ba63b7d82f
Downloaded from https://archive.mozilla.org/pub/opus/opus-1.3.1.tar.gz
215 lines
12 KiB
C
215 lines
12 KiB
C
/***********************************************************************
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Copyright (c) 2006-2011, 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, are permitted provided that the following conditions
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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 Internet Society, IETF or IETF Trust, nor the
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names of specific contributors, may be used to endorse or promote
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products derived from this software without specific prior written
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permission.
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
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LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
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CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
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ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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POSSIBILITY OF SUCH DAMAGE.
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***********************************************************************/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include "main.h"
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/* Delayed-decision quantizer for NLSF residuals */
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opus_int32 silk_NLSF_del_dec_quant( /* O Returns RD value in Q25 */
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opus_int8 indices[], /* O Quantization indices [ order ] */
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const opus_int16 x_Q10[], /* I Input [ order ] */
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const opus_int16 w_Q5[], /* I Weights [ order ] */
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const opus_uint8 pred_coef_Q8[], /* I Backward predictor coefs [ order ] */
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const opus_int16 ec_ix[], /* I Indices to entropy coding tables [ order ] */
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const opus_uint8 ec_rates_Q5[], /* I Rates [] */
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const opus_int quant_step_size_Q16, /* I Quantization step size */
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const opus_int16 inv_quant_step_size_Q6, /* I Inverse quantization step size */
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const opus_int32 mu_Q20, /* I R/D tradeoff */
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const opus_int16 order /* I Number of input values */
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)
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{
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opus_int i, j, nStates, ind_tmp, ind_min_max, ind_max_min, in_Q10, res_Q10;
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opus_int pred_Q10, diff_Q10, rate0_Q5, rate1_Q5;
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opus_int16 out0_Q10, out1_Q10;
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opus_int32 RD_tmp_Q25, min_Q25, min_max_Q25, max_min_Q25;
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opus_int ind_sort[ NLSF_QUANT_DEL_DEC_STATES ];
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opus_int8 ind[ NLSF_QUANT_DEL_DEC_STATES ][ MAX_LPC_ORDER ];
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opus_int16 prev_out_Q10[ 2 * NLSF_QUANT_DEL_DEC_STATES ];
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opus_int32 RD_Q25[ 2 * NLSF_QUANT_DEL_DEC_STATES ];
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opus_int32 RD_min_Q25[ NLSF_QUANT_DEL_DEC_STATES ];
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opus_int32 RD_max_Q25[ NLSF_QUANT_DEL_DEC_STATES ];
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const opus_uint8 *rates_Q5;
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opus_int out0_Q10_table[2 * NLSF_QUANT_MAX_AMPLITUDE_EXT];
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opus_int out1_Q10_table[2 * NLSF_QUANT_MAX_AMPLITUDE_EXT];
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for (i = -NLSF_QUANT_MAX_AMPLITUDE_EXT; i <= NLSF_QUANT_MAX_AMPLITUDE_EXT-1; i++)
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{
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out0_Q10 = silk_LSHIFT( i, 10 );
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out1_Q10 = silk_ADD16( out0_Q10, 1024 );
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if( i > 0 ) {
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out0_Q10 = silk_SUB16( out0_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
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out1_Q10 = silk_SUB16( out1_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
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} else if( i == 0 ) {
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out1_Q10 = silk_SUB16( out1_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
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} else if( i == -1 ) {
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out0_Q10 = silk_ADD16( out0_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
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} else {
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out0_Q10 = silk_ADD16( out0_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
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out1_Q10 = silk_ADD16( out1_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
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}
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out0_Q10_table[ i + NLSF_QUANT_MAX_AMPLITUDE_EXT ] = silk_RSHIFT( silk_SMULBB( out0_Q10, quant_step_size_Q16 ), 16 );
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out1_Q10_table[ i + NLSF_QUANT_MAX_AMPLITUDE_EXT ] = silk_RSHIFT( silk_SMULBB( out1_Q10, quant_step_size_Q16 ), 16 );
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}
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silk_assert( (NLSF_QUANT_DEL_DEC_STATES & (NLSF_QUANT_DEL_DEC_STATES-1)) == 0 ); /* must be power of two */
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nStates = 1;
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RD_Q25[ 0 ] = 0;
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prev_out_Q10[ 0 ] = 0;
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for( i = order - 1; i >= 0; i-- ) {
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rates_Q5 = &ec_rates_Q5[ ec_ix[ i ] ];
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in_Q10 = x_Q10[ i ];
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for( j = 0; j < nStates; j++ ) {
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pred_Q10 = silk_RSHIFT( silk_SMULBB( (opus_int16)pred_coef_Q8[ i ], prev_out_Q10[ j ] ), 8 );
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res_Q10 = silk_SUB16( in_Q10, pred_Q10 );
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ind_tmp = silk_RSHIFT( silk_SMULBB( inv_quant_step_size_Q6, res_Q10 ), 16 );
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ind_tmp = silk_LIMIT( ind_tmp, -NLSF_QUANT_MAX_AMPLITUDE_EXT, NLSF_QUANT_MAX_AMPLITUDE_EXT-1 );
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ind[ j ][ i ] = (opus_int8)ind_tmp;
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/* compute outputs for ind_tmp and ind_tmp + 1 */
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out0_Q10 = out0_Q10_table[ ind_tmp + NLSF_QUANT_MAX_AMPLITUDE_EXT ];
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out1_Q10 = out1_Q10_table[ ind_tmp + NLSF_QUANT_MAX_AMPLITUDE_EXT ];
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out0_Q10 = silk_ADD16( out0_Q10, pred_Q10 );
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out1_Q10 = silk_ADD16( out1_Q10, pred_Q10 );
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prev_out_Q10[ j ] = out0_Q10;
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prev_out_Q10[ j + nStates ] = out1_Q10;
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/* compute RD for ind_tmp and ind_tmp + 1 */
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if( ind_tmp + 1 >= NLSF_QUANT_MAX_AMPLITUDE ) {
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if( ind_tmp + 1 == NLSF_QUANT_MAX_AMPLITUDE ) {
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rate0_Q5 = rates_Q5[ ind_tmp + NLSF_QUANT_MAX_AMPLITUDE ];
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rate1_Q5 = 280;
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} else {
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rate0_Q5 = silk_SMLABB( 280 - 43 * NLSF_QUANT_MAX_AMPLITUDE, 43, ind_tmp );
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rate1_Q5 = silk_ADD16( rate0_Q5, 43 );
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}
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} else if( ind_tmp <= -NLSF_QUANT_MAX_AMPLITUDE ) {
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if( ind_tmp == -NLSF_QUANT_MAX_AMPLITUDE ) {
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rate0_Q5 = 280;
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rate1_Q5 = rates_Q5[ ind_tmp + 1 + NLSF_QUANT_MAX_AMPLITUDE ];
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} else {
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rate0_Q5 = silk_SMLABB( 280 - 43 * NLSF_QUANT_MAX_AMPLITUDE, -43, ind_tmp );
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rate1_Q5 = silk_SUB16( rate0_Q5, 43 );
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}
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} else {
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rate0_Q5 = rates_Q5[ ind_tmp + NLSF_QUANT_MAX_AMPLITUDE ];
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rate1_Q5 = rates_Q5[ ind_tmp + 1 + NLSF_QUANT_MAX_AMPLITUDE ];
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}
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RD_tmp_Q25 = RD_Q25[ j ];
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diff_Q10 = silk_SUB16( in_Q10, out0_Q10 );
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RD_Q25[ j ] = silk_SMLABB( silk_MLA( RD_tmp_Q25, silk_SMULBB( diff_Q10, diff_Q10 ), w_Q5[ i ] ), mu_Q20, rate0_Q5 );
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diff_Q10 = silk_SUB16( in_Q10, out1_Q10 );
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RD_Q25[ j + nStates ] = silk_SMLABB( silk_MLA( RD_tmp_Q25, silk_SMULBB( diff_Q10, diff_Q10 ), w_Q5[ i ] ), mu_Q20, rate1_Q5 );
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}
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if( nStates <= NLSF_QUANT_DEL_DEC_STATES/2 ) {
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/* double number of states and copy */
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for( j = 0; j < nStates; j++ ) {
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ind[ j + nStates ][ i ] = ind[ j ][ i ] + 1;
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}
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nStates = silk_LSHIFT( nStates, 1 );
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for( j = nStates; j < NLSF_QUANT_DEL_DEC_STATES; j++ ) {
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ind[ j ][ i ] = ind[ j - nStates ][ i ];
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}
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} else {
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/* sort lower and upper half of RD_Q25, pairwise */
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for( j = 0; j < NLSF_QUANT_DEL_DEC_STATES; j++ ) {
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if( RD_Q25[ j ] > RD_Q25[ j + NLSF_QUANT_DEL_DEC_STATES ] ) {
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RD_max_Q25[ j ] = RD_Q25[ j ];
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RD_min_Q25[ j ] = RD_Q25[ j + NLSF_QUANT_DEL_DEC_STATES ];
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RD_Q25[ j ] = RD_min_Q25[ j ];
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RD_Q25[ j + NLSF_QUANT_DEL_DEC_STATES ] = RD_max_Q25[ j ];
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/* swap prev_out values */
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out0_Q10 = prev_out_Q10[ j ];
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prev_out_Q10[ j ] = prev_out_Q10[ j + NLSF_QUANT_DEL_DEC_STATES ];
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prev_out_Q10[ j + NLSF_QUANT_DEL_DEC_STATES ] = out0_Q10;
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ind_sort[ j ] = j + NLSF_QUANT_DEL_DEC_STATES;
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} else {
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RD_min_Q25[ j ] = RD_Q25[ j ];
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RD_max_Q25[ j ] = RD_Q25[ j + NLSF_QUANT_DEL_DEC_STATES ];
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ind_sort[ j ] = j;
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}
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}
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/* compare the highest RD values of the winning half with the lowest one in the losing half, and copy if necessary */
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/* afterwards ind_sort[] will contain the indices of the NLSF_QUANT_DEL_DEC_STATES winning RD values */
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while( 1 ) {
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min_max_Q25 = silk_int32_MAX;
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max_min_Q25 = 0;
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ind_min_max = 0;
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ind_max_min = 0;
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for( j = 0; j < NLSF_QUANT_DEL_DEC_STATES; j++ ) {
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if( min_max_Q25 > RD_max_Q25[ j ] ) {
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min_max_Q25 = RD_max_Q25[ j ];
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ind_min_max = j;
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}
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if( max_min_Q25 < RD_min_Q25[ j ] ) {
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max_min_Q25 = RD_min_Q25[ j ];
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ind_max_min = j;
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}
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}
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if( min_max_Q25 >= max_min_Q25 ) {
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break;
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}
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/* copy ind_min_max to ind_max_min */
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ind_sort[ ind_max_min ] = ind_sort[ ind_min_max ] ^ NLSF_QUANT_DEL_DEC_STATES;
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RD_Q25[ ind_max_min ] = RD_Q25[ ind_min_max + NLSF_QUANT_DEL_DEC_STATES ];
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prev_out_Q10[ ind_max_min ] = prev_out_Q10[ ind_min_max + NLSF_QUANT_DEL_DEC_STATES ];
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RD_min_Q25[ ind_max_min ] = 0;
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RD_max_Q25[ ind_min_max ] = silk_int32_MAX;
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silk_memcpy( ind[ ind_max_min ], ind[ ind_min_max ], MAX_LPC_ORDER * sizeof( opus_int8 ) );
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}
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/* increment index if it comes from the upper half */
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for( j = 0; j < NLSF_QUANT_DEL_DEC_STATES; j++ ) {
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ind[ j ][ i ] += silk_RSHIFT( ind_sort[ j ], NLSF_QUANT_DEL_DEC_STATES_LOG2 );
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}
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}
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}
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/* last sample: find winner, copy indices and return RD value */
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ind_tmp = 0;
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min_Q25 = silk_int32_MAX;
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for( j = 0; j < 2 * NLSF_QUANT_DEL_DEC_STATES; j++ ) {
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if( min_Q25 > RD_Q25[ j ] ) {
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min_Q25 = RD_Q25[ j ];
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ind_tmp = j;
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}
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}
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for( j = 0; j < order; j++ ) {
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indices[ j ] = ind[ ind_tmp & ( NLSF_QUANT_DEL_DEC_STATES - 1 ) ][ j ];
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silk_assert( indices[ j ] >= -NLSF_QUANT_MAX_AMPLITUDE_EXT );
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silk_assert( indices[ j ] <= NLSF_QUANT_MAX_AMPLITUDE_EXT );
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}
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indices[ 0 ] += silk_RSHIFT( ind_tmp, NLSF_QUANT_DEL_DEC_STATES_LOG2 );
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silk_assert( indices[ 0 ] <= NLSF_QUANT_MAX_AMPLITUDE_EXT );
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silk_assert( min_Q25 >= 0 );
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return min_Q25;
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}
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