silk-sys 0.1.0

/***********************************************************************
Copyright (c) 2006-2012, Skype Limited. All rights reserved. 
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modification, (subject to the limitations in the disclaimer below) 
are permitted provided that the following conditions are met:
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BY THIS LICENSE. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND 
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COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, 
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OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
***********************************************************************/

#include "SKP_Silk_main.h"
#include "SKP_Silk_PLC.h"

#define NB_ATT 2
static const SKP_int16 HARM_ATT_Q15[NB_ATT]              = { 32440, 31130 }; /* 0.99, 0.95 */
static const SKP_int16 PLC_RAND_ATTENUATE_V_Q15[NB_ATT]  = { 31130, 26214 }; /* 0.95, 0.8 */
static const SKP_int16 PLC_RAND_ATTENUATE_UV_Q15[NB_ATT] = { 32440, 29491 }; /* 0.99, 0.9 */

void SKP_Silk_PLC_Reset(
    SKP_Silk_decoder_state      *psDec              /* I/O Decoder state        */
)
{
    psDec->sPLC.pitchL_Q8 = SKP_RSHIFT( psDec->frame_length, 1 );
}

void SKP_Silk_PLC(
    SKP_Silk_decoder_state      *psDec,             /* I Decoder state          */
    SKP_Silk_decoder_control    *psDecCtrl,         /* I Decoder control        */
    SKP_int16                   signal[],           /* O Concealed signal       */
    SKP_int                     length,             /* I length of residual     */
    SKP_int                     lost                /* I Loss flag              */
)
{
    /* PLC control function */
    if( psDec->fs_kHz != psDec->sPLC.fs_kHz ) {
        SKP_Silk_PLC_Reset( psDec );
        psDec->sPLC.fs_kHz = psDec->fs_kHz;
    }

    if( lost ) {
        /****************************/
        /* Generate Signal          */
        /****************************/
        SKP_Silk_PLC_conceal( psDec, psDecCtrl, signal, length );

        psDec->lossCnt++;
    } else {
        /****************************/
        /* Update state             */
        /****************************/
        SKP_Silk_PLC_update( psDec, psDecCtrl, signal, length );
    }
}

/**************************************************/
/* Update state of PLC                            */
/**************************************************/
void SKP_Silk_PLC_update(
    SKP_Silk_decoder_state      *psDec,             /* (I/O) Decoder state          */
    SKP_Silk_decoder_control    *psDecCtrl,         /* (I/O) Decoder control        */
    SKP_int16                   signal[],
    SKP_int                     length
)
{
    SKP_int32 LTP_Gain_Q14, temp_LTP_Gain_Q14;
    SKP_int   i, j;
    SKP_Silk_PLC_struct *psPLC;

    psPLC = &psDec->sPLC;

    /* Update parameters used in case of packet loss */
    psDec->prev_sigtype = psDecCtrl->sigtype;
    LTP_Gain_Q14 = 0;
    if( psDecCtrl->sigtype == SIG_TYPE_VOICED ) {
        /* Find the parameters for the last subframe which contains a pitch pulse */
        for( j = 0; j * psDec->subfr_length  < psDecCtrl->pitchL[ NB_SUBFR - 1 ]; j++ ) {
            temp_LTP_Gain_Q14 = 0;
            for( i = 0; i < LTP_ORDER; i++ ) {
                temp_LTP_Gain_Q14 += psDecCtrl->LTPCoef_Q14[ ( NB_SUBFR - 1 - j ) * LTP_ORDER  + i ];
            }
            if( temp_LTP_Gain_Q14 > LTP_Gain_Q14 ) {
                LTP_Gain_Q14 = temp_LTP_Gain_Q14;
                SKP_memcpy( psPLC->LTPCoef_Q14,
                    &psDecCtrl->LTPCoef_Q14[ SKP_SMULBB( NB_SUBFR - 1 - j, LTP_ORDER ) ],
                    LTP_ORDER * sizeof( SKP_int16 ) );

                psPLC->pitchL_Q8 = SKP_LSHIFT( psDecCtrl->pitchL[ NB_SUBFR - 1 - j ], 8 );
            }
        }

#if USE_SINGLE_TAP
        SKP_memset( psPLC->LTPCoef_Q14, 0, LTP_ORDER * sizeof( SKP_int16 ) );
        psPLC->LTPCoef_Q14[ LTP_ORDER / 2 ] = LTP_Gain_Q14;
#endif

        /* Limit LT coefs */
        if( LTP_Gain_Q14 < V_PITCH_GAIN_START_MIN_Q14 ) {
            SKP_int   scale_Q10;
            SKP_int32 tmp;

            tmp = SKP_LSHIFT( V_PITCH_GAIN_START_MIN_Q14, 10 );
            scale_Q10 = SKP_DIV32( tmp, SKP_max( LTP_Gain_Q14, 1 ) );
            for( i = 0; i < LTP_ORDER; i++ ) {
                psPLC->LTPCoef_Q14[ i ] = SKP_RSHIFT( SKP_SMULBB( psPLC->LTPCoef_Q14[ i ], scale_Q10 ), 10 );
            }
        } else if( LTP_Gain_Q14 > V_PITCH_GAIN_START_MAX_Q14 ) {
            SKP_int   scale_Q14;
            SKP_int32 tmp;

            tmp = SKP_LSHIFT( V_PITCH_GAIN_START_MAX_Q14, 14 );
            scale_Q14 = SKP_DIV32( tmp, SKP_max( LTP_Gain_Q14, 1 ) );
            for( i = 0; i < LTP_ORDER; i++ ) {
                psPLC->LTPCoef_Q14[ i ] = SKP_RSHIFT( SKP_SMULBB( psPLC->LTPCoef_Q14[ i ], scale_Q14 ), 14 );
            }
        }
    } else {
        psPLC->pitchL_Q8 = SKP_LSHIFT( SKP_SMULBB( psDec->fs_kHz, 18 ), 8 );
        SKP_memset( psPLC->LTPCoef_Q14, 0, LTP_ORDER * sizeof( SKP_int16 ));
    }

    /* Save LPC coeficients */
    SKP_memcpy( psPLC->prevLPC_Q12, psDecCtrl->PredCoef_Q12[ 1 ], psDec->LPC_order * sizeof( SKP_int16 ) );
    psPLC->prevLTP_scale_Q14 = psDecCtrl->LTP_scale_Q14;

    /* Save Gains */
    SKP_memcpy( psPLC->prevGain_Q16, psDecCtrl->Gains_Q16, NB_SUBFR * sizeof( SKP_int32 ) );
}

void SKP_Silk_PLC_conceal(
    SKP_Silk_decoder_state      *psDec,             /* I/O Decoder state */
    SKP_Silk_decoder_control    *psDecCtrl,         /* I/O Decoder control */
    SKP_int16                   signal[],           /* O concealed signal */
    SKP_int                     length              /* I length of residual */
)
{
    SKP_int   i, j, k;
    SKP_int16 *B_Q14, exc_buf[ MAX_FRAME_LENGTH ], *exc_buf_ptr;
    SKP_int16 rand_scale_Q14;
    union {
        SKP_int16 as_int16[ MAX_LPC_ORDER ];
        SKP_int32 as_int32[ MAX_LPC_ORDER / 2 ];
    } A_Q12_tmp;
    SKP_int32 rand_seed, harm_Gain_Q15, rand_Gain_Q15;
    SKP_int   lag, idx, sLTP_buf_idx, shift1, shift2;
    SKP_int32 energy1, energy2, *rand_ptr, *pred_lag_ptr;
    SKP_int32 sig_Q10[ MAX_FRAME_LENGTH ], *sig_Q10_ptr, LPC_exc_Q10, LPC_pred_Q10,  LTP_pred_Q14;
    SKP_Silk_PLC_struct *psPLC;
#if !defined(_SYSTEM_IS_BIG_ENDIAN)
    SKP_int32 Atmp;
#endif
    psPLC = &psDec->sPLC;

    /* Update LTP buffer */
    SKP_memcpy( psDec->sLTP_Q16, &psDec->sLTP_Q16[ psDec->frame_length ], psDec->frame_length * sizeof( SKP_int32 ) );

    /* LPC concealment. Apply BWE to previous LPC */
    SKP_Silk_bwexpander( psPLC->prevLPC_Q12, psDec->LPC_order, BWE_COEF_Q16 );

    /* Find random noise component */
    /* Scale previous excitation signal */
    exc_buf_ptr = exc_buf;
    for( k = ( NB_SUBFR >> 1 ); k < NB_SUBFR; k++ ) {
        for( i = 0; i < psDec->subfr_length; i++ ) {
            exc_buf_ptr[ i ] = ( SKP_int16 )SKP_RSHIFT( 
                SKP_SMULWW( psDec->exc_Q10[ i + k * psDec->subfr_length ], psPLC->prevGain_Q16[ k ] ), 10 );
        }
        exc_buf_ptr += psDec->subfr_length;
    }
    /* Find the subframe with lowest energy of the last two and use that as random noise generator */ 
    SKP_Silk_sum_sqr_shift( &energy1, &shift1, exc_buf,                         psDec->subfr_length );
    SKP_Silk_sum_sqr_shift( &energy2, &shift2, &exc_buf[ psDec->subfr_length ], psDec->subfr_length );
        
    if( SKP_RSHIFT( energy1, shift2 ) < SKP_RSHIFT( energy2, shift1 ) ) {
        /* First sub-frame has lowest energy */
        rand_ptr = &psDec->exc_Q10[ SKP_max_int( 0, 3 * psDec->subfr_length - RAND_BUF_SIZE ) ];
    } else {
        /* Second sub-frame has lowest energy */
        rand_ptr = &psDec->exc_Q10[ SKP_max_int( 0, psDec->frame_length - RAND_BUF_SIZE ) ];
    }

    /* Setup Gain to random noise component */ 
    B_Q14          = psPLC->LTPCoef_Q14;
    rand_scale_Q14 = psPLC->randScale_Q14;

    /* Setup attenuation gains */
    harm_Gain_Q15 = HARM_ATT_Q15[ SKP_min_int( NB_ATT - 1, psDec->lossCnt ) ];
    if( psDec->prev_sigtype == SIG_TYPE_VOICED ) {
        rand_Gain_Q15 = PLC_RAND_ATTENUATE_V_Q15[  SKP_min_int( NB_ATT - 1, psDec->lossCnt ) ];
    } else {
        rand_Gain_Q15 = PLC_RAND_ATTENUATE_UV_Q15[ SKP_min_int( NB_ATT - 1, psDec->lossCnt ) ];
    }

    /* First Lost frame */
    if( psDec->lossCnt == 0 ) {
        rand_scale_Q14 = (1 << 14 );
    
        /* Reduce random noise Gain for voiced frames */
        if( psDec->prev_sigtype == SIG_TYPE_VOICED ) {
            for( i = 0; i < LTP_ORDER; i++ ) {
                rand_scale_Q14 -= B_Q14[ i ];
            }
            rand_scale_Q14 = SKP_max_16( 3277, rand_scale_Q14 ); /* 0.2 */
            rand_scale_Q14 = ( SKP_int16 )SKP_RSHIFT( SKP_SMULBB( rand_scale_Q14, psPLC->prevLTP_scale_Q14 ), 14 );
        }

        /* Reduce random noise for unvoiced frames with high LPC gain */
        if( psDec->prev_sigtype == SIG_TYPE_UNVOICED ) {
            SKP_int32 invGain_Q30, down_scale_Q30;
            
            SKP_Silk_LPC_inverse_pred_gain( &invGain_Q30, psPLC->prevLPC_Q12, psDec->LPC_order );
            
            down_scale_Q30 = SKP_min_32( SKP_RSHIFT( ( 1 << 30 ), LOG2_INV_LPC_GAIN_HIGH_THRES ), invGain_Q30 );
            down_scale_Q30 = SKP_max_32( SKP_RSHIFT( ( 1 << 30 ), LOG2_INV_LPC_GAIN_LOW_THRES ), down_scale_Q30 );
            down_scale_Q30 = SKP_LSHIFT( down_scale_Q30, LOG2_INV_LPC_GAIN_HIGH_THRES );
            
            rand_Gain_Q15 = SKP_RSHIFT( SKP_SMULWB( down_scale_Q30, rand_Gain_Q15 ), 14 );
        }
    }

    rand_seed    = psPLC->rand_seed;
    lag          = SKP_RSHIFT_ROUND( psPLC->pitchL_Q8, 8 );
    sLTP_buf_idx = psDec->frame_length;

    /***************************/
    /* LTP synthesis filtering */
    /***************************/
    sig_Q10_ptr = sig_Q10;
    for( k = 0; k < NB_SUBFR; k++ ) {
        /* Setup pointer */
        pred_lag_ptr = &psDec->sLTP_Q16[ sLTP_buf_idx - lag + LTP_ORDER / 2 ];
        for( i = 0; i < psDec->subfr_length; i++ ) {
            rand_seed = SKP_RAND( rand_seed );
            idx = SKP_RSHIFT( rand_seed, 25 ) & RAND_BUF_MASK;

            /* Unrolled loop */
            LTP_pred_Q14 = SKP_SMULWB(               pred_lag_ptr[  0 ], B_Q14[ 0 ] );
            LTP_pred_Q14 = SKP_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -1 ], B_Q14[ 1 ] );
            LTP_pred_Q14 = SKP_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -2 ], B_Q14[ 2 ] );
            LTP_pred_Q14 = SKP_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -3 ], B_Q14[ 3 ] );
            LTP_pred_Q14 = SKP_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -4 ], B_Q14[ 4 ] );
            pred_lag_ptr++;
            
            /* Generate LPC residual */
            LPC_exc_Q10 = SKP_LSHIFT( SKP_SMULWB( rand_ptr[ idx ], rand_scale_Q14 ), 2 ); /* Random noise part */
            LPC_exc_Q10 = SKP_ADD32( LPC_exc_Q10, SKP_RSHIFT_ROUND( LTP_pred_Q14, 4 ) );  /* Harmonic part */
            
            /* Update states */
            psDec->sLTP_Q16[ sLTP_buf_idx ] = SKP_LSHIFT( LPC_exc_Q10, 6 );
            sLTP_buf_idx++;
                
            /* Save LPC residual */
            sig_Q10_ptr[ i ] = LPC_exc_Q10;
        }
        sig_Q10_ptr += psDec->subfr_length;
        /* Gradually reduce LTP gain */
        for( j = 0; j < LTP_ORDER; j++ ) {
            B_Q14[ j ] = SKP_RSHIFT( SKP_SMULBB( harm_Gain_Q15, B_Q14[ j ] ), 15 );
        }
        /* Gradually reduce excitation gain */
        rand_scale_Q14 = SKP_RSHIFT( SKP_SMULBB( rand_scale_Q14, rand_Gain_Q15 ), 15 );

        /* Slowly increase pitch lag */
        psPLC->pitchL_Q8 += SKP_SMULWB( psPLC->pitchL_Q8, PITCH_DRIFT_FAC_Q16 );
        psPLC->pitchL_Q8 = SKP_min_32( psPLC->pitchL_Q8, SKP_LSHIFT( SKP_SMULBB( MAX_PITCH_LAG_MS, psDec->fs_kHz ), 8 ) );
        lag = SKP_RSHIFT_ROUND( psPLC->pitchL_Q8, 8 );
    }

    /***************************/
    /* LPC synthesis filtering */
    /***************************/
    sig_Q10_ptr = sig_Q10;
    /* Preload LPC coeficients to array on stack. Gives small performance gain */
    SKP_memcpy( A_Q12_tmp.as_int16, psPLC->prevLPC_Q12, psDec->LPC_order * sizeof( SKP_int16 ) );
    SKP_assert( psDec->LPC_order >= 10 ); /* check that unrolling works */
    for( k = 0; k < NB_SUBFR; k++ ) {
        for( i = 0; i < psDec->subfr_length; i++ ){
            /* partly unrolled */
#if !defined(_SYSTEM_IS_BIG_ENDIAN)
            /* NOTE: the code below loads two int16 values in an int32, and multiplies each using the   */
            /* SMLAWB and SMLAWT instructions. On a big-endian CPU the two int16 variables would be     */
            /* loaded in reverse order and the code will give the wrong result. In that case swapping   */
            /* the SMLAWB and SMLAWT instructions should solve the problem.                             */
            Atmp = A_Q12_tmp.as_int32[ 0 ];    /* read two coefficients at once */
            LPC_pred_Q10 = SKP_SMULWB(               psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  1 ], Atmp );
            LPC_pred_Q10 = SKP_SMLAWT( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  2 ], Atmp );
            Atmp = A_Q12_tmp.as_int32[ 1 ];
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  3 ], Atmp );
            LPC_pred_Q10 = SKP_SMLAWT( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  4 ], Atmp );
            Atmp = A_Q12_tmp.as_int32[ 2 ];
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  5 ], Atmp );
            LPC_pred_Q10 = SKP_SMLAWT( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  6 ], Atmp );
            Atmp = A_Q12_tmp.as_int32[ 3 ];
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  7 ], Atmp );
            LPC_pred_Q10 = SKP_SMLAWT( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  8 ], Atmp );
            Atmp = A_Q12_tmp.as_int32[ 4 ];
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  9 ], Atmp );
            LPC_pred_Q10 = SKP_SMLAWT( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i - 10 ], Atmp );
            for( j = 10 ; j < psDec->LPC_order ; j+=2 ) {
                Atmp = A_Q12_tmp.as_int32[ j / 2 ];
                LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  1 - j ], Atmp );
                LPC_pred_Q10 = SKP_SMLAWT( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  2 - j ], Atmp );
            }
#else
            LPC_pred_Q10 = SKP_SMULWB(               psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  1 ], A_Q12_tmp.as_int16[ 0 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  2 ], A_Q12_tmp.as_int16[ 1 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  3 ], A_Q12_tmp.as_int16[ 2 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  4 ], A_Q12_tmp.as_int16[ 3 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  5 ], A_Q12_tmp.as_int16[ 4 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  6 ], A_Q12_tmp.as_int16[ 5 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  7 ], A_Q12_tmp.as_int16[ 6 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  8 ], A_Q12_tmp.as_int16[ 7 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i -  9 ], A_Q12_tmp.as_int16[ 8 ] );
            LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i - 10 ], A_Q12_tmp.as_int16[ 9 ] );

            for( j = 10; j < psDec->LPC_order; j++ ) {
                LPC_pred_Q10 = SKP_SMLAWB( LPC_pred_Q10, psDec->sLPC_Q14[ MAX_LPC_ORDER + i - j - 1 ], A_Q12_tmp.as_int16[ j ] );
            }
#endif
            /* Add prediction to LPC residual */
            sig_Q10_ptr[ i ] = SKP_ADD32( sig_Q10_ptr[ i ], LPC_pred_Q10 );
                
            /* Update states */
            psDec->sLPC_Q14[ MAX_LPC_ORDER + i ] = SKP_LSHIFT( sig_Q10_ptr[ i ], 4 );
        }
        sig_Q10_ptr += psDec->subfr_length;
        /* Update LPC filter state */
        SKP_memcpy( psDec->sLPC_Q14, &psDec->sLPC_Q14[ psDec->subfr_length ], MAX_LPC_ORDER * sizeof( SKP_int32 ) );
    }

    /* Scale with Gain */
    for( i = 0; i < psDec->frame_length; i++ ) {
        signal[ i ] = ( SKP_int16 )SKP_SAT16( SKP_RSHIFT_ROUND( SKP_SMULWW( sig_Q10[ i ], psPLC->prevGain_Q16[ NB_SUBFR - 1 ] ), 10 ) );
    }

    /**************************************/
    /* Update states                      */
    /**************************************/
    psPLC->rand_seed     = rand_seed;
    psPLC->randScale_Q14 = rand_scale_Q14;
    for( i = 0; i < NB_SUBFR; i++ ) {
        psDecCtrl->pitchL[ i ] = lag;
    }
}

/* Glues concealed frames with new good recieved frames             */
void SKP_Silk_PLC_glue_frames(
    SKP_Silk_decoder_state      *psDec,             /* I/O decoder state    */
    SKP_Silk_decoder_control    *psDecCtrl,         /* I/O Decoder control  */
    SKP_int16                   signal[],           /* I/O signal           */
    SKP_int                     length              /* I length of residual */
)
{
    SKP_int   i, energy_shift;
    SKP_int32 energy;
    SKP_Silk_PLC_struct *psPLC;
    psPLC = &psDec->sPLC;

    if( psDec->lossCnt ) {
        /* Calculate energy in concealed residual */
        SKP_Silk_sum_sqr_shift( &psPLC->conc_energy, &psPLC->conc_energy_shift, signal, length );
        
        psPLC->last_frame_lost = 1;
    } else {
        if( psDec->sPLC.last_frame_lost ) {
            /* Calculate residual in decoded signal if last frame was lost */
            SKP_Silk_sum_sqr_shift( &energy, &energy_shift, signal, length );

            /* Normalize energies */
            if( energy_shift > psPLC->conc_energy_shift ) {
                psPLC->conc_energy = SKP_RSHIFT( psPLC->conc_energy, energy_shift - psPLC->conc_energy_shift );
            } else if( energy_shift < psPLC->conc_energy_shift ) {
                energy = SKP_RSHIFT( energy, psPLC->conc_energy_shift - energy_shift );
            }

            /* Fade in the energy difference */
            if( energy > psPLC->conc_energy ) {
                SKP_int32 frac_Q24, LZ;
                SKP_int32 gain_Q12, slope_Q12;

                LZ = SKP_Silk_CLZ32( psPLC->conc_energy );
                LZ = LZ - 1;
                psPLC->conc_energy = SKP_LSHIFT( psPLC->conc_energy, LZ );
                energy = SKP_RSHIFT( energy, SKP_max_32( 24 - LZ, 0 ) );
                
                frac_Q24 = SKP_DIV32( psPLC->conc_energy, SKP_max( energy, 1 ) );
                
                gain_Q12 = SKP_Silk_SQRT_APPROX( frac_Q24 );
                slope_Q12 = SKP_DIV32_16( ( 1 << 12 ) - gain_Q12, length );

                for( i = 0; i < length; i++ ) {
                    signal[ i ] = SKP_RSHIFT( SKP_MUL( gain_Q12, signal[ i ] ), 12 );
                    gain_Q12 += slope_Q12;
                    gain_Q12 = SKP_min( gain_Q12, ( 1 << 12 ) );
                }
            }
        }
        psPLC->last_frame_lost = 0;

    }
}