shithub: opus

ref: fce4323e15821b3278fe447c973dc744bafad585
dir: /silk/silk_NLSF_decode.c/

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/***********************************************************************
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#include "silk_main.h"

/* Predictive dequantizer for NLSF residuals */
void silk_NLSF_residual_dequant(                            /* O    Returns RD value in Q30                     */
          SKP_int16         x_Q10[],                        /* O    Output [ order ]                            */
    const SKP_int8          indices[],                      /* I    Quantization indices [ order ]              */
    const SKP_uint8         pred_coef_Q8[],                 /* I    Backward predictor coefs [ order ]          */
    const SKP_int           quant_step_size_Q16,            /* I    Quantization step size                      */
    const SKP_int16         order                           /* I    Number of input values                      */
)
{
    SKP_int     i, out_Q10, pred_Q10;
    
    out_Q10 = 0;
    for( i = order-1; i >= 0; i-- ) {
        pred_Q10 = SKP_RSHIFT( SKP_SMULBB( out_Q10, (SKP_int16)pred_coef_Q8[ i ] ), 8 );
        out_Q10  = SKP_LSHIFT( indices[ i ], 10 );
        if( out_Q10 > 0 ) {
            out_Q10 = SKP_SUB16( out_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
        } else if( out_Q10 < 0 ) {
            out_Q10 = SKP_ADD16( out_Q10, SILK_FIX_CONST( NLSF_QUANT_LEVEL_ADJ, 10 ) );
        }
        out_Q10  = SKP_SMLAWB( pred_Q10, out_Q10, quant_step_size_Q16 );
        x_Q10[ i ] = out_Q10;
    }
}


/***********************/
/* NLSF vector decoder */
/***********************/
void silk_NLSF_decode(
          SKP_int16             *pNLSF_Q15,             /* O    Quantized NLSF vector [ LPC_ORDER ]     */
          SKP_int8              *NLSFIndices,           /* I    Codebook path vector [ LPC_ORDER + 1 ]  */
    const silk_NLSF_CB_struct   *psNLSF_CB              /* I    Codebook object                         */
)
{
    SKP_int         i;
    SKP_uint8       pred_Q8[  MAX_LPC_ORDER ];
    SKP_int16       ec_ix[    MAX_LPC_ORDER ];
    SKP_int16       res_Q10[  MAX_LPC_ORDER ];
    SKP_int16       W_tmp_QW[ MAX_LPC_ORDER ];
    SKP_int32       W_tmp_Q9, NLSF_Q15_tmp;
    const SKP_uint8 *pCB_element;

    /* Decode first stage */
    pCB_element = &psNLSF_CB->CB1_NLSF_Q8[ NLSFIndices[ 0 ] * psNLSF_CB->order ];
    for( i = 0; i < psNLSF_CB->order; i++ ) {
        pNLSF_Q15[ i ] = SKP_LSHIFT( ( SKP_int16 )pCB_element[ i ], 7 );
    }

    /* Unpack entropy table indices and predictor for current CB1 index */
    silk_NLSF_unpack( ec_ix, pred_Q8, psNLSF_CB, NLSFIndices[ 0 ] );

    /* Trellis dequantizer */
    silk_NLSF_residual_dequant( res_Q10, &NLSFIndices[ 1 ], pred_Q8, psNLSF_CB->quantStepSize_Q16, psNLSF_CB->order );

    /* Weights from codebook vector */
    silk_NLSF_VQ_weights_laroia( W_tmp_QW, pNLSF_Q15, psNLSF_CB->order );

    /* Apply inverse square-rooted weights and add to output */
    for( i = 0; i < psNLSF_CB->order; i++ ) {
        W_tmp_Q9 = silk_SQRT_APPROX( SKP_LSHIFT( ( SKP_int32 )W_tmp_QW[ i ], 18 - NLSF_W_Q ) );
        NLSF_Q15_tmp = SKP_ADD32( pNLSF_Q15[ i ], SKP_DIV32_16( SKP_LSHIFT( ( SKP_int32 )res_Q10[ i ], 14 ), W_tmp_Q9 ) );
        pNLSF_Q15[ i ] = (SKP_int16)SKP_LIMIT( NLSF_Q15_tmp, 0, 32767 );
    }

    /* NLSF stabilization */
    silk_NLSF_stabilize( pNLSF_Q15, psNLSF_CB->deltaMin_Q15, psNLSF_CB->order );
}