x_windowed , psEnc - > sCmn . shapeWinLength , psEnc - > sCmn . shapingLPCOrder + 1 , arch ) ;
}
/* Add white noise, as a fraction of energy */
auto_corr [ 0 ] = silk_ADD32 ( auto_corr [ 0 ] , silk_max_32 ( silk_SMULWB ( silk_RSHIFT ( auto_corr [ 0 ] , 4 ) ,
SILK_FIX_CONST ( SHAPE_WHITE_NOISE_FRACTION , 20 ) ) , 1 ) ) ;
/* Calculate the reflection coefficients using schur */
nrg = silk_schur64 ( refl_coef_Q16 , auto_corr , psEnc - > sCmn . shapingLPCOrder ) ;
silk_assert ( nrg > = 0 ) ;
/* Convert reflection coefficients to prediction coefficients */
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silk_k2a_Q16 ( AR_Q24 , refl_coef_Q16 , psEnc - > sCmn . shapingLPCOrder ) ;
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Qnrg = - scale ; /* range: -12...30*/
silk_assert ( Qnrg > = - 12 ) ;
silk_assert ( Qnrg < = 30 ) ;
/* Make sure that Qnrg is an even number */
if ( Qnrg & 1 ) {
Qnrg - = 1 ;
nrg > > = 1 ;
}
tmp32 = silk_SQRT_APPROX ( nrg ) ;
Qnrg > > = 1 ; /* range: -6...15*/
psEncCtrl - > Gains_Q16 [ k ] = silk_LSHIFT_SAT32 ( tmp32 , 16 - Qnrg ) ;
if ( psEnc - > sCmn . warping_Q16 > 0 ) {
/* Adjust gain for warping */
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gain_mult_Q16 = warped_gain ( AR_Q24 , warping_Q16 , psEnc - > sCmn . shapingLPCOrder ) ;
silk_assert ( psEncCtrl - > Gains_Q16 [ k ] > 0 ) ;
if ( psEncCtrl - > Gains_Q16 [ k ] < SILK_FIX_CONST ( 0.25 , 16 ) ) {
psEncCtrl - > Gains_Q16 [ k ] = silk_SMULWW ( psEncCtrl - > Gains_Q16 [ k ] , gain_mult_Q16 ) ;
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} else {
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psEncCtrl - > Gains_Q16 [ k ] = silk_SMULWW ( silk_RSHIFT_ROUND ( psEncCtrl - > Gains_Q16 [ k ] , 1 ) , gain_mult_Q16 ) ;
if ( psEncCtrl - > Gains_Q16 [ k ] > = ( silk_int32_MAX > > 1 ) ) {
psEncCtrl - > Gains_Q16 [ k ] = silk_int32_MAX ;
} else {
psEncCtrl - > Gains_Q16 [ k ] = silk_LSHIFT32 ( psEncCtrl - > Gains_Q16 [ k ] , 1 ) ;
}
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}
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silk_assert ( psEncCtrl - > Gains_Q16 [ k ] > 0 ) ;
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}
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/* Bandwidth expansion */
silk_bwexpander_32 ( AR_Q24 , psEnc - > sCmn . shapingLPCOrder , BWExp_Q16 ) ;
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if ( psEnc - > sCmn . warping_Q16 > 0 ) {
/* Convert to monic warped prediction coefficients and limit absolute values */
limit_warped_coefs ( AR_Q24 , warping_Q16 , SILK_FIX_CONST ( 3.999 , 24 ) , psEnc - > sCmn . shapingLPCOrder ) ;
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/* Convert from Q24 to Q13 and store in int16 */
for ( i = 0 ; i < psEnc - > sCmn . shapingLPCOrder ; i + + ) {
psEncCtrl - > AR_Q13 [ k * MAX_SHAPE_LPC_ORDER + i ] = ( opus_int16 ) silk_SAT16 ( silk_RSHIFT_ROUND ( AR_Q24 [ i ] , 11 ) ) ;
}
} else {
silk_LPC_fit ( & psEncCtrl - > AR_Q13 [ k * MAX_SHAPE_LPC_ORDER ] , AR_Q24 , 13 , 24 , psEnc - > sCmn . shapingLPCOrder ) ;
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}
}
/*****************/
/* Gain tweaking */
/*****************/
/* Increase gains during low speech activity and put lower limit on gains */
gain_mult_Q16 = silk_log2lin ( - silk_SMLAWB ( - SILK_FIX_CONST ( 16.0 , 7 ) , SNR_adj_dB_Q7 , SILK_FIX_CONST ( 0.16 , 16 ) ) ) ;
gain_add_Q16 = silk_log2lin ( silk_SMLAWB ( SILK_FIX_CONST ( 16.0 , 7 ) , SILK_FIX_CONST ( MIN_QGAIN_DB , 7 ) , SILK_FIX_CONST ( 0.16 , 16 ) ) ) ;
silk_assert ( gain_mult_Q16 > 0 ) ;
for ( k = 0 ; k < psEnc - > sCmn . nb_subfr ; k + + ) {
psEncCtrl - > Gains_Q16 [ k ] = silk_SMULWW ( psEncCtrl - > Gains_Q16 [ k ] , gain_mult_Q16 ) ;
silk_assert ( psEncCtrl - > Gains_Q16 [ k ] > = 0 ) ;
psEncCtrl - > Gains_Q16 [ k ] = silk_ADD_POS_SAT32 ( psEncCtrl - > Gains_Q16 [ k ] , gain_add_Q16 ) ;
}
/************************************************/
/* Control low-frequency shaping and noise tilt */
/************************************************/
/* Less low frequency shaping for noisy inputs */
strength_Q16 = silk_MUL ( SILK_FIX_CONST ( LOW_FREQ_SHAPING , 4 ) , silk_SMLAWB ( SILK_FIX_CONST ( 1.0 , 12 ) ,
SILK_FIX_CONST ( LOW_QUALITY_LOW_FREQ_SHAPING_DECR , 13 ) , psEnc - > sCmn . input_quality_bands_Q15 [ 0 ] - SILK_FIX_CONST ( 1.0 , 15 ) ) ) ;
strength_Q16 = silk_RSHIFT ( silk_MUL ( strength_Q16 , psEnc - > sCmn . speech_activity_Q8 ) , 8 ) ;
if ( psEnc - > sCmn . indices . signalType = = TYPE_VOICED ) {
/* Reduce low frequencies quantization noise for periodic signals, depending on pitch lag */
/*f = 400; freqz([1, -0.98 + 2e-4 * f], [1, -0.97 + 7e-4 * f], 2^12, Fs); axis([0, 1000, -10, 1])*/
opus_int fs_kHz_inv = silk_DIV32_16 ( SILK_FIX_CONST ( 0.2 , 14 ) , psEnc - > sCmn . fs_kHz ) ;
for ( k = 0 ; k < psEnc - > sCmn . nb_subfr ; k + + ) {
b_Q14 = fs_kHz_inv + silk_DIV32_16 ( SILK_FIX_CONST ( 3.0 , 14 ) , psEncCtrl - > pitchL [ k ] ) ;
/* Pack two coefficients in one int32 */
psEncCtrl - > LF_shp_Q14 [ k ] = silk_LSHIFT ( SILK_FIX_CONST ( 1.0 , 14 ) - b_Q14 - silk_SMULWB ( strength_Q16 , b_Q14 ) , 16 ) ;
psEncCtrl - > LF_shp_Q14 [ k ] | = ( opus_uint16 ) ( b_Q14 - SILK_FIX_CONST ( 1.0 , 14 ) ) ;
}
silk_assert ( SILK_FIX_CONST ( HARM_HP_NOISE_COEF , 24 ) < SILK_FIX_CONST ( 0.5 , 24 ) ) ; /* Guarantees that second argument to SMULWB() is within range of an opus_int16*/
Tilt_Q16 = - SILK_FIX_CONST ( HP_NOISE_COEF , 16 ) -
silk_SMULWB ( SILK_FIX_CONST ( 1.0 , 16 ) - SILK_FIX_CONST ( HP_NOISE_COEF , 16 ) ,
silk_SMULWB ( SILK_FIX_CONST ( HARM_HP_NOISE_COEF , 24 ) , psEnc - > sCmn . speech_activity_Q8 ) ) ;
} else {
b_Q14 = silk_DIV32_16 ( 21299 , psEnc - > sCmn . fs_kHz ) ; /* 1.3_Q0 = 21299_Q14*/
/* Pack two coefficients in one int32 */
psEncCtrl - > LF_shp_Q14 [ 0 ] = silk_LSHIFT ( SILK_FIX_CONST ( 1.0 , 14 ) - b_Q14 -
silk_SMULWB ( strength_Q16 , silk_SMULWB ( SILK_FIX_CONST ( 0.6 , 16 ) , b_Q14 ) ) , 16 ) ;
psEncCtrl - > LF_shp_Q14 [ 0 ] | = ( opus_uint16 ) ( b_Q14 - SILK_FIX_CONST ( 1.0 , 14 ) ) ;
for ( k = 1 ; k < psEnc - > sCmn . nb_subfr ; k + + ) {
psEncCtrl - > LF_shp_Q14 [ k ] = psEncCtrl - > LF_shp_Q14 [ 0 ] ;
}
Tilt_Q16 = - SILK_FIX_CONST ( HP_NOISE_COEF , 16 ) ;
}
/****************************/
/* HARMONIC SHAPING CONTROL */
/****************************/
if ( USE_HARM_SHAPING & & psEnc - > sCmn . indices . signalType = = TYPE_VOICED ) {
/* More harmonic noise shaping for high bitrates or noisy input */
HarmShapeGain_Q16 = silk_SMLAWB ( SILK_FIX_CONST ( HARMONIC_SHAPING , 16 ) ,
SILK_FIX_CONST ( 1.0 , 16 ) - silk_SMULWB ( SILK_FIX_CONST ( 1.0 , 18 ) - silk_LSHIFT ( psEncCtrl - > coding_quality_Q14 , 4 ) ,
psEncCtrl - > input_quality_Q14 ) , SILK_FIX_CONST ( HIGH_RATE_OR_LOW_QUALITY_HARMONIC_SHAPING , 16 ) ) ;
/* Less harmonic noise shaping for less periodic signals */
HarmShapeGain_Q16 = silk_SMULWB ( silk_LSHIFT ( HarmShapeGain_Q16 , 1 ) ,
silk_SQRT_APPROX ( silk_LSHIFT ( psEnc - > LTPCorr_Q15 , 15 ) ) ) ;
} else {
HarmShapeGain_Q16 = 0 ;
}
/*************************/
/* Smooth over subframes */
/*************************/
for ( k = 0 ; k < MAX_NB_SUBFR ; k + + ) {
psShapeSt - > HarmShapeGain_smth_Q16 =
silk_SMLAWB ( psShapeSt - > HarmShapeGain_smth_Q16 , HarmShapeGain_Q16 - psShapeSt - > HarmShapeGain_smth_Q16 , SILK_FIX_CONST ( SUBFR_SMTH_COEF , 16 ) ) ;
psShapeSt - > Tilt_smth_Q16 =
silk_SMLAWB ( psShapeSt - > Tilt_smth_Q16 , Tilt_Q16 - psShapeSt - > Tilt_smth_Q16 , SILK_FIX_CONST ( SUBFR_SMTH_COEF , 16 ) ) ;
psEncCtrl - > HarmShapeGain_Q14 [ k ] = ( opus_int ) silk_RSHIFT_ROUND ( psShapeSt - > HarmShapeGain_smth_Q16 , 2 ) ;
psEncCtrl - > Tilt_Q14 [ k ] = ( opus_int ) silk_RSHIFT_ROUND ( psShapeSt - > Tilt_smth_Q16 , 2 ) ;
}
RESTORE_STACK ;
}
2017-03-30 23:58:05 +00:00
# endif /* OVERRIDE_silk_noise_shape_analysis_FIX */