shithub: opus

ref: 4e1ce38d49963361c53932783b6d590b115e4255
dir: /silk/silk_pitch_analysis_core.c/

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/***********************************************************************
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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

/***********************************************************
* Pitch analyser function
********************************************************** */
#include "silk_SigProc_FIX.h"
#include "silk_pitch_est_defines.h"
#include "silk_debug.h"

#define SCRATCH_SIZE    22

/************************************************************/
/* Internally used functions                                */
/************************************************************/
void silk_P_Ana_calc_corr_st3(
    opus_int32        cross_corr_st3[ PE_MAX_NB_SUBFR ][ PE_NB_CBKS_STAGE3_MAX ][ PE_NB_STAGE3_LAGS ],/* (O) 3 DIM correlation array */
    const opus_int16  frame[],                         /* I vector to correlate         */
    opus_int          start_lag,                       /* I lag offset to search around */
    opus_int          sf_length,                       /* I length of a 5 ms subframe   */
    opus_int          nb_subfr,                        /* I number of subframes         */
    opus_int          complexity                       /* I Complexity setting          */
);

void silk_P_Ana_calc_energy_st3(
    opus_int32        energies_st3[ PE_MAX_NB_SUBFR ][ PE_NB_CBKS_STAGE3_MAX ][ PE_NB_STAGE3_LAGS ],/* (O) 3 DIM energy array */
    const opus_int16  frame[],                         /* I vector to calc energy in    */
    opus_int          start_lag,                       /* I lag offset to search around */
    opus_int          sf_length,                       /* I length of one 5 ms subframe */
    opus_int          nb_subfr,                        /* I number of subframes         */
    opus_int          complexity                       /* I Complexity setting          */
);

opus_int32 silk_P_Ana_find_scaling(
    const opus_int16  *frame,
    const opus_int    frame_length,
    const opus_int    sum_sqr_len
);

/*************************************************************/
/*      FIXED POINT CORE PITCH ANALYSIS FUNCTION             */
/*************************************************************/
opus_int silk_pitch_analysis_core(        /* O    Voicing estimate: 0 voiced, 1 unvoiced                     */
    const opus_int16  *frame,             /* I    Signal of length PE_FRAME_LENGTH_MS*Fs_kHz                 */
    opus_int          *pitch_out,         /* O    4 pitch lag values                                         */
    opus_int16        *lagIndex,          /* O    Lag Index                                                  */
    opus_int8         *contourIndex,      /* O    Pitch contour Index                                        */
    opus_int          *LTPCorr_Q15,       /* I/O  Normalized correlation; input: value from previous frame   */
    opus_int          prevLag,            /* I    Last lag of previous frame; set to zero is unvoiced        */
    const opus_int32  search_thres1_Q16,  /* I    First stage threshold for lag candidates 0 - 1             */
    const opus_int    search_thres2_Q15,  /* I    Final threshold for lag candidates 0 - 1                   */
    const opus_int    Fs_kHz,             /* I    Sample frequency (kHz)                                     */
    const opus_int    complexity,         /* I    Complexity setting, 0-2, where 2 is highest                */
    const opus_int    nb_subfr            /* I    number of 5 ms subframes                                   */
)
{
    opus_int16 frame_8kHz[ PE_MAX_FRAME_LENGTH_ST_2 ];
    opus_int16 frame_4kHz[ PE_MAX_FRAME_LENGTH_ST_1 ];
    opus_int32 filt_state[ 6 ];
    opus_int32 scratch_mem[ 3 * PE_MAX_FRAME_LENGTH ];
    opus_int16 *input_frame_ptr;
    opus_int   i, k, d, j;
    opus_int16 C[ PE_MAX_NB_SUBFR ][ ( PE_MAX_LAG >> 1 ) + 5 ];
    const opus_int16 *target_ptr, *basis_ptr;
    opus_int32 cross_corr, normalizer, energy, shift, energy_basis, energy_target;
    opus_int   d_srch[ PE_D_SRCH_LENGTH ], Cmax, length_d_srch, length_d_comp;
    opus_int16 d_comp[ ( PE_MAX_LAG >> 1 ) + 5 ];
    opus_int32 sum, threshold, temp32, lag_counter;
    opus_int   CBimax, CBimax_new, CBimax_old, lag, start_lag, end_lag, lag_new;
    opus_int32 CC[ PE_NB_CBKS_STAGE2_EXT ], CCmax, CCmax_b, CCmax_new_b, CCmax_new;
    opus_int32 energies_st3[  PE_MAX_NB_SUBFR ][ PE_NB_CBKS_STAGE3_MAX ][ PE_NB_STAGE3_LAGS ];
    opus_int32 crosscorr_st3[ PE_MAX_NB_SUBFR ][ PE_NB_CBKS_STAGE3_MAX ][ PE_NB_STAGE3_LAGS ];
    opus_int   frame_length, frame_length_8kHz, frame_length_4kHz, max_sum_sq_length;
    opus_int   sf_length, sf_length_8kHz, sf_length_4kHz;
    opus_int   min_lag, min_lag_8kHz, min_lag_4kHz;
    opus_int   max_lag, max_lag_8kHz, max_lag_4kHz;
    opus_int32 contour_bias_Q20, diff, lz, lshift;
    opus_int   nb_cbk_search, cbk_size;
    opus_int32 delta_lag_log2_sqr_Q7, lag_log2_Q7, prevLag_log2_Q7, prev_lag_bias_Q15, corr_thres_Q15;
    const opus_int8 *Lag_CB_ptr;
    /* Check for valid sampling frequency */
    SKP_assert( Fs_kHz == 8 || Fs_kHz == 12 || Fs_kHz == 16 );

    /* Check for valid complexity setting */
    SKP_assert( complexity >= SILK_PE_MIN_COMPLEX );
    SKP_assert( complexity <= SILK_PE_MAX_COMPLEX );

    SKP_assert( search_thres1_Q16 >= 0 && search_thres1_Q16 <= (1<<16) );
    SKP_assert( search_thres2_Q15 >= 0 && search_thres2_Q15 <= (1<<15) );

    /* Setup frame lengths max / min lag for the sampling frequency */
    frame_length      = ( PE_LTP_MEM_LENGTH_MS + nb_subfr * PE_SUBFR_LENGTH_MS ) * Fs_kHz;
    frame_length_4kHz = ( PE_LTP_MEM_LENGTH_MS + nb_subfr * PE_SUBFR_LENGTH_MS ) * 4;
    frame_length_8kHz = ( PE_LTP_MEM_LENGTH_MS + nb_subfr * PE_SUBFR_LENGTH_MS ) * 8;
    sf_length         = PE_SUBFR_LENGTH_MS * Fs_kHz;
    sf_length_4kHz    = PE_SUBFR_LENGTH_MS * 4;
    sf_length_8kHz    = PE_SUBFR_LENGTH_MS * 8;
    min_lag           = PE_MIN_LAG_MS * Fs_kHz;
    min_lag_4kHz      = PE_MIN_LAG_MS * 4;
    min_lag_8kHz      = PE_MIN_LAG_MS * 8;
    max_lag           = PE_MAX_LAG_MS * Fs_kHz - 1;
    max_lag_4kHz      = PE_MAX_LAG_MS * 4;
    max_lag_8kHz      = PE_MAX_LAG_MS * 8 - 1;

    SKP_memset( C, 0, sizeof( opus_int16 ) * nb_subfr * ( ( PE_MAX_LAG >> 1 ) + 5) );

    /* Resample from input sampled at Fs_kHz to 8 kHz */
    if( Fs_kHz == 16 ) {
        SKP_memset( filt_state, 0, 2 * sizeof( opus_int32 ) );
        silk_resampler_down2( filt_state, frame_8kHz, frame, frame_length );
    } else if ( Fs_kHz == 12 ) {
        SKP_memset( filt_state, 0, 6 * sizeof( opus_int32 ) );
        silk_resampler_down2_3( filt_state, frame_8kHz, frame, frame_length );
    } else {
        SKP_assert( Fs_kHz == 8 );
        SKP_memcpy( frame_8kHz, frame, frame_length_8kHz * sizeof(opus_int16) );
    }

    /* Decimate again to 4 kHz */
    SKP_memset( filt_state, 0, 2 * sizeof( opus_int32 ) );/* Set state to zero */
    silk_resampler_down2( filt_state, frame_4kHz, frame_8kHz, frame_length_8kHz );

    /* Low-pass filter */
    for( i = frame_length_4kHz - 1; i > 0; i-- ) {
        frame_4kHz[ i ] = SKP_ADD_SAT16( frame_4kHz[ i ], frame_4kHz[ i - 1 ] );
    }

    /*******************************************************************************
    ** Scale 4 kHz signal down to prevent correlations measures from overflowing
    ** find scaling as max scaling for each 8kHz(?) subframe
    *******************************************************************************/

    /* Inner product is calculated with different lengths, so scale for the worst case */
    max_sum_sq_length = SKP_max_32( sf_length_8kHz, SKP_LSHIFT( sf_length_4kHz, 2 ) );
    shift = silk_P_Ana_find_scaling( frame_4kHz, frame_length_4kHz, max_sum_sq_length );
    if( shift > 0 ) {
        for( i = 0; i < frame_length_4kHz; i++ ) {
            frame_4kHz[ i ] = SKP_RSHIFT( frame_4kHz[ i ], shift );
        }
    }

    /******************************************************************************
    * FIRST STAGE, operating in 4 khz
    ******************************************************************************/
    target_ptr = &frame_4kHz[ SKP_LSHIFT( sf_length_4kHz, 2 ) ];
    for( k = 0; k < nb_subfr >> 1; k++ ) {
        /* Check that we are within range of the array */
        SKP_assert( target_ptr >= frame_4kHz );
        SKP_assert( target_ptr + sf_length_8kHz <= frame_4kHz + frame_length_4kHz );

        basis_ptr = target_ptr - min_lag_4kHz;

        /* Check that we are within range of the array */
        SKP_assert( basis_ptr >= frame_4kHz );
        SKP_assert( basis_ptr + sf_length_8kHz <= frame_4kHz + frame_length_4kHz );

        normalizer = 0;
        cross_corr = 0;
        /* Calculate first vector products before loop */
        cross_corr = silk_inner_prod_aligned( target_ptr, basis_ptr, sf_length_8kHz );
        normalizer = silk_inner_prod_aligned( basis_ptr,  basis_ptr, sf_length_8kHz );
        normalizer = SKP_ADD_SAT32( normalizer, SKP_SMULBB( sf_length_8kHz, 4000 ) );

        temp32 = SKP_DIV32( cross_corr, silk_SQRT_APPROX( normalizer ) + 1 );
        C[ k ][ min_lag_4kHz ] = (opus_int16)SKP_SAT16( temp32 );        /* Q0 */

        /* From now on normalizer is computed recursively */
        for( d = min_lag_4kHz + 1; d <= max_lag_4kHz; d++ ) {
            basis_ptr--;

            /* Check that we are within range of the array */
            SKP_assert( basis_ptr >= frame_4kHz );
            SKP_assert( basis_ptr + sf_length_8kHz <= frame_4kHz + frame_length_4kHz );

            cross_corr = silk_inner_prod_aligned( target_ptr, basis_ptr, sf_length_8kHz );

            /* Add contribution of new sample and remove contribution from oldest sample */
            normalizer +=
                SKP_SMULBB( basis_ptr[ 0 ], basis_ptr[ 0 ] ) -
                SKP_SMULBB( basis_ptr[ sf_length_8kHz ], basis_ptr[ sf_length_8kHz ] );

            temp32 = SKP_DIV32( cross_corr, silk_SQRT_APPROX( normalizer ) + 1 );
            C[ k ][ d ] = (opus_int16)SKP_SAT16( temp32 );                        /* Q0 */
        }
        /* Update target pointer */
        target_ptr += sf_length_8kHz;
    }

    /* Combine two subframes into single correlation measure and apply short-lag bias */
    if( nb_subfr == PE_MAX_NB_SUBFR ) {
        for( i = max_lag_4kHz; i >= min_lag_4kHz; i-- ) {
            sum = (opus_int32)C[ 0 ][ i ] + (opus_int32)C[ 1 ][ i ];                /* Q0 */
            SKP_assert( SKP_RSHIFT( sum, 1 ) == SKP_SAT16( SKP_RSHIFT( sum, 1 ) ) );
            sum = SKP_RSHIFT( sum, 1 );                                           /* Q-1 */
            SKP_assert( SKP_LSHIFT( (opus_int32)-i, 4 ) == SKP_SAT16( SKP_LSHIFT( (opus_int32)-i, 4 ) ) );
            sum = SKP_SMLAWB( sum, sum, SKP_LSHIFT( -i, 4 ) );                    /* Q-1 */
            SKP_assert( sum == SKP_SAT16( sum ) );
            C[ 0 ][ i ] = (opus_int16)sum;                                         /* Q-1 */
        }
    } else {
        /* Only short-lag bias */
        for( i = max_lag_4kHz; i >= min_lag_4kHz; i-- ) {
            sum = (opus_int32)C[ 0 ][ i ];
            sum = SKP_SMLAWB( sum, sum, SKP_LSHIFT( -i, 4 ) );                    /* Q-1 */
            C[ 0 ][ i ] = (opus_int16)sum;                                         /* Q-1 */
        }
    }

    /* Sort */
    length_d_srch = SKP_ADD_LSHIFT32( 4, complexity, 1 );
    SKP_assert( 3 * length_d_srch <= PE_D_SRCH_LENGTH );
    silk_insertion_sort_decreasing_int16( &C[ 0 ][ min_lag_4kHz ], d_srch, max_lag_4kHz - min_lag_4kHz + 1, length_d_srch );

    /* Escape if correlation is very low already here */
    target_ptr = &frame_4kHz[ SKP_SMULBB( sf_length_4kHz, nb_subfr ) ];
    energy = silk_inner_prod_aligned( target_ptr, target_ptr, SKP_LSHIFT( sf_length_4kHz, 2 ) );
    energy = SKP_ADD_SAT32( energy, 1000 );                                  /* Q0 */
    Cmax = (opus_int)C[ 0 ][ min_lag_4kHz ];                                  /* Q-1 */
    threshold = SKP_SMULBB( Cmax, Cmax );                                    /* Q-2 */

    /* Compare in Q-2 domain */
    if( SKP_RSHIFT( energy, 4 + 2 ) > threshold ) {
        SKP_memset( pitch_out, 0, nb_subfr * sizeof( opus_int ) );
        *LTPCorr_Q15  = 0;
        *lagIndex     = 0;
        *contourIndex = 0;
        return 1;
    }

    threshold = SKP_SMULWB( search_thres1_Q16, Cmax );
    for( i = 0; i < length_d_srch; i++ ) {
        /* Convert to 8 kHz indices for the sorted correlation that exceeds the threshold */
        if( C[ 0 ][ min_lag_4kHz + i ] > threshold ) {
            d_srch[ i ] = SKP_LSHIFT( d_srch[ i ] + min_lag_4kHz, 1 );
        } else {
            length_d_srch = i;
            break;
        }
    }
    SKP_assert( length_d_srch > 0 );

    for( i = min_lag_8kHz - 5; i < max_lag_8kHz + 5; i++ ) {
        d_comp[ i ] = 0;
    }
    for( i = 0; i < length_d_srch; i++ ) {
        d_comp[ d_srch[ i ] ] = 1;
    }

    /* Convolution */
    for( i = max_lag_8kHz + 3; i >= min_lag_8kHz; i-- ) {
        d_comp[ i ] += d_comp[ i - 1 ] + d_comp[ i - 2 ];
    }

    length_d_srch = 0;
    for( i = min_lag_8kHz; i < max_lag_8kHz + 1; i++ ) {
        if( d_comp[ i + 1 ] > 0 ) {
            d_srch[ length_d_srch ] = i;
            length_d_srch++;
        }
    }

    /* Convolution */
    for( i = max_lag_8kHz + 3; i >= min_lag_8kHz; i-- ) {
        d_comp[ i ] += d_comp[ i - 1 ] + d_comp[ i - 2 ] + d_comp[ i - 3 ];
    }

    length_d_comp = 0;
    for( i = min_lag_8kHz; i < max_lag_8kHz + 4; i++ ) {
        if( d_comp[ i ] > 0 ) {
            d_comp[ length_d_comp ] = i - 2;
            length_d_comp++;
        }
    }

    /**********************************************************************************
    ** SECOND STAGE, operating at 8 kHz, on lag sections with high correlation
    *************************************************************************************/

    /******************************************************************************
    ** Scale signal down to avoid correlations measures from overflowing
    *******************************************************************************/
    /* find scaling as max scaling for each subframe */
    shift = silk_P_Ana_find_scaling( frame_8kHz, frame_length_8kHz, sf_length_8kHz );
    if( shift > 0 ) {
        for( i = 0; i < frame_length_8kHz; i++ ) {
            frame_8kHz[ i ] = SKP_RSHIFT( frame_8kHz[ i ], shift );
        }
    }

    /*********************************************************************************
    * Find energy of each subframe projected onto its history, for a range of delays
    *********************************************************************************/
    SKP_memset( C, 0, PE_MAX_NB_SUBFR * ( ( PE_MAX_LAG >> 1 ) + 5 ) * sizeof( opus_int16 ) );

    target_ptr = &frame_8kHz[ PE_LTP_MEM_LENGTH_MS * 8 ];
    for( k = 0; k < nb_subfr; k++ ) {

        /* Check that we are within range of the array */
        SKP_assert( target_ptr >= frame_8kHz );
        SKP_assert( target_ptr + sf_length_8kHz <= frame_8kHz + frame_length_8kHz );

        energy_target = silk_inner_prod_aligned( target_ptr, target_ptr, sf_length_8kHz );
        // ToDo: Calculate 1 / energy_target here and save one division inside next for loop
        for( j = 0; j < length_d_comp; j++ ) {
            d = d_comp[ j ];
            basis_ptr = target_ptr - d;

            /* Check that we are within range of the array */
            SKP_assert( basis_ptr >= frame_8kHz );
            SKP_assert( basis_ptr + sf_length_8kHz <= frame_8kHz + frame_length_8kHz );

            cross_corr   = silk_inner_prod_aligned( target_ptr, basis_ptr, sf_length_8kHz );
            energy_basis = silk_inner_prod_aligned( basis_ptr,  basis_ptr, sf_length_8kHz );
            if( cross_corr > 0 ) {
                energy = SKP_max( energy_target, energy_basis ); /* Find max to make sure first division < 1.0 */
                lz = silk_CLZ32( cross_corr );
                lshift = SKP_LIMIT_32( lz - 1, 0, 15 );
                temp32 = SKP_DIV32( SKP_LSHIFT( cross_corr, lshift ), SKP_RSHIFT( energy, 15 - lshift ) + 1 ); /* Q15 */
                SKP_assert( temp32 == SKP_SAT16( temp32 ) );
                temp32 = SKP_SMULWB( cross_corr, temp32 ); /* Q(-1), cc * ( cc / max(b, t) ) */
                temp32 = SKP_ADD_SAT32( temp32, temp32 );  /* Q(0) */
                lz = silk_CLZ32( temp32 );
                lshift = SKP_LIMIT_32( lz - 1, 0, 15 );
                energy = SKP_min( energy_target, energy_basis );
                C[ k ][ d ] = SKP_DIV32( SKP_LSHIFT( temp32, lshift ), SKP_RSHIFT( energy, 15 - lshift ) + 1 ); // Q15
            } else {
                C[ k ][ d ] = 0;
            }
        }
        target_ptr += sf_length_8kHz;
    }

    /* search over lag range and lags codebook */
    /* scale factor for lag codebook, as a function of center lag */

    CCmax   = SKP_int32_MIN;
    CCmax_b = SKP_int32_MIN;

    CBimax = 0; /* To avoid returning undefined lag values */
    lag = -1;   /* To check if lag with strong enough correlation has been found */

    if( prevLag > 0 ) {
        if( Fs_kHz == 12 ) {
            prevLag = SKP_DIV32_16( SKP_LSHIFT( prevLag, 1 ), 3 );
        } else if( Fs_kHz == 16 ) {
            prevLag = SKP_RSHIFT( prevLag, 1 );
        }
        prevLag_log2_Q7 = silk_lin2log( (opus_int32)prevLag );
    } else {
        prevLag_log2_Q7 = 0;
    }
    SKP_assert( search_thres2_Q15 == SKP_SAT16( search_thres2_Q15 ) );
    /* Setup stage 2 codebook based on number of subframes */
    if( nb_subfr == PE_MAX_NB_SUBFR ) {
        cbk_size   = PE_NB_CBKS_STAGE2_EXT;
        Lag_CB_ptr = &silk_CB_lags_stage2[ 0 ][ 0 ];
        if( Fs_kHz == 8 && complexity > SILK_PE_MIN_COMPLEX ) {
            /* If input is 8 khz use a larger codebook here because it is last stage */
            nb_cbk_search = PE_NB_CBKS_STAGE2_EXT;
        } else {
            nb_cbk_search = PE_NB_CBKS_STAGE2;
        }
        corr_thres_Q15 = SKP_RSHIFT( SKP_SMULBB( search_thres2_Q15, search_thres2_Q15 ), 13 );
    } else {
        cbk_size       = PE_NB_CBKS_STAGE2_10MS;
        Lag_CB_ptr     = &silk_CB_lags_stage2_10_ms[ 0 ][ 0 ];
        nb_cbk_search  = PE_NB_CBKS_STAGE2_10MS;
        corr_thres_Q15 = SKP_RSHIFT( SKP_SMULBB( search_thres2_Q15, search_thres2_Q15 ), 14 );
    }

    for( k = 0; k < length_d_srch; k++ ) {
        d = d_srch[ k ];
        for( j = 0; j < nb_cbk_search; j++ ) {
            CC[ j ] = 0;
            for( i = 0; i < nb_subfr; i++ ) {
                /* Try all codebooks */
                CC[ j ] = CC[ j ] + (opus_int32)C[ i ][ d + matrix_ptr( Lag_CB_ptr, i, j, cbk_size )];
            }
        }
        /* Find best codebook */
        CCmax_new = SKP_int32_MIN;
        CBimax_new = 0;
        for( i = 0; i < nb_cbk_search; i++ ) {
            if( CC[ i ] > CCmax_new ) {
                CCmax_new = CC[ i ];
                CBimax_new = i;
            }
        }

        /* Bias towards shorter lags */
        lag_log2_Q7 = silk_lin2log( (opus_int32)d ); /* Q7 */
        SKP_assert( lag_log2_Q7 == SKP_SAT16( lag_log2_Q7 ) );
        SKP_assert( nb_subfr * SILK_FIX_CONST( PE_SHORTLAG_BIAS, 15 ) == SKP_SAT16( nb_subfr * SILK_FIX_CONST( PE_SHORTLAG_BIAS, 15 ) ) );
        CCmax_new_b = CCmax_new - SKP_RSHIFT( SKP_SMULBB( nb_subfr * SILK_FIX_CONST( PE_SHORTLAG_BIAS, 15 ), lag_log2_Q7 ), 7 ); /* Q15 */

        /* Bias towards previous lag */
        SKP_assert( nb_subfr * SILK_FIX_CONST( PE_PREVLAG_BIAS, 15 ) == SKP_SAT16( nb_subfr * SILK_FIX_CONST( PE_PREVLAG_BIAS, 15 ) ) );
        if( prevLag > 0 ) {
            delta_lag_log2_sqr_Q7 = lag_log2_Q7 - prevLag_log2_Q7;
            SKP_assert( delta_lag_log2_sqr_Q7 == SKP_SAT16( delta_lag_log2_sqr_Q7 ) );
            delta_lag_log2_sqr_Q7 = SKP_RSHIFT( SKP_SMULBB( delta_lag_log2_sqr_Q7, delta_lag_log2_sqr_Q7 ), 7 );
            prev_lag_bias_Q15 = SKP_RSHIFT( SKP_SMULBB( nb_subfr * SILK_FIX_CONST( PE_PREVLAG_BIAS, 15 ), *LTPCorr_Q15 ), 15 ); /* Q15 */
            prev_lag_bias_Q15 = SKP_DIV32( SKP_MUL( prev_lag_bias_Q15, delta_lag_log2_sqr_Q7 ), delta_lag_log2_sqr_Q7 + ( 1 << 6 ) );
            CCmax_new_b -= prev_lag_bias_Q15; /* Q15 */
        }

        if ( CCmax_new_b > CCmax_b                                          && /* Find maximum biased correlation                  */
             CCmax_new > corr_thres_Q15                                     && /* Correlation needs to be high enough to be voiced */
             silk_CB_lags_stage2[ 0 ][ CBimax_new ] <= min_lag_8kHz        /* Lag must be in range                             */
            ) {
            CCmax_b = CCmax_new_b;
            CCmax   = CCmax_new;
            lag     = d;
            CBimax  = CBimax_new;
        }
    }

    if( lag == -1 ) {
        /* No suitable candidate found */
        SKP_memset( pitch_out, 0, nb_subfr * sizeof( opus_int ) );
        *LTPCorr_Q15  = 0;
        *lagIndex     = 0;
        *contourIndex = 0;
        return 1;
    }

    if( Fs_kHz > 8 ) {

        /******************************************************************************
        ** Scale input signal down to avoid correlations measures from overflowing
        *******************************************************************************/
        /* find scaling as max scaling for each subframe */
        shift = silk_P_Ana_find_scaling( frame, frame_length, sf_length );
        if( shift > 0 ) {
            /* Move signal to scratch mem because the input signal should be unchanged */
            /* Reuse the 32 bit scratch mem vector, use a 16 bit pointer from now */
            input_frame_ptr = (opus_int16*)scratch_mem;
            for( i = 0; i < frame_length; i++ ) {
                input_frame_ptr[ i ] = SKP_RSHIFT( frame[ i ], shift );
            }
        } else {
            input_frame_ptr = (opus_int16*)frame;
        }
        /*********************************************************************************/

        /* Search in original signal */

        CBimax_old = CBimax;
        /* Compensate for decimation */
        SKP_assert( lag == SKP_SAT16( lag ) );
        if( Fs_kHz == 12 ) {
            lag = SKP_RSHIFT( SKP_SMULBB( lag, 3 ), 1 );
        } else if( Fs_kHz == 16 ) {
            lag = SKP_LSHIFT( lag, 1 );
        } else {
            lag = SKP_SMULBB( lag, 3 );
        }

        lag = SKP_LIMIT_int( lag, min_lag, max_lag );
        start_lag = SKP_max_int( lag - 2, min_lag );
        end_lag   = SKP_min_int( lag + 2, max_lag );
        lag_new   = lag;                                    /* to avoid undefined lag */
        CBimax    = 0;                                        /* to avoid undefined lag */
        SKP_assert( SKP_LSHIFT( CCmax, 13 ) >= 0 );
        *LTPCorr_Q15 = (opus_int)silk_SQRT_APPROX( SKP_LSHIFT( CCmax, 13 ) ); /* Output normalized correlation */

        CCmax = SKP_int32_MIN;
        /* pitch lags according to second stage */
        for( k = 0; k < nb_subfr; k++ ) {
            pitch_out[ k ] = lag + 2 * silk_CB_lags_stage2[ k ][ CBimax_old ];
        }
        /* Calculate the correlations and energies needed in stage 3 */
        silk_P_Ana_calc_corr_st3(  crosscorr_st3, input_frame_ptr, start_lag, sf_length, nb_subfr, complexity );
        silk_P_Ana_calc_energy_st3( energies_st3, input_frame_ptr, start_lag, sf_length, nb_subfr, complexity );

        lag_counter = 0;
        SKP_assert( lag == SKP_SAT16( lag ) );
        contour_bias_Q20 = SKP_DIV32_16( SILK_FIX_CONST( PE_FLATCONTOUR_BIAS, 20 ), lag );

        /* Setup cbk parameters acording to complexity setting and frame length */
        if( nb_subfr == PE_MAX_NB_SUBFR ) {
            nb_cbk_search   = (opus_int)silk_nb_cbk_searchs_stage3[ complexity ];
            cbk_size        = PE_NB_CBKS_STAGE3_MAX;
            Lag_CB_ptr      = &silk_CB_lags_stage3[ 0 ][ 0 ];
        } else {
            nb_cbk_search   = PE_NB_CBKS_STAGE3_10MS;
            cbk_size        = PE_NB_CBKS_STAGE3_10MS;
            Lag_CB_ptr      = &silk_CB_lags_stage3_10_ms[ 0 ][ 0 ];
        }
        for( d = start_lag; d <= end_lag; d++ ) {
            for( j = 0; j < nb_cbk_search; j++ ) {
                cross_corr = 0;
                energy     = 0;
                for( k = 0; k < nb_subfr; k++ ) {
                    SKP_assert( PE_MAX_NB_SUBFR == 4 );
                    energy     += SKP_RSHIFT( energies_st3[  k ][ j ][ lag_counter ], 2 ); /* use mean, to avoid overflow */
                    SKP_assert( energy >= 0 );
                    cross_corr += SKP_RSHIFT( crosscorr_st3[ k ][ j ][ lag_counter ], 2 ); /* use mean, to avoid overflow */
                }
                if( cross_corr > 0 ) {
                    /* Divide cross_corr / energy and get result in Q15 */
                    lz = silk_CLZ32( cross_corr );
                    /* Divide with result in Q13, cross_corr could be larger than energy */
                    lshift = SKP_LIMIT_32( lz - 1, 0, 13 );
                    CCmax_new = SKP_DIV32( SKP_LSHIFT( cross_corr, lshift ), SKP_RSHIFT( energy, 13 - lshift ) + 1 );
                    CCmax_new = SKP_SAT16( CCmax_new );
                    CCmax_new = SKP_SMULWB( cross_corr, CCmax_new );
                    /* Saturate */
                    if( CCmax_new > SKP_RSHIFT( SKP_int32_MAX, 3 ) ) {
                        CCmax_new = SKP_int32_MAX;
                    } else {
                        CCmax_new = SKP_LSHIFT( CCmax_new, 3 );
                    }
                    /* Reduce depending on flatness of contour */
                    diff = SKP_int16_MAX - SKP_RSHIFT( SKP_MUL( contour_bias_Q20, j ), 5 ); /* Q20 -> Q15 */
                    SKP_assert( diff == SKP_SAT16( diff ) );
                    CCmax_new = SKP_LSHIFT( SKP_SMULWB( CCmax_new, diff ), 1 );
                } else {
                    CCmax_new = 0;
                }

                if( CCmax_new > CCmax                                               &&
                   ( d + silk_CB_lags_stage3[ 0 ][ j ] ) <= max_lag
                   ) {
                    CCmax   = CCmax_new;
                    lag_new = d;
                    CBimax  = j;
                }
            }
            lag_counter++;
        }

        for( k = 0; k < nb_subfr; k++ ) {
            pitch_out[ k ] = lag_new + matrix_ptr( Lag_CB_ptr, k, CBimax, cbk_size );
        }
        *lagIndex = (opus_int16)( lag_new - min_lag);
        *contourIndex = (opus_int8)CBimax;
    } else {
        /* Save Lags and correlation */
        CCmax = SKP_max( CCmax, 0 );
        *LTPCorr_Q15 = (opus_int)silk_SQRT_APPROX( SKP_LSHIFT( CCmax, 13 ) ); /* Output normalized correlation */
        for( k = 0; k < nb_subfr; k++ ) {
            pitch_out[ k ] = lag + matrix_ptr( Lag_CB_ptr, k, CBimax, cbk_size );
        }
        *lagIndex = (opus_int16)( lag - min_lag_8kHz );
        *contourIndex = (opus_int8)CBimax;
    }
    SKP_assert( *lagIndex >= 0 );
    /* return as voiced */
    return 0;
}

/*************************************************************************/
/* Calculates the correlations used in stage 3 search. In order to cover */
/* the whole lag codebook for all the searched offset lags (lag +- 2),   */
/*************************************************************************/
void silk_P_Ana_calc_corr_st3(
    opus_int32        cross_corr_st3[ PE_MAX_NB_SUBFR ][ PE_NB_CBKS_STAGE3_MAX ][ PE_NB_STAGE3_LAGS ],/* (O) 3 DIM correlation array */
    const opus_int16  frame[],                         /* I vector to correlate         */
    opus_int          start_lag,                       /* I lag offset to search around */
    opus_int          sf_length,                       /* I length of a 5 ms subframe   */
    opus_int          nb_subfr,                        /* I number of subframes         */
    opus_int          complexity                       /* I Complexity setting          */
)
{
    const opus_int16 *target_ptr, *basis_ptr;
    opus_int32 cross_corr;
    opus_int   i, j, k, lag_counter, lag_low, lag_high;
    opus_int   nb_cbk_search, delta, idx, cbk_size;
    opus_int32 scratch_mem[ SCRATCH_SIZE ];
    const opus_int8 *Lag_range_ptr, *Lag_CB_ptr;

    SKP_assert( complexity >= SILK_PE_MIN_COMPLEX );
    SKP_assert( complexity <= SILK_PE_MAX_COMPLEX );

    if( nb_subfr == PE_MAX_NB_SUBFR ){
        Lag_range_ptr = &silk_Lag_range_stage3[ complexity ][ 0 ][ 0 ];
        Lag_CB_ptr    = &silk_CB_lags_stage3[ 0 ][ 0 ];
        nb_cbk_search = silk_nb_cbk_searchs_stage3[ complexity ];
        cbk_size      = PE_NB_CBKS_STAGE3_MAX;
    } else {
        SKP_assert( nb_subfr == PE_MAX_NB_SUBFR >> 1);
        Lag_range_ptr = &silk_Lag_range_stage3_10_ms[ 0 ][ 0 ];
        Lag_CB_ptr    = &silk_CB_lags_stage3_10_ms[ 0 ][ 0 ];
        nb_cbk_search = PE_NB_CBKS_STAGE3_10MS;
        cbk_size      = PE_NB_CBKS_STAGE3_10MS;
    }

    target_ptr = &frame[ SKP_LSHIFT( sf_length, 2 ) ]; /* Pointer to middle of frame */
    for( k = 0; k < nb_subfr; k++ ) {
        lag_counter = 0;

        /* Calculate the correlations for each subframe */
        lag_low  = matrix_ptr( Lag_range_ptr, k, 0, 2 );
        lag_high = matrix_ptr( Lag_range_ptr, k, 1, 2 );
        for( j = lag_low; j <= lag_high; j++ ) {
            basis_ptr = target_ptr - ( start_lag + j );
            cross_corr = silk_inner_prod_aligned( (opus_int16*)target_ptr, (opus_int16*)basis_ptr, sf_length );
            SKP_assert( lag_counter < SCRATCH_SIZE );
            scratch_mem[ lag_counter ] = cross_corr;
            lag_counter++;
        }

        delta = matrix_ptr( Lag_range_ptr, k, 0, 2 );
        for( i = 0; i < nb_cbk_search; i++ ) {
            /* Fill out the 3 dim array that stores the correlations for */
            /* each code_book vector for each start lag */
            idx = matrix_ptr( Lag_CB_ptr, k, i, cbk_size ) - delta;
            for( j = 0; j < PE_NB_STAGE3_LAGS; j++ ) {
                SKP_assert( idx + j < SCRATCH_SIZE );
                SKP_assert( idx + j < lag_counter );
                cross_corr_st3[ k ][ i ][ j ] = scratch_mem[ idx + j ];
            }
        }
        target_ptr += sf_length;
    }
}

/********************************************************************/
/* Calculate the energies for first two subframes. The energies are */
/* calculated recursively.                                          */
/********************************************************************/
void silk_P_Ana_calc_energy_st3(
    opus_int32        energies_st3[ PE_MAX_NB_SUBFR ][ PE_NB_CBKS_STAGE3_MAX ][ PE_NB_STAGE3_LAGS ],/* (O) 3 DIM energy array */
    const opus_int16  frame[],                         /* I vector to calc energy in    */
    opus_int          start_lag,                       /* I lag offset to search around */
    opus_int          sf_length,                       /* I length of one 5 ms subframe */
    opus_int          nb_subfr,                     /* I number of subframes         */
    opus_int          complexity                       /* I Complexity setting          */
)
{
    const opus_int16 *target_ptr, *basis_ptr;
    opus_int32 energy;
    opus_int   k, i, j, lag_counter;
    opus_int   nb_cbk_search, delta, idx, cbk_size, lag_diff;
    opus_int32 scratch_mem[ SCRATCH_SIZE ];
    const opus_int8 *Lag_range_ptr, *Lag_CB_ptr;

    SKP_assert( complexity >= SILK_PE_MIN_COMPLEX );
    SKP_assert( complexity <= SILK_PE_MAX_COMPLEX );

    if( nb_subfr == PE_MAX_NB_SUBFR ){
        Lag_range_ptr = &silk_Lag_range_stage3[ complexity ][ 0 ][ 0 ];
        Lag_CB_ptr    = &silk_CB_lags_stage3[ 0 ][ 0 ];
        nb_cbk_search = silk_nb_cbk_searchs_stage3[ complexity ];
        cbk_size      = PE_NB_CBKS_STAGE3_MAX;
    } else {
        SKP_assert( nb_subfr == PE_MAX_NB_SUBFR >> 1);
        Lag_range_ptr = &silk_Lag_range_stage3_10_ms[ 0 ][ 0 ];
        Lag_CB_ptr    = &silk_CB_lags_stage3_10_ms[ 0 ][ 0 ];
        nb_cbk_search = PE_NB_CBKS_STAGE3_10MS;
        cbk_size      = PE_NB_CBKS_STAGE3_10MS;
    }
    target_ptr = &frame[ SKP_LSHIFT( sf_length, 2 ) ];
    for( k = 0; k < nb_subfr; k++ ) {
        lag_counter = 0;

        /* Calculate the energy for first lag */
        basis_ptr = target_ptr - ( start_lag + matrix_ptr( Lag_range_ptr, k, 0, 2 ) );
        energy = silk_inner_prod_aligned( basis_ptr, basis_ptr, sf_length );
        SKP_assert( energy >= 0 );
        scratch_mem[ lag_counter ] = energy;
        lag_counter++;

        lag_diff = ( matrix_ptr( Lag_range_ptr, k, 1, 2 ) -  matrix_ptr( Lag_range_ptr, k, 0, 2 ) + 1 );
        for( i = 1; i < lag_diff; i++ ) {
            /* remove part outside new window */
            energy -= SKP_SMULBB( basis_ptr[ sf_length - i ], basis_ptr[ sf_length - i ] );
            SKP_assert( energy >= 0 );

            /* add part that comes into window */
            energy = SKP_ADD_SAT32( energy, SKP_SMULBB( basis_ptr[ -i ], basis_ptr[ -i ] ) );
            SKP_assert( energy >= 0 );
            SKP_assert( lag_counter < SCRATCH_SIZE );
            scratch_mem[ lag_counter ] = energy;
            lag_counter++;
        }

        delta = matrix_ptr( Lag_range_ptr, k, 0, 2 );
        for( i = 0; i < nb_cbk_search; i++ ) {
            /* Fill out the 3 dim array that stores the correlations for    */
            /* each code_book vector for each start lag                     */
            idx = matrix_ptr( Lag_CB_ptr, k, i, cbk_size ) - delta;
            for( j = 0; j < PE_NB_STAGE3_LAGS; j++ ) {
                SKP_assert( idx + j < SCRATCH_SIZE );
                SKP_assert( idx + j < lag_counter );
                energies_st3[ k ][ i ][ j ] = scratch_mem[ idx + j ];
                SKP_assert( energies_st3[ k ][ i ][ j ] >= 0 );
            }
        }
        target_ptr += sf_length;
    }
}

opus_int32 silk_P_Ana_find_scaling(
    const opus_int16  *frame,
    const opus_int    frame_length,
    const opus_int    sum_sqr_len
)
{
    opus_int32 nbits, x_max;

    x_max = silk_int16_array_maxabs( frame, frame_length );

    if( x_max < SKP_int16_MAX ) {
        /* Number of bits needed for the sum of the squares */
        nbits = 32 - silk_CLZ32( SKP_SMULBB( x_max, x_max ) );
    } else {
        /* Here we don't know if x_max should have been SKP_int16_MAX + 1, so we expect the worst case */
        nbits = 30;
    }
    nbits += 17 - silk_CLZ16( sum_sqr_len );

    /* Without a guarantee of saturation, we need to keep the 31st bit free */
    if( nbits < 31 ) {
        return 0;
    } else {
        return( nbits - 30 );
    }
}