339 lines
18 KiB
C
339 lines
18 KiB
C
/***********************************************************************
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Copyright (c) 2006-2010, Skype Limited. All rights reserved.
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Redistribution and use in source and binary forms, with or without
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modification, (subject to the limitations in the disclaimer below)
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are permitted provided that the following conditions are met:
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- Redistributions of source code must retain the above copyright notice,
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this list of conditions and the following disclaimer.
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- Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in the
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documentation and/or other materials provided with the distribution.
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- Neither the name of Skype Limited, nor the names of specific
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contributors, may be used to endorse or promote products derived from
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this software without specific prior written permission.
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NO EXPRESS OR IMPLIED LICENSES TO ANY PARTY'S PATENT RIGHTS ARE GRANTED
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BY THIS LICENSE. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
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CONTRIBUTORS ''AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING,
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BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
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FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
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COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
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INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
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NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
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USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
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ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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***********************************************************************/
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#include "SKP_Silk_main_FIX.h"
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#include "SKP_Silk_perceptual_parameters_FIX.h"
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/**************************************************************/
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/* Compute noise shaping coefficients and initial gain values */
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/**************************************************************/
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void SKP_Silk_noise_shape_analysis_FIX(
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SKP_Silk_encoder_state_FIX *psEnc, /* I/O Encoder state FIX */
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SKP_Silk_encoder_control_FIX *psEncCtrl, /* I/O Encoder control FIX */
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const SKP_int16 *pitch_res, /* I LPC residual from pitch analysis */
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const SKP_int16 *x /* I Input signal [ 2 * frame_length + la_shape ]*/
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)
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{
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SKP_Silk_shape_state_FIX *psShapeSt = &psEnc->sShape;
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SKP_int k, nSamples, lz, Qnrg, b_Q14, scale = 0, sz;
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SKP_int32 SNR_adj_dB_Q7, HarmBoost_Q16, HarmShapeGain_Q16, Tilt_Q16, tmp32;
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SKP_int32 nrg, pre_nrg_Q30, log_energy_Q7, log_energy_prev_Q7, energy_variation_Q7;
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SKP_int32 delta_Q16, BWExp1_Q16, BWExp2_Q16, gain_mult_Q16, gain_add_Q16, strength_Q16, b_Q8;
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SKP_int32 auto_corr[ SHAPE_LPC_ORDER_MAX + 1 ];
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SKP_int32 refl_coef_Q16[ SHAPE_LPC_ORDER_MAX ];
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SKP_int32 AR_Q24[ SHAPE_LPC_ORDER_MAX ];
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SKP_int16 x_windowed[ SHAPE_LPC_WIN_MAX ];
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const SKP_int16 *x_ptr, *pitch_res_ptr;
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SKP_int32 sqrt_nrg[ NB_SUBFR ], Qnrg_vec[ NB_SUBFR ];
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/* Point to start of first LPC analysis block */
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x_ptr = x + psEnc->sCmn.la_shape - SKP_SMULBB( SHAPE_LPC_WIN_MS, psEnc->sCmn.fs_kHz ) + psEnc->sCmn.frame_length / NB_SUBFR;
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/****************/
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/* CONTROL SNR */
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/****************/
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/* Reduce SNR_dB values if recent bitstream has exceeded TargetRate */
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psEncCtrl->current_SNR_dB_Q7 = psEnc->SNR_dB_Q7 - SKP_SMULWB( SKP_LSHIFT( ( SKP_int32 )psEnc->BufferedInChannel_ms, 7 ), 3277 );
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/* Reduce SNR_dB if inband FEC used */
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if( psEnc->speech_activity_Q8 > LBRR_SPEECH_ACTIVITY_THRES_Q8 ) {
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psEncCtrl->current_SNR_dB_Q7 -= SKP_RSHIFT( psEnc->inBandFEC_SNR_comp_Q8, 1 );
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}
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/****************/
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/* GAIN CONTROL */
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/****************/
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/* Input quality is the average of the quality in the lowest two VAD bands */
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psEncCtrl->input_quality_Q14 = ( SKP_int )SKP_RSHIFT( ( SKP_int32 )psEncCtrl->input_quality_bands_Q15[ 0 ]
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+ psEncCtrl->input_quality_bands_Q15[ 1 ], 2 );
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/* Coding quality level, between 0.0_Q0 and 1.0_Q0, but in Q14 */
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psEncCtrl->coding_quality_Q14 = SKP_RSHIFT( SKP_Silk_sigm_Q15( SKP_RSHIFT_ROUND( psEncCtrl->current_SNR_dB_Q7 - ( 18 << 7 ), 4 ) ), 1 );
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/* Reduce coding SNR during low speech activity */
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b_Q8 = ( 1 << 8 ) - psEnc->speech_activity_Q8;
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b_Q8 = SKP_SMULWB( SKP_LSHIFT( b_Q8, 8 ), b_Q8 );
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SNR_adj_dB_Q7 = SKP_SMLAWB( psEncCtrl->current_SNR_dB_Q7,
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SKP_SMULBB( -BG_SNR_DECR_dB_Q7 >> ( 4 + 1 ), b_Q8 ), // Q11
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SKP_SMULWB( ( 1 << 14 ) + psEncCtrl->input_quality_Q14, psEncCtrl->coding_quality_Q14 ) ); // Q12
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if( psEncCtrl->sCmn.sigtype == SIG_TYPE_VOICED ) {
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/* Reduce gains for periodic signals */
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SNR_adj_dB_Q7 = SKP_SMLAWB( SNR_adj_dB_Q7, HARM_SNR_INCR_dB_Q7 << 1, psEnc->LTPCorr_Q15 );
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} else {
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/* For unvoiced signals and low-quality input, adjust the quality slower than SNR_dB setting */
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SNR_adj_dB_Q7 = SKP_SMLAWB( SNR_adj_dB_Q7,
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SKP_SMLAWB( 6 << ( 7 + 2 ), -104856, psEncCtrl->current_SNR_dB_Q7 ), //-104856_Q18 = -0.4_Q0, Q9
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( 1 << 14 ) - psEncCtrl->input_quality_Q14 ); // Q14
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}
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/*************************/
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/* SPARSENESS PROCESSING */
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/*************************/
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/* Set quantizer offset */
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if( psEncCtrl->sCmn.sigtype == SIG_TYPE_VOICED ) {
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/* Initally set to 0; may be overruled in process_gains(..) */
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psEncCtrl->sCmn.QuantOffsetType = 0;
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psEncCtrl->sparseness_Q8 = 0;
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} else {
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/* Sparseness measure, based on relative fluctuations of energy per 2 milliseconds */
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nSamples = SKP_LSHIFT( psEnc->sCmn.fs_kHz, 1 );
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energy_variation_Q7 = 0;
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log_energy_prev_Q7 = 0;
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pitch_res_ptr = pitch_res;
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for( k = 0; k < FRAME_LENGTH_MS / 2; k++ ) {
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SKP_Silk_sum_sqr_shift( &nrg, &scale, pitch_res_ptr, nSamples );
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nrg += SKP_RSHIFT( nSamples, scale ); // Q(-scale)
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log_energy_Q7 = SKP_Silk_lin2log( nrg );
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if( k > 0 ) {
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energy_variation_Q7 += SKP_abs( log_energy_Q7 - log_energy_prev_Q7 );
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}
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log_energy_prev_Q7 = log_energy_Q7;
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pitch_res_ptr += nSamples;
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}
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psEncCtrl->sparseness_Q8 = SKP_RSHIFT( SKP_Silk_sigm_Q15( SKP_SMULWB( energy_variation_Q7 - ( 5 << 7 ), 6554 ) ), 7 ); // 6554_Q16 = 0.1_Q0
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/* Set quantization offset depending on sparseness measure */
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if( psEncCtrl->sparseness_Q8 > SPARSENESS_THRESHOLD_QNT_OFFSET_Q8 ) {
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psEncCtrl->sCmn.QuantOffsetType = 0;
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} else {
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psEncCtrl->sCmn.QuantOffsetType = 1;
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}
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/* Increase coding SNR for sparse signals */
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SNR_adj_dB_Q7 = SKP_SMLAWB( SNR_adj_dB_Q7, SPARSE_SNR_INCR_dB_Q7 << 8, psEncCtrl->sparseness_Q8 - ( 1 << 7 ) );
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}
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/*******************************/
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/* Control bandwidth expansion */
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/*******************************/
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delta_Q16 = SKP_SMULWB( ( 1 << 16 ) - SKP_SMULBB( 3, psEncCtrl->coding_quality_Q14 ), LOW_RATE_BANDWIDTH_EXPANSION_DELTA_Q16 );
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BWExp1_Q16 = BANDWIDTH_EXPANSION_Q16 - delta_Q16;
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BWExp2_Q16 = BANDWIDTH_EXPANSION_Q16 + delta_Q16;
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if( psEnc->sCmn.fs_kHz == 24 ) {
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/* Less bandwidth expansion for super wideband */
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BWExp1_Q16 = ( 1 << 16 ) - SKP_SMULWB( SWB_BANDWIDTH_EXPANSION_REDUCTION_Q16, ( 1 << 16 ) - BWExp1_Q16 );
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BWExp2_Q16 = ( 1 << 16 ) - SKP_SMULWB( SWB_BANDWIDTH_EXPANSION_REDUCTION_Q16, ( 1 << 16 ) - BWExp2_Q16 );
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}
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/* BWExp1 will be applied after BWExp2, so make it relative */
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BWExp1_Q16 = SKP_DIV32_16( SKP_LSHIFT( BWExp1_Q16, 14 ), SKP_RSHIFT( BWExp2_Q16, 2 ) );
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/********************************************/
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/* Compute noise shaping AR coefs and gains */
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/********************************************/
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sz = ( SKP_int )SKP_SMULBB( SHAPE_LPC_WIN_MS, psEnc->sCmn.fs_kHz );
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for( k = 0; k < NB_SUBFR; k++ ) {
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/* Apply window */
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SKP_Silk_apply_sine_window( x_windowed, x_ptr, 0, SHAPE_LPC_WIN_MS * psEnc->sCmn.fs_kHz );
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/* Update pointer: next LPC analysis block */
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x_ptr += psEnc->sCmn.frame_length / NB_SUBFR;
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/* Calculate auto correlation */
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SKP_Silk_autocorr( auto_corr, &scale, x_windowed, sz, psEnc->sCmn.shapingLPCOrder + 1 );
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/* Add white noise, as a fraction of energy */
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auto_corr[0] = SKP_ADD32( auto_corr[0], SKP_max_32( SKP_SMULWB( SKP_RSHIFT( auto_corr[ 0 ], 4 ), SHAPE_WHITE_NOISE_FRACTION_Q20 ), 1 ) );
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/* Calculate the reflection coefficients using schur */
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nrg = SKP_Silk_schur64( refl_coef_Q16, auto_corr, psEnc->sCmn.shapingLPCOrder );
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/* Convert reflection coefficients to prediction coefficients */
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SKP_Silk_k2a_Q16( AR_Q24, refl_coef_Q16, psEnc->sCmn.shapingLPCOrder );
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/* Bandwidth expansion for synthesis filter shaping */
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SKP_Silk_bwexpander_32( AR_Q24, psEnc->sCmn.shapingLPCOrder, BWExp2_Q16 );
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/* Make sure to fit in Q13 SKP_int16 */
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SKP_Silk_LPC_fit( &psEncCtrl->AR2_Q13[ k * SHAPE_LPC_ORDER_MAX ], AR_Q24, 13, psEnc->sCmn.shapingLPCOrder );
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/* Compute noise shaping filter coefficients */
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SKP_memcpy(
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&psEncCtrl->AR1_Q13[ k * SHAPE_LPC_ORDER_MAX ],
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&psEncCtrl->AR2_Q13[ k * SHAPE_LPC_ORDER_MAX ],
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psEnc->sCmn.shapingLPCOrder * sizeof( SKP_int16 ) );
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/* Bandwidth expansion for analysis filter shaping */
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SKP_assert( BWExp1_Q16 <= ( 1 << 16 ) ); // If ever breaking, use LPC_stabilize() in these cases to stay within range
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SKP_Silk_bwexpander( &psEncCtrl->AR1_Q13[ k * SHAPE_LPC_ORDER_MAX ], psEnc->sCmn.shapingLPCOrder, BWExp1_Q16 );
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/* Increase residual energy */
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nrg = SKP_SMLAWB( nrg, SKP_RSHIFT( auto_corr[ 0 ], 8 ), SHAPE_MIN_ENERGY_RATIO_Q24 );
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Qnrg = -scale; // range: -12...30
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SKP_assert( Qnrg >= -12 );
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SKP_assert( Qnrg <= 30 );
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/* Make sure that Qnrg is an even number */
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if( Qnrg & 1 ) {
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Qnrg -= 1;
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nrg >>= 1;
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}
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tmp32 = SKP_Silk_SQRT_APPROX( nrg );
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Qnrg >>= 1; // range: -6...15
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sqrt_nrg[ k ] = tmp32;
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Qnrg_vec[ k ] = Qnrg;
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psEncCtrl->Gains_Q16[ k ] = SKP_LSHIFT_SAT32( tmp32, 16 - Qnrg );
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/* Ratio of prediction gains, in energy domain */
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SKP_Silk_LPC_inverse_pred_gain_Q13( &pre_nrg_Q30, &psEncCtrl->AR2_Q13[ k * SHAPE_LPC_ORDER_MAX ], psEnc->sCmn.shapingLPCOrder );
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SKP_Silk_LPC_inverse_pred_gain_Q13( &nrg, &psEncCtrl->AR1_Q13[ k * SHAPE_LPC_ORDER_MAX ], psEnc->sCmn.shapingLPCOrder );
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lz = SKP_min_32( SKP_Silk_CLZ32( pre_nrg_Q30 ) - 1, 19 );
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pre_nrg_Q30 = SKP_DIV32( SKP_LSHIFT( pre_nrg_Q30, lz ), SKP_RSHIFT( nrg, 20 - lz ) + 1 ); // Q20
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pre_nrg_Q30 = SKP_RSHIFT( SKP_LSHIFT_SAT32( pre_nrg_Q30, 9 ), 1 ); /* Q28 */
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psEncCtrl->GainsPre_Q14[ k ] = ( SKP_int )SKP_Silk_SQRT_APPROX( pre_nrg_Q30 );
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}
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/*****************/
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/* Gain tweaking */
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/*****************/
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/* Increase gains during low speech activity and put lower limit on gains */
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gain_mult_Q16 = SKP_Silk_log2lin( -SKP_SMLAWB( -16 << 7, SNR_adj_dB_Q7, 10486 ) ); // 10486_Q16 = 0.16_Q0
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gain_add_Q16 = SKP_Silk_log2lin( SKP_SMLAWB( 16 << 7, NOISE_FLOOR_dB_Q7, 10486 ) ); // 10486_Q16 = 0.16_Q0
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tmp32 = SKP_Silk_log2lin( SKP_SMLAWB( 16 << 7, RELATIVE_MIN_GAIN_dB_Q7, 10486 ) ); // 10486_Q16 = 0.16_Q0
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tmp32 = SKP_SMULWW( psEnc->avgGain_Q16, tmp32 );
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gain_add_Q16 = SKP_ADD_SAT32( gain_add_Q16, tmp32 );
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SKP_assert( gain_mult_Q16 >= 0 );
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for( k = 0; k < NB_SUBFR; k++ ) {
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psEncCtrl->Gains_Q16[ k ] = SKP_SMULWW( psEncCtrl->Gains_Q16[ k ], gain_mult_Q16 );
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SKP_assert( psEncCtrl->Gains_Q16[ k ] >= 0 );
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}
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for( k = 0; k < NB_SUBFR; k++ ) {
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psEncCtrl->Gains_Q16[ k ] = SKP_ADD_POS_SAT32( psEncCtrl->Gains_Q16[ k ], gain_add_Q16 );
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psEnc->avgGain_Q16 = SKP_ADD_SAT32(
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psEnc->avgGain_Q16,
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SKP_SMULWB(
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psEncCtrl->Gains_Q16[ k ] - psEnc->avgGain_Q16,
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SKP_RSHIFT_ROUND( SKP_SMULBB( psEnc->speech_activity_Q8, GAIN_SMOOTHING_COEF_Q10 ), 2 )
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) );
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}
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/************************************************/
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/* Decrease level during fricatives (de-essing) */
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/************************************************/
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gain_mult_Q16 = ( 1 << 16 ) + SKP_RSHIFT_ROUND( SKP_MLA( INPUT_TILT_Q26, psEncCtrl->coding_quality_Q14, HIGH_RATE_INPUT_TILT_Q12 ), 10 );
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if( psEncCtrl->input_tilt_Q15 <= 0 && psEncCtrl->sCmn.sigtype == SIG_TYPE_UNVOICED ) {
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if( psEnc->sCmn.fs_kHz == 24 ) {
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SKP_int32 essStrength_Q15 = SKP_SMULWW( -psEncCtrl->input_tilt_Q15,
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SKP_SMULBB( psEnc->speech_activity_Q8, ( 1 << 8 ) - psEncCtrl->sparseness_Q8 ) );
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tmp32 = SKP_Silk_log2lin( ( 16 << 7 ) - SKP_SMULWB( essStrength_Q15,
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SKP_SMULWB( DE_ESSER_COEF_SWB_dB_Q7, 20972 ) ) ); // 20972_Q17 = 0.16_Q0
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gain_mult_Q16 = SKP_SMULWW( gain_mult_Q16, tmp32 );
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} else if( psEnc->sCmn.fs_kHz == 16 ) {
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SKP_int32 essStrength_Q15 = SKP_SMULWW(-psEncCtrl->input_tilt_Q15,
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SKP_SMULBB( psEnc->speech_activity_Q8, ( 1 << 8 ) - psEncCtrl->sparseness_Q8 ));
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tmp32 = SKP_Silk_log2lin( ( 16 << 7 ) - SKP_SMULWB( essStrength_Q15,
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SKP_SMULWB( DE_ESSER_COEF_WB_dB_Q7, 20972 ) ) ); // 20972_Q17 = 0.16_Q0
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gain_mult_Q16 = SKP_SMULWW( gain_mult_Q16, tmp32 );
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} else {
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SKP_assert( psEnc->sCmn.fs_kHz == 12 || psEnc->sCmn.fs_kHz == 8 );
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}
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}
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for( k = 0; k < NB_SUBFR; k++ ) {
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psEncCtrl->GainsPre_Q14[ k ] = SKP_SMULWB( gain_mult_Q16, psEncCtrl->GainsPre_Q14[ k ] );
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}
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/************************************************/
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/* Control low-frequency shaping and noise tilt */
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/************************************************/
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/* Less low frequency shaping for noisy inputs */
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strength_Q16 = SKP_MUL( LOW_FREQ_SHAPING_Q0, ( 1 << 16 ) + SKP_SMULBB( LOW_QUALITY_LOW_FREQ_SHAPING_DECR_Q1, psEncCtrl->input_quality_bands_Q15[ 0 ] - ( 1 << 15 ) ) );
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if( psEncCtrl->sCmn.sigtype == SIG_TYPE_VOICED ) {
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/* Reduce low frequencies quantization noise for periodic signals, depending on pitch lag */
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/*f = 400; freqz([1, -0.98 + 2e-4 * f], [1, -0.97 + 7e-4 * f], 2^12, Fs); axis([0, 1000, -10, 1])*/
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SKP_int fs_kHz_inv = SKP_DIV32_16( 3277, psEnc->sCmn.fs_kHz ); // 0.2_Q0 = 3277_Q14
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for( k = 0; k < NB_SUBFR; k++ ) {
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b_Q14 = fs_kHz_inv + SKP_DIV32_16( ( 3 << 14 ), psEncCtrl->sCmn.pitchL[ k ] );
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/* Pack two coefficients in one int32 */
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psEncCtrl->LF_shp_Q14[ k ] = SKP_LSHIFT( ( 1 << 14 ) - b_Q14 - SKP_SMULWB( strength_Q16, b_Q14 ), 16 );
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psEncCtrl->LF_shp_Q14[ k ] |= (SKP_uint16)( b_Q14 - ( 1 << 14 ) );
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}
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SKP_assert( HARM_HP_NOISE_COEF_Q24 < ( 1 << 23 ) ); // Guarantees that second argument to SMULWB() is within range of an SKP_int16
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Tilt_Q16 = - HP_NOISE_COEF_Q16 -
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SKP_SMULWB( ( 1 << 16 ) - HP_NOISE_COEF_Q16, SKP_SMULWB( HARM_HP_NOISE_COEF_Q24, psEnc->speech_activity_Q8 ) );
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} else {
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b_Q14 = SKP_DIV32_16( 21299, psEnc->sCmn.fs_kHz ); // 1.3_Q0 = 21299_Q14
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/* Pack two coefficients in one int32 */
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psEncCtrl->LF_shp_Q14[ 0 ] = SKP_LSHIFT( ( 1 << 14 ) - b_Q14 - SKP_SMULWB( strength_Q16, SKP_SMULWB( 39322, b_Q14 ) ), 16 ); // 0.6_Q0 = 39322_Q16
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psEncCtrl->LF_shp_Q14[ 0 ] |= (SKP_uint16)( b_Q14 - ( 1 << 14 ) );
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for( k = 1; k < NB_SUBFR; k++ ) {
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psEncCtrl->LF_shp_Q14[ k ] = psEncCtrl->LF_shp_Q14[ k - 1 ];
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}
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Tilt_Q16 = -HP_NOISE_COEF_Q16;
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}
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/****************************/
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/* HARMONIC SHAPING CONTROL */
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/****************************/
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/* Control boosting of harmonic frequencies */
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HarmBoost_Q16 = SKP_SMULWB( SKP_SMULWB( ( 1 << 17 ) - SKP_LSHIFT( psEncCtrl->coding_quality_Q14, 3 ),
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psEnc->LTPCorr_Q15 ), LOW_RATE_HARMONIC_BOOST_Q16 );
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/* More harmonic boost for noisy input signals */
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HarmBoost_Q16 = SKP_SMLAWB( HarmBoost_Q16,
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( 1 << 16 ) - SKP_LSHIFT( psEncCtrl->input_quality_Q14, 2 ), LOW_INPUT_QUALITY_HARMONIC_BOOST_Q16 );
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if( USE_HARM_SHAPING && psEncCtrl->sCmn.sigtype == SIG_TYPE_VOICED ) {
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/* More harmonic noise shaping for high bitrates or noisy input */
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HarmShapeGain_Q16 = SKP_SMLAWB( HARMONIC_SHAPING_Q16,
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( 1 << 16 ) - SKP_SMULWB( ( 1 << 18 ) - SKP_LSHIFT( psEncCtrl->coding_quality_Q14, 4 ),
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psEncCtrl->input_quality_Q14 ), HIGH_RATE_OR_LOW_QUALITY_HARMONIC_SHAPING_Q16 );
|
|
|
|
/* Less harmonic noise shaping for less periodic signals */
|
|
HarmShapeGain_Q16 = SKP_SMULWB( SKP_LSHIFT( HarmShapeGain_Q16, 1 ),
|
|
SKP_Silk_SQRT_APPROX( SKP_LSHIFT( psEnc->LTPCorr_Q15, 15 ) ) );
|
|
} else {
|
|
HarmShapeGain_Q16 = 0;
|
|
}
|
|
|
|
/*************************/
|
|
/* Smooth over subframes */
|
|
/*************************/
|
|
for( k = 0; k < NB_SUBFR; k++ ) {
|
|
psShapeSt->HarmBoost_smth_Q16 =
|
|
SKP_SMLAWB( psShapeSt->HarmBoost_smth_Q16, HarmBoost_Q16 - psShapeSt->HarmBoost_smth_Q16, SUBFR_SMTH_COEF_Q16 );
|
|
psShapeSt->HarmShapeGain_smth_Q16 =
|
|
SKP_SMLAWB( psShapeSt->HarmShapeGain_smth_Q16, HarmShapeGain_Q16 - psShapeSt->HarmShapeGain_smth_Q16, SUBFR_SMTH_COEF_Q16 );
|
|
psShapeSt->Tilt_smth_Q16 =
|
|
SKP_SMLAWB( psShapeSt->Tilt_smth_Q16, Tilt_Q16 - psShapeSt->Tilt_smth_Q16, SUBFR_SMTH_COEF_Q16 );
|
|
|
|
psEncCtrl->HarmBoost_Q14[ k ] = ( SKP_int )SKP_RSHIFT_ROUND( psShapeSt->HarmBoost_smth_Q16, 2 );
|
|
psEncCtrl->HarmShapeGain_Q14[ k ] = ( SKP_int )SKP_RSHIFT_ROUND( psShapeSt->HarmShapeGain_smth_Q16, 2 );
|
|
psEncCtrl->Tilt_Q14[ k ] = ( SKP_int )SKP_RSHIFT_ROUND( psShapeSt->Tilt_smth_Q16, 2 );
|
|
}
|
|
}
|