shithub: opus

ref: f8ed894b1fb681109abc73ba75b3d6237a751d72
dir: /silk/arm/NSQ_del_dec_neon_intr.c/

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#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include <arm_neon.h>
#ifdef OPUS_CHECK_ASM
# include <string.h>
#endif
#include "main.h"
#include "stack_alloc.h"

/* NEON intrinsics optimization now can only parallelize up to 4 delay decision states.    */
/* If there are more states, C function is called, and this optimization must be expanded. */
#define NEON_MAX_DEL_DEC_STATES 4

typedef struct {
    opus_int32 sLPC_Q14[ MAX_SUB_FRAME_LENGTH + NSQ_LPC_BUF_LENGTH ][ NEON_MAX_DEL_DEC_STATES ];
    opus_int32 RandState[ DECISION_DELAY ][     NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Q_Q10[     DECISION_DELAY ][     NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Xq_Q14[    DECISION_DELAY ][     NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Pred_Q15[  DECISION_DELAY ][     NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Shape_Q14[ DECISION_DELAY ][     NEON_MAX_DEL_DEC_STATES ];
    opus_int32 sAR2_Q14[ MAX_SHAPE_LPC_ORDER ][ NEON_MAX_DEL_DEC_STATES ];
    opus_int32 LF_AR_Q14[ NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Diff_Q14[  NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Seed[      NEON_MAX_DEL_DEC_STATES ];
    opus_int32 SeedInit[  NEON_MAX_DEL_DEC_STATES ];
    opus_int32 RD_Q10[    NEON_MAX_DEL_DEC_STATES ];
} NSQ_del_decs_struct;

typedef struct {
    opus_int32 Q_Q10[        NEON_MAX_DEL_DEC_STATES ];
    opus_int32 RD_Q10[       NEON_MAX_DEL_DEC_STATES ];
    opus_int32 xq_Q14[       NEON_MAX_DEL_DEC_STATES ];
    opus_int32 LF_AR_Q14[    NEON_MAX_DEL_DEC_STATES ];
    opus_int32 Diff_Q14[     NEON_MAX_DEL_DEC_STATES ];
    opus_int32 sLTP_shp_Q14[ NEON_MAX_DEL_DEC_STATES ];
    opus_int32 LPC_exc_Q14[  NEON_MAX_DEL_DEC_STATES ];
} NSQ_samples_struct;

static OPUS_INLINE void silk_nsq_del_dec_scale_states_neon(
    const silk_encoder_state *psEncC,               /* I    Encoder State                       */
    silk_nsq_state      *NSQ,                       /* I/O  NSQ state                           */
    NSQ_del_decs_struct psDelDec[],                 /* I/O  Delayed decision states             */
    const opus_int16    x16[],                      /* I    Input                               */
    opus_int32          x_sc_Q10[],                 /* O    Input scaled with 1/Gain in Q10     */
    const opus_int16    sLTP[],                     /* I    Re-whitened LTP state in Q0         */
    opus_int32          sLTP_Q15[],                 /* O    LTP state matching scaled input     */
    opus_int            subfr,                      /* I    Subframe number                     */
    const opus_int      LTP_scale_Q14,              /* I    LTP state scaling                   */
    const opus_int32    Gains_Q16[ MAX_NB_SUBFR ],  /* I                                        */
    const opus_int      pitchL[ MAX_NB_SUBFR ],     /* I    Pitch lag                           */
    const opus_int      signal_type,                /* I    Signal type                         */
    const opus_int      decisionDelay               /* I    Decision delay                      */
);

/******************************************/
/* Noise shape quantizer for one subframe */
/******************************************/
static OPUS_INLINE void silk_noise_shape_quantizer_del_dec_neon(
    silk_nsq_state      *NSQ,                   /* I/O  NSQ state                           */
    NSQ_del_decs_struct psDelDec[],             /* I/O  Delayed decision states             */
    opus_int            signalType,             /* I    Signal type                         */
    const opus_int32    x_Q10[],                /* I                                        */
    opus_int8           pulses[],               /* O                                        */
    opus_int16          xq[],                   /* O                                        */
    opus_int32          sLTP_Q15[],             /* I/O  LTP filter state                    */
    opus_int32          delayedGain_Q10[],      /* I/O  Gain delay buffer                   */
    const opus_int16    a_Q12[],                /* I    Short term prediction coefs         */
    const opus_int16    b_Q14[],                /* I    Long term prediction coefs          */
    const opus_int16    AR_shp_Q13[],           /* I    Noise shaping coefs                 */
    opus_int            lag,                    /* I    Pitch lag                           */
    opus_int32          HarmShapeFIRPacked_Q14, /* I                                        */
    opus_int            Tilt_Q14,               /* I    Spectral tilt                       */
    opus_int32          LF_shp_Q14,             /* I                                        */
    opus_int32          Gain_Q16,               /* I                                        */
    opus_int            Lambda_Q10,             /* I                                        */
    opus_int            offset_Q10,             /* I                                        */
    opus_int            length,                 /* I    Input length                        */
    opus_int            subfr,                  /* I    Subframe number                     */
    opus_int            shapingLPCOrder,        /* I    Shaping LPC filter order            */
    opus_int            predictLPCOrder,        /* I    Prediction filter order             */
    opus_int            warping_Q16,            /* I                                        */
    opus_int            nStatesDelayedDecision, /* I    Number of states in decision tree   */
    opus_int            *smpl_buf_idx,          /* I/O  Index to newest samples in buffers  */
    opus_int            decisionDelay           /* I                                        */
);

static OPUS_INLINE void copy_winner_state_kernel(
    const NSQ_del_decs_struct *psDelDec,
    const opus_int            offset,
    const opus_int            last_smple_idx,
    const opus_int            Winner_ind,
    const int32x2_t           gain_lo_s32x2,
    const int32x2_t           gain_hi_s32x2,
    const int32x4_t           shift_s32x4,
    int32x4_t                 t0_s32x4,
    int32x4_t                 t1_s32x4,
    opus_int8 *const          pulses,
    opus_int16                *pxq,
    silk_nsq_state            *NSQ
)
{
    int16x8_t t_s16x8;
    int32x4_t o0_s32x4, o1_s32x4;

    t0_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 0 ][ Winner_ind ], t0_s32x4, 0 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 1 ][ Winner_ind ], t0_s32x4, 1 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 2 ][ Winner_ind ], t0_s32x4, 2 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 3 ][ Winner_ind ], t0_s32x4, 3 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 4 ][ Winner_ind ], t1_s32x4, 0 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 5 ][ Winner_ind ], t1_s32x4, 1 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 6 ][ Winner_ind ], t1_s32x4, 2 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Q_Q10[ last_smple_idx - 7 ][ Winner_ind ], t1_s32x4, 3 );
    t_s16x8 = vcombine_s16( vrshrn_n_s32( t0_s32x4, 10 ), vrshrn_n_s32( t1_s32x4, 10 ) );
    vst1_s8( &pulses[ offset ], vmovn_s16( t_s16x8 ) );

    t0_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 0 ][ Winner_ind ], t0_s32x4, 0 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 1 ][ Winner_ind ], t0_s32x4, 1 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 2 ][ Winner_ind ], t0_s32x4, 2 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 3 ][ Winner_ind ], t0_s32x4, 3 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 4 ][ Winner_ind ], t1_s32x4, 0 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 5 ][ Winner_ind ], t1_s32x4, 1 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 6 ][ Winner_ind ], t1_s32x4, 2 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Xq_Q14[ last_smple_idx - 7 ][ Winner_ind ], t1_s32x4, 3 );
    o0_s32x4 = vqdmulhq_lane_s32( t0_s32x4, gain_lo_s32x2, 0 );
    o1_s32x4 = vqdmulhq_lane_s32( t1_s32x4, gain_lo_s32x2, 0 );
    o0_s32x4 = vmlaq_lane_s32( o0_s32x4, t0_s32x4, gain_hi_s32x2, 0 );
    o1_s32x4 = vmlaq_lane_s32( o1_s32x4, t1_s32x4, gain_hi_s32x2, 0 );
    o0_s32x4 = vrshlq_s32( o0_s32x4, shift_s32x4 );
    o1_s32x4 = vrshlq_s32( o1_s32x4, shift_s32x4 );
    vst1_s16( &pxq[ offset + 0 ], vqmovn_s32( o0_s32x4 ) );
    vst1_s16( &pxq[ offset + 4 ], vqmovn_s32( o1_s32x4 ) );

    t0_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 0 ][ Winner_ind ], t0_s32x4, 0 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 1 ][ Winner_ind ], t0_s32x4, 1 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 2 ][ Winner_ind ], t0_s32x4, 2 );
    t0_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 3 ][ Winner_ind ], t0_s32x4, 3 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 4 ][ Winner_ind ], t1_s32x4, 0 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 5 ][ Winner_ind ], t1_s32x4, 1 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 6 ][ Winner_ind ], t1_s32x4, 2 );
    t1_s32x4 = vld1q_lane_s32( &psDelDec->Shape_Q14[ last_smple_idx - 7 ][ Winner_ind ], t1_s32x4, 3 );
    vst1q_s32( &NSQ->sLTP_shp_Q14[ NSQ->sLTP_shp_buf_idx + offset + 0 ], t0_s32x4 );
    vst1q_s32( &NSQ->sLTP_shp_Q14[ NSQ->sLTP_shp_buf_idx + offset + 4 ], t1_s32x4 );
}

static OPUS_INLINE void copy_winner_state(
    const NSQ_del_decs_struct *psDelDec,
    const opus_int            decisionDelay,
    const opus_int            smpl_buf_idx,
    const opus_int            Winner_ind,
    const opus_int32          gain,
    const opus_int32          shift,
    opus_int8 *const          pulses,
    opus_int16                *pxq,
    silk_nsq_state            *NSQ
)
{
    opus_int        i, last_smple_idx;
    const int32x2_t gain_lo_s32x2 = vdup_n_s32( silk_LSHIFT32( gain & 0x0000FFFF, 15 ) );
    const int32x2_t gain_hi_s32x2 = vdup_n_s32( gain >> 16 );
    const int32x4_t shift_s32x4 = vdupq_n_s32( -shift );
    int32x4_t       t0_s32x4, t1_s32x4;

    t0_s32x4 = t1_s32x4 = vdupq_n_s32( 0 ); /* initialization */
    last_smple_idx = smpl_buf_idx + decisionDelay - 1 + DECISION_DELAY;
    if( last_smple_idx >= DECISION_DELAY ) last_smple_idx -= DECISION_DELAY;
    if( last_smple_idx >= DECISION_DELAY ) last_smple_idx -= DECISION_DELAY;

    for( i = 0; ( i < ( decisionDelay - 7 ) ) && ( last_smple_idx >= 7 ); i += 8, last_smple_idx -= 8 ) {
        copy_winner_state_kernel( psDelDec, i - decisionDelay, last_smple_idx, Winner_ind, gain_lo_s32x2, gain_hi_s32x2, shift_s32x4, t0_s32x4, t1_s32x4, pulses, pxq, NSQ );
    }
    for( ; ( i < decisionDelay ) && ( last_smple_idx >= 0 ); i++, last_smple_idx-- ) {
        pulses[ i - decisionDelay ] = (opus_int8)silk_RSHIFT_ROUND( psDelDec->Q_Q10[ last_smple_idx ][ Winner_ind ], 10 );
        pxq[ i - decisionDelay ] = (opus_int16)silk_SAT16( silk_RSHIFT_ROUND( silk_SMULWW( psDelDec->Xq_Q14[ last_smple_idx ][ Winner_ind ], gain ), shift ) );
        NSQ->sLTP_shp_Q14[ NSQ->sLTP_shp_buf_idx - decisionDelay + i ] = psDelDec->Shape_Q14[ last_smple_idx ][ Winner_ind ];
    }

    last_smple_idx += DECISION_DELAY;
    for( ; i < ( decisionDelay - 7 ); i++, last_smple_idx-- ) {
        copy_winner_state_kernel( psDelDec, i - decisionDelay, last_smple_idx, Winner_ind, gain_lo_s32x2, gain_hi_s32x2, shift_s32x4, t0_s32x4, t1_s32x4, pulses, pxq, NSQ );
    }
    for( ; i < decisionDelay; i++, last_smple_idx-- ) {
        pulses[ i - decisionDelay ] = (opus_int8)silk_RSHIFT_ROUND( psDelDec->Q_Q10[ last_smple_idx ][ Winner_ind ], 10 );
        pxq[ i - decisionDelay ] = (opus_int16)silk_SAT16( silk_RSHIFT_ROUND( silk_SMULWW( psDelDec->Xq_Q14[ last_smple_idx ][ Winner_ind ], gain ), shift ) );
        NSQ->sLTP_shp_Q14[ NSQ->sLTP_shp_buf_idx - decisionDelay + i ] = psDelDec->Shape_Q14[ last_smple_idx ][ Winner_ind ];
    }
}

void silk_NSQ_del_dec_neon(
    const silk_encoder_state    *psEncC,                                    /* I    Encoder State                   */
    silk_nsq_state              *NSQ,                                       /* I/O  NSQ state                       */
    SideInfoIndices             *psIndices,                                 /* I/O  Quantization Indices            */
    const opus_int16            x16[],                                      /* I    Input                           */
    opus_int8                   pulses[],                                   /* O    Quantized pulse signal          */
    const opus_int16            PredCoef_Q12[ 2 * MAX_LPC_ORDER ],          /* I    Short term prediction coefs     */
    const opus_int16            LTPCoef_Q14[ LTP_ORDER * MAX_NB_SUBFR ],    /* I    Long term prediction coefs      */
    const opus_int16            AR_Q13[ MAX_NB_SUBFR * MAX_SHAPE_LPC_ORDER ], /* I Noise shaping coefs              */
    const opus_int              HarmShapeGain_Q14[ MAX_NB_SUBFR ],          /* I    Long term shaping coefs         */
    const opus_int              Tilt_Q14[ MAX_NB_SUBFR ],                   /* I    Spectral tilt                   */
    const opus_int32            LF_shp_Q14[ MAX_NB_SUBFR ],                 /* I    Low frequency shaping coefs     */
    const opus_int32            Gains_Q16[ MAX_NB_SUBFR ],                  /* I    Quantization step sizes         */
    const opus_int              pitchL[ MAX_NB_SUBFR ],                     /* I    Pitch lags                      */
    const opus_int              Lambda_Q10,                                 /* I    Rate/distortion tradeoff        */
    const opus_int              LTP_scale_Q14                               /* I    LTP state scaling               */
)
{
#ifdef OPUS_CHECK_ASM
    silk_nsq_state NSQ_c;
    SideInfoIndices psIndices_c;
    opus_int8 pulses_c[ MAX_FRAME_LENGTH ];
    const opus_int8 *const pulses_a = pulses;

    ( void )pulses_a;
    silk_memcpy( &NSQ_c, NSQ, sizeof( NSQ_c ) );
    silk_memcpy( &psIndices_c, psIndices, sizeof( psIndices_c ) );
    silk_memcpy( pulses_c, pulses, sizeof( pulses_c ) );
    silk_NSQ_del_dec_c( psEncC, &NSQ_c, &psIndices_c, x16, pulses_c, PredCoef_Q12, LTPCoef_Q14, AR_Q13, HarmShapeGain_Q14, Tilt_Q14, LF_shp_Q14, Gains_Q16,
                       pitchL, Lambda_Q10, LTP_scale_Q14 );
#endif

    /* The optimization parallelizes the different delay decision states. */
    if(( psEncC->nStatesDelayedDecision > NEON_MAX_DEL_DEC_STATES ) || ( psEncC->nStatesDelayedDecision <= 2 )) {
        /* NEON intrinsics optimization now can only parallelize up to 4 delay decision states.    */
        /* If there are more states, C function is called, and this optimization must be expanded. */
        /* When the number of delay decision states is less than 3, there are penalties using this */
        /* optimization, and C function is called.                                                 */
        /* When the number of delay decision states is 2, it's better to specialize another        */
        /* structure NSQ_del_dec2_struct and optimize with shorter NEON registers. (Low priority)  */
        silk_NSQ_del_dec_c( psEncC, NSQ, psIndices, x16, pulses, PredCoef_Q12, LTPCoef_Q14, AR_Q13, HarmShapeGain_Q14,
            Tilt_Q14, LF_shp_Q14, Gains_Q16, pitchL, Lambda_Q10, LTP_scale_Q14 );
    } else {
        opus_int            i, k, lag, start_idx, LSF_interpolation_flag, Winner_ind, subfr;
        opus_int            smpl_buf_idx, decisionDelay;
        const opus_int16    *A_Q12, *B_Q14, *AR_shp_Q13;
        opus_int16          *pxq;
        VARDECL( opus_int32, sLTP_Q15 );
        VARDECL( opus_int16, sLTP );
        opus_int32          HarmShapeFIRPacked_Q14;
        opus_int            offset_Q10;
        opus_int32          RDmin_Q10, Gain_Q10;
        VARDECL( opus_int32, x_sc_Q10 );
        VARDECL( opus_int32, delayedGain_Q10 );
        VARDECL( NSQ_del_decs_struct, psDelDec );
        int32x4_t           t_s32x4;
        SAVE_STACK;

        /* Set unvoiced lag to the previous one, overwrite later for voiced */
        lag = NSQ->lagPrev;

        silk_assert( NSQ->prev_gain_Q16 != 0 );

        /* Initialize delayed decision states */
        ALLOC( psDelDec, 1, NSQ_del_decs_struct );
        /* Only RandState and RD_Q10 need to be initialized to 0. */
        silk_memset( psDelDec->RandState, 0, sizeof( psDelDec->RandState ) );
        vst1q_s32( psDelDec->RD_Q10, vdupq_n_s32( 0 ) );

        for( k = 0; k < psEncC->nStatesDelayedDecision; k++ ) {
            psDelDec->SeedInit[ k ] = psDelDec->Seed[ k ] = ( k + psIndices->Seed ) & 3;
        }
        vst1q_s32( psDelDec->LF_AR_Q14, vld1q_dup_s32( &NSQ->sLF_AR_shp_Q14 ) );
        vst1q_s32( psDelDec->Diff_Q14, vld1q_dup_s32( &NSQ->sDiff_shp_Q14 ) );
        vst1q_s32( psDelDec->Shape_Q14[ 0 ], vld1q_dup_s32( &NSQ->sLTP_shp_Q14[ psEncC->ltp_mem_length - 1 ] ) );
        for( i = 0; i < NSQ_LPC_BUF_LENGTH; i++ ) {
            vst1q_s32( psDelDec->sLPC_Q14[ i ], vld1q_dup_s32( &NSQ->sLPC_Q14[ i ] ) );
        }
        for( i = 0; i < (opus_int)( sizeof( NSQ->sAR2_Q14 ) / sizeof( NSQ->sAR2_Q14[ 0 ] ) ); i++ ) {
            vst1q_s32( psDelDec->sAR2_Q14[ i ], vld1q_dup_s32( &NSQ->sAR2_Q14[ i ] ) );
        }

        offset_Q10   = silk_Quantization_Offsets_Q10[ psIndices->signalType >> 1 ][ psIndices->quantOffsetType ];
        smpl_buf_idx = 0; /* index of oldest samples */

        decisionDelay = silk_min_int( DECISION_DELAY, psEncC->subfr_length );

        /* For voiced frames limit the decision delay to lower than the pitch lag */
        if( psIndices->signalType == TYPE_VOICED ) {
            opus_int pitch_min = pitchL[ 0 ];
            for( k = 1; k < psEncC->nb_subfr; k++ ) {
                pitch_min = silk_min_int( pitch_min, pitchL[ k ] );
            }
            decisionDelay = silk_min_int( decisionDelay, pitch_min - LTP_ORDER / 2 - 1 );
        } else {
            if( lag > 0 ) {
                decisionDelay = silk_min_int( decisionDelay, lag - LTP_ORDER / 2 - 1 );
            }
        }

        if( psIndices->NLSFInterpCoef_Q2 == 4 ) {
            LSF_interpolation_flag = 0;
        } else {
            LSF_interpolation_flag = 1;
        }

        ALLOC( sLTP_Q15, psEncC->ltp_mem_length + psEncC->frame_length, opus_int32 );
        ALLOC( sLTP, psEncC->ltp_mem_length + psEncC->frame_length, opus_int16 );
        ALLOC( x_sc_Q10, psEncC->subfr_length, opus_int32 );
        ALLOC( delayedGain_Q10, DECISION_DELAY, opus_int32 );
        /* Set up pointers to start of sub frame */
        pxq                   = &NSQ->xq[ psEncC->ltp_mem_length ];
        NSQ->sLTP_shp_buf_idx = psEncC->ltp_mem_length;
        NSQ->sLTP_buf_idx     = psEncC->ltp_mem_length;
        subfr = 0;
        for( k = 0; k < psEncC->nb_subfr; k++ ) {
            A_Q12      = &PredCoef_Q12[ ( ( k >> 1 ) | ( 1 - LSF_interpolation_flag ) ) * MAX_LPC_ORDER ];
            B_Q14      = &LTPCoef_Q14[ k * LTP_ORDER           ];
            AR_shp_Q13 = &AR_Q13[     k * MAX_SHAPE_LPC_ORDER ];

            /* Noise shape parameters */
            silk_assert( HarmShapeGain_Q14[ k ] >= 0 );
            HarmShapeFIRPacked_Q14  =                          silk_RSHIFT( HarmShapeGain_Q14[ k ], 2 );
            HarmShapeFIRPacked_Q14 |= silk_LSHIFT( (opus_int32)silk_RSHIFT( HarmShapeGain_Q14[ k ], 1 ), 16 );

            NSQ->rewhite_flag = 0;
            if( psIndices->signalType == TYPE_VOICED ) {
                /* Voiced */
                lag = pitchL[ k ];

                /* Re-whitening */
                if( ( k & ( 3 - silk_LSHIFT( LSF_interpolation_flag, 1 ) ) ) == 0 ) {
                    if( k == 2 ) {
                        /* RESET DELAYED DECISIONS */
                        /* Find winner */
                        int32x4_t RD_Q10_s32x4;
                        RDmin_Q10 = psDelDec->RD_Q10[ 0 ];
                        Winner_ind = 0;
                        for( i = 1; i < psEncC->nStatesDelayedDecision; i++ ) {
                            if( psDelDec->RD_Q10[ i ] < RDmin_Q10 ) {
                                RDmin_Q10 = psDelDec->RD_Q10[ i ];
                                Winner_ind = i;
                            }
                        }
                        psDelDec->RD_Q10[ Winner_ind ] -= ( silk_int32_MAX >> 4 );
                        RD_Q10_s32x4 = vld1q_s32( psDelDec->RD_Q10 );
                        RD_Q10_s32x4 = vaddq_s32( RD_Q10_s32x4, vdupq_n_s32( silk_int32_MAX >> 4 ) );
                        vst1q_s32( psDelDec->RD_Q10, RD_Q10_s32x4 );

                        /* Copy final part of signals from winner state to output and long-term filter states */
                        copy_winner_state( psDelDec, decisionDelay, smpl_buf_idx, Winner_ind, Gains_Q16[ 1 ], 14, pulses, pxq, NSQ );

                        subfr = 0;
                    }

                    /* Rewhiten with new A coefs */
                    start_idx = psEncC->ltp_mem_length - lag - psEncC->predictLPCOrder - LTP_ORDER / 2;
                    silk_assert( start_idx > 0 );

                    silk_LPC_analysis_filter( &sLTP[ start_idx ], &NSQ->xq[ start_idx + k * psEncC->subfr_length ],
                        A_Q12, psEncC->ltp_mem_length - start_idx, psEncC->predictLPCOrder, psEncC->arch );

                    NSQ->sLTP_buf_idx = psEncC->ltp_mem_length;
                    NSQ->rewhite_flag = 1;
                }
            }

            silk_nsq_del_dec_scale_states_neon( psEncC, NSQ, psDelDec, x16, x_sc_Q10, sLTP, sLTP_Q15, k,
                LTP_scale_Q14, Gains_Q16, pitchL, psIndices->signalType, decisionDelay );

            silk_noise_shape_quantizer_del_dec_neon( NSQ, psDelDec, psIndices->signalType, x_sc_Q10, pulses, pxq, sLTP_Q15,
                delayedGain_Q10, A_Q12, B_Q14, AR_shp_Q13, lag, HarmShapeFIRPacked_Q14, Tilt_Q14[ k ], LF_shp_Q14[ k ],
                Gains_Q16[ k ], Lambda_Q10, offset_Q10, psEncC->subfr_length, subfr++, psEncC->shapingLPCOrder,
                psEncC->predictLPCOrder, psEncC->warping_Q16, psEncC->nStatesDelayedDecision, &smpl_buf_idx, decisionDelay );

            x16    += psEncC->subfr_length;
            pulses += psEncC->subfr_length;
            pxq    += psEncC->subfr_length;
        }

        /* Find winner */
        RDmin_Q10 = psDelDec->RD_Q10[ 0 ];
        Winner_ind = 0;
        for( k = 1; k < psEncC->nStatesDelayedDecision; k++ ) {
            if( psDelDec->RD_Q10[ k ] < RDmin_Q10 ) {
                RDmin_Q10 = psDelDec->RD_Q10[ k ];
                Winner_ind = k;
            }
        }

        /* Copy final part of signals from winner state to output and long-term filter states */
        psIndices->Seed = psDelDec->SeedInit[ Winner_ind ];
        Gain_Q10 = silk_RSHIFT32( Gains_Q16[ psEncC->nb_subfr - 1 ], 6 );
        copy_winner_state( psDelDec, decisionDelay, smpl_buf_idx, Winner_ind, Gain_Q10, 8, pulses, pxq, NSQ );

        t_s32x4 = vdupq_n_s32( 0 ); /* initialization */
        for( i = 0; i < ( NSQ_LPC_BUF_LENGTH - 3 ); i += 4 ) {
            t_s32x4 = vld1q_lane_s32( &psDelDec->sLPC_Q14[ i + 0 ][ Winner_ind ], t_s32x4, 0 );
            t_s32x4 = vld1q_lane_s32( &psDelDec->sLPC_Q14[ i + 1 ][ Winner_ind ], t_s32x4, 1 );
            t_s32x4 = vld1q_lane_s32( &psDelDec->sLPC_Q14[ i + 2 ][ Winner_ind ], t_s32x4, 2 );
            t_s32x4 = vld1q_lane_s32( &psDelDec->sLPC_Q14[ i + 3 ][ Winner_ind ], t_s32x4, 3 );
            vst1q_s32( &NSQ->sLPC_Q14[ i ], t_s32x4 );
        }

        for( ; i < NSQ_LPC_BUF_LENGTH; i++ ) {
          NSQ->sLPC_Q14[ i ] = psDelDec->sLPC_Q14[ i ][ Winner_ind ];
        }

        for( i = 0; i < (opus_int)( sizeof( NSQ->sAR2_Q14 ) / sizeof( NSQ->sAR2_Q14[ 0 ] ) - 3 ); i += 4 ) {
            t_s32x4 = vld1q_lane_s32( &psDelDec->sAR2_Q14[ i + 0 ][ Winner_ind ], t_s32x4, 0 );
            t_s32x4 = vld1q_lane_s32( &psDelDec->sAR2_Q14[ i + 1 ][ Winner_ind ], t_s32x4, 1 );
            t_s32x4 = vld1q_lane_s32( &psDelDec->sAR2_Q14[ i + 2 ][ Winner_ind ], t_s32x4, 2 );
            t_s32x4 = vld1q_lane_s32( &psDelDec->sAR2_Q14[ i + 3 ][ Winner_ind ], t_s32x4, 3 );
            vst1q_s32( &NSQ->sAR2_Q14[ i ], t_s32x4 );
        }

        for( ; i < (opus_int)( sizeof( NSQ->sAR2_Q14 ) / sizeof( NSQ->sAR2_Q14[ 0 ] ) ); i++ ) {
          NSQ->sAR2_Q14[ i ] = psDelDec->sAR2_Q14[ i ][ Winner_ind ];
        }

        /* Update states */
        NSQ->sLF_AR_shp_Q14 = psDelDec->LF_AR_Q14[ Winner_ind ];
        NSQ->sDiff_shp_Q14  = psDelDec->Diff_Q14[ Winner_ind ];
        NSQ->lagPrev        = pitchL[ psEncC->nb_subfr - 1 ];

        /* Save quantized speech signal */
        silk_memmove( NSQ->xq,           &NSQ->xq[           psEncC->frame_length ], psEncC->ltp_mem_length * sizeof( opus_int16 ) );
        silk_memmove( NSQ->sLTP_shp_Q14, &NSQ->sLTP_shp_Q14[ psEncC->frame_length ], psEncC->ltp_mem_length * sizeof( opus_int32 ) );
        RESTORE_STACK;
    }

#ifdef OPUS_CHECK_ASM
    silk_assert( !memcmp( &NSQ_c, NSQ, sizeof( NSQ_c ) ) );
    silk_assert( !memcmp( &psIndices_c, psIndices, sizeof( psIndices_c ) ) );
    silk_assert( !memcmp( pulses_c, pulses_a, sizeof( pulses_c ) ) );
#endif
}

/******************************************/
/* Noise shape quantizer for one subframe */
/******************************************/
/* Note: Function silk_short_prediction_create_arch_coef_neon() defined in NSQ_neon.h is actually a hacking C function. */
/*       Therefore here we append "_local" to the NEON function name to avoid confusion.                                */
static OPUS_INLINE void silk_short_prediction_create_arch_coef_neon_local(opus_int32 *out, const opus_int16 *in, opus_int order)
{
  int16x8_t t_s16x8;
  int32x4_t t0_s32x4, t1_s32x4, t2_s32x4, t3_s32x4;
  silk_assert( order == 10 || order == 16 );

  t_s16x8 = vld1q_s16( in + 0 );                                                   /* 7 6 5 4  3 2 1 0    */
  t_s16x8 = vrev64q_s16( t_s16x8 );                                                /* 4 5 6 7  0 1 2 3    */
  t2_s32x4 = vshll_n_s16( vget_high_s16( t_s16x8 ), 15 );                          /* 4 5 6 7             */
  t3_s32x4 = vshll_n_s16( vget_low_s16(  t_s16x8 ), 15 );                          /* 0 1 2 3             */

  if( order == 16 ) {
      t_s16x8 = vld1q_s16( in + 8 );                                               /* F E D C  B A 9 8    */
      t_s16x8 = vrev64q_s16( t_s16x8 );                                            /* C D E F  8 9 A B    */
      t0_s32x4 = vshll_n_s16( vget_high_s16( t_s16x8 ), 15 );                      /* C D E F             */
      t1_s32x4 = vshll_n_s16( vget_low_s16(  t_s16x8 ), 15 );                      /* 8 9 A B             */
  } else {
      int16x4_t t_s16x4;

      t0_s32x4 = vdupq_n_s32( 0 );                                                 /* zero zero zero zero */
      t_s16x4 = vld1_s16( in + 6 );                                                /* 9    8    7    6    */
      t_s16x4 = vrev64_s16( t_s16x4 );                                             /* 6    7    8    9    */
      t1_s32x4 = vshll_n_s16( t_s16x4, 15 );
      t1_s32x4 = vcombine_s32( vget_low_s32(t0_s32x4), vget_low_s32( t1_s32x4 ) ); /* 8    9    zero zero */
  }
  vst1q_s32( out +  0, t0_s32x4 );
  vst1q_s32( out +  4, t1_s32x4 );
  vst1q_s32( out +  8, t2_s32x4 );
  vst1q_s32( out + 12, t3_s32x4 );
}

static OPUS_INLINE int32x4_t silk_SMLAWB_lane0_neon(
    const int32x4_t out_s32x4,
    const int32x4_t in_s32x4,
    const int32x2_t coef_s32x2
)
{
    return vaddq_s32( out_s32x4, vqdmulhq_lane_s32( in_s32x4, coef_s32x2, 0 ) );
}

static OPUS_INLINE int32x4_t silk_SMLAWB_lane1_neon(
    const int32x4_t out_s32x4,
    const int32x4_t in_s32x4,
    const int32x2_t coef_s32x2
)
{
    return vaddq_s32( out_s32x4, vqdmulhq_lane_s32( in_s32x4, coef_s32x2, 1 ) );
}

/* Note: This function has different return value than silk_noise_shape_quantizer_short_prediction_neon(). */
/*       Therefore here we append "_local" to the function name to avoid confusion.                        */
static OPUS_INLINE int32x4_t silk_noise_shape_quantizer_short_prediction_neon_local(const opus_int32 *buf32, const opus_int32 *a_Q12_arch, opus_int order)
{
    const int32x4_t a_Q12_arch0_s32x4 = vld1q_s32( a_Q12_arch + 0 );
    const int32x4_t a_Q12_arch1_s32x4 = vld1q_s32( a_Q12_arch + 4 );
    const int32x4_t a_Q12_arch2_s32x4 = vld1q_s32( a_Q12_arch + 8 );
    const int32x4_t a_Q12_arch3_s32x4 = vld1q_s32( a_Q12_arch + 12 );
    int32x4_t LPC_pred_Q14_s32x4;

    silk_assert( order == 10 || order == 16 );
    /* Avoids introducing a bias because silk_SMLAWB() always rounds to -inf */
    LPC_pred_Q14_s32x4 = vdupq_n_s32( silk_RSHIFT( order, 1 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  0 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch0_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  1 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch0_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  2 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch0_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  3 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch0_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  4 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch1_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  5 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch1_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  6 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch1_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  7 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch1_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  8 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch2_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 +  9 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch2_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 + 10 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch2_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 + 11 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch2_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 + 12 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch3_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 + 13 * NEON_MAX_DEL_DEC_STATES ), vget_low_s32(  a_Q12_arch3_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane0_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 + 14 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch3_s32x4 ) );
    LPC_pred_Q14_s32x4 = silk_SMLAWB_lane1_neon( LPC_pred_Q14_s32x4, vld1q_s32( buf32 + 15 * NEON_MAX_DEL_DEC_STATES ), vget_high_s32( a_Q12_arch3_s32x4 ) );

    return LPC_pred_Q14_s32x4;
}

static OPUS_INLINE void silk_noise_shape_quantizer_del_dec_neon(
    silk_nsq_state      *NSQ,                   /* I/O  NSQ state                           */
    NSQ_del_decs_struct psDelDec[],             /* I/O  Delayed decision states             */
    opus_int            signalType,             /* I    Signal type                         */
    const opus_int32    x_Q10[],                /* I                                        */
    opus_int8           pulses[],               /* O                                        */
    opus_int16          xq[],                   /* O                                        */
    opus_int32          sLTP_Q15[],             /* I/O  LTP filter state                    */
    opus_int32          delayedGain_Q10[],      /* I/O  Gain delay buffer                   */
    const opus_int16    a_Q12[],                /* I    Short term prediction coefs         */
    const opus_int16    b_Q14[],                /* I    Long term prediction coefs          */
    const opus_int16    AR_shp_Q13[],           /* I    Noise shaping coefs                 */
    opus_int            lag,                    /* I    Pitch lag                           */
    opus_int32          HarmShapeFIRPacked_Q14, /* I                                        */
    opus_int            Tilt_Q14,               /* I    Spectral tilt                       */
    opus_int32          LF_shp_Q14,             /* I                                        */
    opus_int32          Gain_Q16,               /* I                                        */
    opus_int            Lambda_Q10,             /* I                                        */
    opus_int            offset_Q10,             /* I                                        */
    opus_int            length,                 /* I    Input length                        */
    opus_int            subfr,                  /* I    Subframe number                     */
    opus_int            shapingLPCOrder,        /* I    Shaping LPC filter order            */
    opus_int            predictLPCOrder,        /* I    Prediction filter order             */
    opus_int            warping_Q16,            /* I                                        */
    opus_int            nStatesDelayedDecision, /* I    Number of states in decision tree   */
    opus_int            *smpl_buf_idx,          /* I/O  Index to newest samples in buffers  */
    opus_int            decisionDelay           /* I                                        */
)
{
    opus_int     i, j, k, Winner_ind, RDmin_ind, RDmax_ind, last_smple_idx;
    opus_int32   Winner_rand_state;
    opus_int32   LTP_pred_Q14, n_LTP_Q14;
    opus_int32   RDmin_Q10, RDmax_Q10;
    opus_int32   Gain_Q10;
    opus_int32   *pred_lag_ptr, *shp_lag_ptr;
    opus_int32   a_Q12_arch[MAX_LPC_ORDER];
    const int32x2_t warping_Q16_s32x2 = vdup_n_s32( silk_LSHIFT32( warping_Q16, 16 ) >> 1 );
    const opus_int32 LF_shp_Q29 = silk_LSHIFT32( LF_shp_Q14, 16 ) >> 1;
    opus_int32 AR_shp_Q28[ MAX_SHAPE_LPC_ORDER ];
    const uint32x4_t rand_multiplier_u32x4 = vdupq_n_u32( RAND_MULTIPLIER );
    const uint32x4_t rand_increment_u32x4 = vdupq_n_u32( RAND_INCREMENT );

    VARDECL( NSQ_samples_struct, psSampleState );
    SAVE_STACK;

    silk_assert( nStatesDelayedDecision > 0 );
    silk_assert( ( shapingLPCOrder & 1 ) == 0 );   /* check that order is even */
    ALLOC( psSampleState, 2, NSQ_samples_struct );

    shp_lag_ptr  = &NSQ->sLTP_shp_Q14[ NSQ->sLTP_shp_buf_idx - lag + HARM_SHAPE_FIR_TAPS / 2 ];
    pred_lag_ptr = &sLTP_Q15[ NSQ->sLTP_buf_idx - lag + LTP_ORDER / 2 ];
    Gain_Q10     = silk_RSHIFT( Gain_Q16, 6 );

    for( i = 0; i < ( MAX_SHAPE_LPC_ORDER - 7 ); i += 8 ) {
      const int16x8_t t_s16x8 = vld1q_s16( AR_shp_Q13 +  i );
      vst1q_s32( AR_shp_Q28 + i + 0, vshll_n_s16( vget_low_s16(  t_s16x8 ), 15 ) );
      vst1q_s32( AR_shp_Q28 + i + 4, vshll_n_s16( vget_high_s16( t_s16x8 ), 15 ) );
    }

    for( ; i < MAX_SHAPE_LPC_ORDER; i++ ) {
      AR_shp_Q28[i] = silk_LSHIFT32( AR_shp_Q13[i], 15 );
    }

    silk_short_prediction_create_arch_coef_neon_local( a_Q12_arch, a_Q12, predictLPCOrder );

    for( i = 0; i < length; i++ ) {
        int32x4_t Seed_s32x4, LPC_pred_Q14_s32x4;
        int32x4_t sign_s32x4, tmp1_s32x4, tmp2_s32x4;
        int32x4_t n_AR_Q14_s32x4, n_LF_Q14_s32x4;
        int32x2_t AR_shp_Q28_s32x2;
        int16x4_t r_Q10_s16x4, rr_Q10_s16x4;

        /* Perform common calculations used in all states */

        /* Long-term prediction */
        if( signalType == TYPE_VOICED ) {
            /* Unrolled loop */
            /* Avoids introducing a bias because silk_SMLAWB() always rounds to -inf */
            LTP_pred_Q14 = 2;
            LTP_pred_Q14 = silk_SMLAWB( LTP_pred_Q14, pred_lag_ptr[  0 ], b_Q14[ 0 ] );
            LTP_pred_Q14 = silk_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -1 ], b_Q14[ 1 ] );
            LTP_pred_Q14 = silk_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -2 ], b_Q14[ 2 ] );
            LTP_pred_Q14 = silk_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -3 ], b_Q14[ 3 ] );
            LTP_pred_Q14 = silk_SMLAWB( LTP_pred_Q14, pred_lag_ptr[ -4 ], b_Q14[ 4 ] );
            LTP_pred_Q14 = silk_LSHIFT( LTP_pred_Q14, 1 );                          /* Q13 -> Q14 */
            pred_lag_ptr++;
        } else {
            LTP_pred_Q14 = 0;
        }

        /* Long-term shaping */
        if( lag > 0 ) {
            /* Symmetric, packed FIR coefficients */
            n_LTP_Q14 = silk_SMULWB( silk_ADD32( shp_lag_ptr[ 0 ], shp_lag_ptr[ -2 ] ), HarmShapeFIRPacked_Q14 );
            n_LTP_Q14 = silk_SMLAWT( n_LTP_Q14, shp_lag_ptr[ -1 ],                      HarmShapeFIRPacked_Q14 );
            n_LTP_Q14 = silk_SUB_LSHIFT32( LTP_pred_Q14, n_LTP_Q14, 2 );            /* Q12 -> Q14 */
            shp_lag_ptr++;
        } else {
            n_LTP_Q14 = 0;
        }

        /* Generate dither */
        Seed_s32x4 = vld1q_s32( psDelDec->Seed );
        Seed_s32x4 = vreinterpretq_s32_u32( vmlaq_u32( rand_increment_u32x4, vreinterpretq_u32_s32( Seed_s32x4 ), rand_multiplier_u32x4 ) );
        vst1q_s32( psDelDec->Seed, Seed_s32x4 );

        /* Short-term prediction */
        LPC_pred_Q14_s32x4 = silk_noise_shape_quantizer_short_prediction_neon_local(psDelDec->sLPC_Q14[ NSQ_LPC_BUF_LENGTH - 16 + i ], a_Q12_arch, predictLPCOrder);
        LPC_pred_Q14_s32x4 = vshlq_n_s32( LPC_pred_Q14_s32x4, 4 ); /* Q10 -> Q14 */

        /* Noise shape feedback */
        /* Output of lowpass section */
        tmp2_s32x4 = silk_SMLAWB_lane0_neon( vld1q_s32( psDelDec->Diff_Q14 ), vld1q_s32( psDelDec->sAR2_Q14[ 0 ] ), warping_Q16_s32x2 );
        /* Output of allpass section */
        tmp1_s32x4 = vsubq_s32( vld1q_s32( psDelDec->sAR2_Q14[ 1 ] ), tmp2_s32x4 );
        tmp1_s32x4 = silk_SMLAWB_lane0_neon( vld1q_s32( psDelDec->sAR2_Q14[ 0 ] ), tmp1_s32x4, warping_Q16_s32x2 );
        vst1q_s32( psDelDec->sAR2_Q14[ 0 ], tmp2_s32x4 );
        AR_shp_Q28_s32x2 = vld1_s32( AR_shp_Q28 );
        n_AR_Q14_s32x4 = vaddq_s32( vdupq_n_s32( silk_RSHIFT( shapingLPCOrder, 1 ) ), vqdmulhq_lane_s32( tmp2_s32x4, AR_shp_Q28_s32x2, 0 ) );

        /* Loop over allpass sections */
        for( j = 2; j < shapingLPCOrder; j += 2 ) {
            /* Output of allpass section */
            tmp2_s32x4 = vsubq_s32( vld1q_s32( psDelDec->sAR2_Q14[ j + 0 ] ), tmp1_s32x4 );
            tmp2_s32x4 = silk_SMLAWB_lane0_neon( vld1q_s32( psDelDec->sAR2_Q14[ j - 1 ] ), tmp2_s32x4, warping_Q16_s32x2 );
            vst1q_s32( psDelDec->sAR2_Q14[ j - 1 ], tmp1_s32x4 );
            n_AR_Q14_s32x4 = vaddq_s32( n_AR_Q14_s32x4, vqdmulhq_lane_s32( tmp1_s32x4, AR_shp_Q28_s32x2, 1 ) );
            /* Output of allpass section */
            tmp1_s32x4 = vsubq_s32( vld1q_s32( psDelDec->sAR2_Q14[ j + 1 ] ), tmp2_s32x4 );
            tmp1_s32x4 = silk_SMLAWB_lane0_neon( vld1q_s32( psDelDec->sAR2_Q14[ j + 0 ] ), tmp1_s32x4, warping_Q16_s32x2 );
            vst1q_s32( psDelDec->sAR2_Q14[ j + 0 ], tmp2_s32x4 );
            AR_shp_Q28_s32x2 = vld1_s32( &AR_shp_Q28[ j ] );
            n_AR_Q14_s32x4 = vaddq_s32( n_AR_Q14_s32x4, vqdmulhq_lane_s32( tmp2_s32x4, AR_shp_Q28_s32x2, 0 ) );
        }
        vst1q_s32( psDelDec->sAR2_Q14[ shapingLPCOrder - 1 ], tmp1_s32x4 );
        n_AR_Q14_s32x4 = vaddq_s32( n_AR_Q14_s32x4, vqdmulhq_lane_s32( tmp1_s32x4, AR_shp_Q28_s32x2, 1 ) );
        n_AR_Q14_s32x4 = vshlq_n_s32( n_AR_Q14_s32x4, 1 );                                                                                        /* Q11 -> Q12 */
        n_AR_Q14_s32x4 = vaddq_s32( n_AR_Q14_s32x4, vqdmulhq_n_s32( vld1q_s32( psDelDec->LF_AR_Q14 ), silk_LSHIFT32( Tilt_Q14, 16 ) >> 1 ) );     /* Q12 */
        n_AR_Q14_s32x4 = vshlq_n_s32( n_AR_Q14_s32x4, 2 );                                                                                        /* Q12 -> Q14 */
        n_LF_Q14_s32x4 = vqdmulhq_n_s32( vld1q_s32( psDelDec->Shape_Q14[ *smpl_buf_idx ] ), LF_shp_Q29 );                                         /* Q12 */
        n_LF_Q14_s32x4 = vaddq_s32( n_LF_Q14_s32x4, vqdmulhq_n_s32( vld1q_s32( psDelDec->LF_AR_Q14 ), silk_LSHIFT32( LF_shp_Q14 >> 16 , 15 ) ) ); /* Q12 */
        n_LF_Q14_s32x4 = vshlq_n_s32( n_LF_Q14_s32x4, 2 );                                                                                        /* Q12 -> Q14 */

        /* Input minus prediction plus noise feedback                       */
        /* r = x[ i ] - LTP_pred - LPC_pred + n_AR + n_Tilt + n_LF + n_LTP  */
        tmp1_s32x4 = vaddq_s32( n_AR_Q14_s32x4, n_LF_Q14_s32x4 );               /* Q14 */
        tmp2_s32x4 = vaddq_s32( vdupq_n_s32( n_LTP_Q14 ), LPC_pred_Q14_s32x4 ); /* Q13 */
        tmp1_s32x4 = vsubq_s32( tmp2_s32x4, tmp1_s32x4 );                       /* Q13 */
        tmp1_s32x4 = vrshrq_n_s32( tmp1_s32x4, 4 );                             /* Q10 */
        tmp1_s32x4 = vsubq_s32( vdupq_n_s32( x_Q10[ i ] ), tmp1_s32x4 );        /* residual error Q10 */

        /* Flip sign depending on dither */
        sign_s32x4 = vreinterpretq_s32_u32( vcltq_s32( Seed_s32x4, vdupq_n_s32( 0 ) ) );
        tmp1_s32x4 = veorq_s32( tmp1_s32x4, sign_s32x4 );
        tmp1_s32x4 = vsubq_s32( tmp1_s32x4, sign_s32x4 );
        tmp1_s32x4 = vmaxq_s32( tmp1_s32x4, vdupq_n_s32( -( 31 << 10 ) ) );
        tmp1_s32x4 = vminq_s32( tmp1_s32x4, vdupq_n_s32( 30 << 10 ) );
        r_Q10_s16x4 = vmovn_s32( tmp1_s32x4 );

        /* Find two quantization level candidates and measure their rate-distortion */
        {
            int16x4_t q1_Q10_s16x4 = vsub_s16( r_Q10_s16x4, vdup_n_s16( offset_Q10 ) );
            int16x4_t q1_Q0_s16x4 = vshr_n_s16( q1_Q10_s16x4, 10 );
            int16x4_t q2_Q10_s16x4;
            int32x4_t rd1_Q10_s32x4, rd2_Q10_s32x4;
            uint32x4_t t_u32x4;

            if( Lambda_Q10 > 2048 ) {
                /* For aggressive RDO, the bias becomes more than one pulse. */
                const int rdo_offset = Lambda_Q10/2 - 512;
                const uint16x4_t greaterThanRdo = vcgt_s16( q1_Q10_s16x4, vdup_n_s16( rdo_offset ) );
                const uint16x4_t lessThanMinusRdo = vclt_s16( q1_Q10_s16x4, vdup_n_s16( -rdo_offset ) );
                /* If Lambda_Q10 > 32767, then q1_Q0, q1_Q10 and q2_Q10 must change to 32-bit. */
                silk_assert( Lambda_Q10 <= 32767 );

                q1_Q0_s16x4 = vreinterpret_s16_u16( vclt_s16( q1_Q10_s16x4, vdup_n_s16( 0 ) ) );
                q1_Q0_s16x4 = vbsl_s16( greaterThanRdo, vsub_s16( q1_Q10_s16x4, vdup_n_s16( rdo_offset ) ), q1_Q0_s16x4 );
                q1_Q0_s16x4 = vbsl_s16( lessThanMinusRdo, vadd_s16( q1_Q10_s16x4, vdup_n_s16( rdo_offset ) ), q1_Q0_s16x4 );
                q1_Q0_s16x4 = vshr_n_s16( q1_Q0_s16x4, 10 );
            }
            {
                const uint16x4_t equal0_u16x4 = vceq_s16( q1_Q0_s16x4, vdup_n_s16( 0 ) );
                const uint16x4_t equalMinus1_u16x4 = vceq_s16( q1_Q0_s16x4, vdup_n_s16( -1 ) );
                const uint16x4_t lessThanMinus1_u16x4 = vclt_s16( q1_Q0_s16x4, vdup_n_s16( -1 ) );
                int16x4_t tmp1_s16x4, tmp2_s16x4;

                q1_Q10_s16x4 = vshl_n_s16( q1_Q0_s16x4, 10 );
                tmp1_s16x4 = vadd_s16( q1_Q10_s16x4, vdup_n_s16( offset_Q10 - QUANT_LEVEL_ADJUST_Q10 ) );
                q1_Q10_s16x4 = vadd_s16( q1_Q10_s16x4, vdup_n_s16( offset_Q10 + QUANT_LEVEL_ADJUST_Q10 ) );
                q1_Q10_s16x4 = vbsl_s16( lessThanMinus1_u16x4, q1_Q10_s16x4, tmp1_s16x4 );
                q1_Q10_s16x4 = vbsl_s16( equal0_u16x4, vdup_n_s16( offset_Q10 ), q1_Q10_s16x4 );
                q1_Q10_s16x4 = vbsl_s16( equalMinus1_u16x4, vdup_n_s16( offset_Q10 - ( 1024 - QUANT_LEVEL_ADJUST_Q10 ) ), q1_Q10_s16x4 );
                q2_Q10_s16x4 = vadd_s16( q1_Q10_s16x4, vdup_n_s16( 1024 ) );
                q2_Q10_s16x4 = vbsl_s16( equal0_u16x4, vdup_n_s16( offset_Q10 + 1024 - QUANT_LEVEL_ADJUST_Q10 ), q2_Q10_s16x4 );
                q2_Q10_s16x4 = vbsl_s16( equalMinus1_u16x4, vdup_n_s16( offset_Q10 ), q2_Q10_s16x4 );
                tmp1_s16x4 = q1_Q10_s16x4;
                tmp2_s16x4 = q2_Q10_s16x4;
                tmp1_s16x4 = vbsl_s16( vorr_u16( equalMinus1_u16x4, lessThanMinus1_u16x4 ), vneg_s16( tmp1_s16x4 ), tmp1_s16x4 );
                tmp2_s16x4 = vbsl_s16( lessThanMinus1_u16x4, vneg_s16( tmp2_s16x4 ), tmp2_s16x4 );
                rd1_Q10_s32x4 = vmull_s16( tmp1_s16x4, vdup_n_s16( Lambda_Q10 ) );
                rd2_Q10_s32x4 = vmull_s16( tmp2_s16x4, vdup_n_s16( Lambda_Q10 ) );
            }

            rr_Q10_s16x4 = vsub_s16( r_Q10_s16x4, q1_Q10_s16x4 );
            rd1_Q10_s32x4 = vmlal_s16( rd1_Q10_s32x4, rr_Q10_s16x4, rr_Q10_s16x4 );
            rd1_Q10_s32x4 = vshrq_n_s32( rd1_Q10_s32x4, 10 );

            rr_Q10_s16x4 = vsub_s16( r_Q10_s16x4, q2_Q10_s16x4 );
            rd2_Q10_s32x4 = vmlal_s16( rd2_Q10_s32x4, rr_Q10_s16x4, rr_Q10_s16x4 );
            rd2_Q10_s32x4 = vshrq_n_s32( rd2_Q10_s32x4, 10 );

            tmp2_s32x4 = vld1q_s32( psDelDec->RD_Q10 );
            tmp1_s32x4 = vaddq_s32( tmp2_s32x4, vminq_s32( rd1_Q10_s32x4, rd2_Q10_s32x4 ) );
            tmp2_s32x4 = vaddq_s32( tmp2_s32x4, vmaxq_s32( rd1_Q10_s32x4, rd2_Q10_s32x4 ) );
            vst1q_s32( psSampleState[ 0 ].RD_Q10, tmp1_s32x4 );
            vst1q_s32( psSampleState[ 1 ].RD_Q10, tmp2_s32x4 );
            t_u32x4 = vcltq_s32( rd1_Q10_s32x4, rd2_Q10_s32x4 );
            tmp1_s32x4 = vbslq_s32( t_u32x4, vmovl_s16( q1_Q10_s16x4 ), vmovl_s16( q2_Q10_s16x4 ) );
            tmp2_s32x4 = vbslq_s32( t_u32x4, vmovl_s16( q2_Q10_s16x4 ), vmovl_s16( q1_Q10_s16x4 ) );
            vst1q_s32( psSampleState[ 0 ].Q_Q10, tmp1_s32x4 );
            vst1q_s32( psSampleState[ 1 ].Q_Q10, tmp2_s32x4 );
        }

        {
            /* Update states for best quantization */
            int32x4_t exc_Q14_s32x4, LPC_exc_Q14_s32x4, xq_Q14_s32x4, sLF_AR_shp_Q14_s32x4;

            /* Quantized excitation */
            exc_Q14_s32x4 = vshlq_n_s32( tmp1_s32x4, 4 );
            exc_Q14_s32x4 = veorq_s32( exc_Q14_s32x4, sign_s32x4 );
            exc_Q14_s32x4 = vsubq_s32( exc_Q14_s32x4, sign_s32x4 );

            /* Add predictions */
            LPC_exc_Q14_s32x4 = vaddq_s32( exc_Q14_s32x4, vdupq_n_s32( LTP_pred_Q14 ) );
            xq_Q14_s32x4      = vaddq_s32( LPC_exc_Q14_s32x4, LPC_pred_Q14_s32x4 );

            /* Update states */
            tmp1_s32x4 = vsubq_s32( xq_Q14_s32x4, vshlq_n_s32( vdupq_n_s32( x_Q10[ i ] ), 4 ) );
            vst1q_s32( psSampleState[ 0 ].Diff_Q14, tmp1_s32x4 );
            sLF_AR_shp_Q14_s32x4 = vsubq_s32( tmp1_s32x4, n_AR_Q14_s32x4 );
            vst1q_s32( psSampleState[ 0 ].sLTP_shp_Q14, vsubq_s32( sLF_AR_shp_Q14_s32x4, n_LF_Q14_s32x4 ) );
            vst1q_s32( psSampleState[ 0 ].LF_AR_Q14, sLF_AR_shp_Q14_s32x4 );
            vst1q_s32( psSampleState[ 0 ].LPC_exc_Q14, LPC_exc_Q14_s32x4 );
            vst1q_s32( psSampleState[ 0 ].xq_Q14, xq_Q14_s32x4 );

            /* Quantized excitation */
            exc_Q14_s32x4 = vshlq_n_s32( tmp2_s32x4, 4 );
            exc_Q14_s32x4 = veorq_s32( exc_Q14_s32x4, sign_s32x4 );
            exc_Q14_s32x4 = vsubq_s32( exc_Q14_s32x4, sign_s32x4 );

            /* Add predictions */
            LPC_exc_Q14_s32x4 = vaddq_s32( exc_Q14_s32x4, vdupq_n_s32( LTP_pred_Q14 ) );
            xq_Q14_s32x4      = vaddq_s32( LPC_exc_Q14_s32x4, LPC_pred_Q14_s32x4 );

            /* Update states */
            tmp1_s32x4 = vsubq_s32( xq_Q14_s32x4, vshlq_n_s32( vdupq_n_s32( x_Q10[ i ] ), 4 ) );
            vst1q_s32( psSampleState[ 1 ].Diff_Q14, tmp1_s32x4 );
            sLF_AR_shp_Q14_s32x4 = vsubq_s32( tmp1_s32x4, n_AR_Q14_s32x4 );
            vst1q_s32( psSampleState[ 1 ].sLTP_shp_Q14, vsubq_s32( sLF_AR_shp_Q14_s32x4, n_LF_Q14_s32x4 ) );
            vst1q_s32( psSampleState[ 1 ].LF_AR_Q14, sLF_AR_shp_Q14_s32x4 );
            vst1q_s32( psSampleState[ 1 ].LPC_exc_Q14, LPC_exc_Q14_s32x4 );
            vst1q_s32( psSampleState[ 1 ].xq_Q14, xq_Q14_s32x4 );
        }

        *smpl_buf_idx = *smpl_buf_idx ? ( *smpl_buf_idx - 1 ) : ( DECISION_DELAY - 1);
        last_smple_idx = *smpl_buf_idx + decisionDelay + DECISION_DELAY;
        if( last_smple_idx >= DECISION_DELAY ) last_smple_idx -= DECISION_DELAY;
        if( last_smple_idx >= DECISION_DELAY ) last_smple_idx -= DECISION_DELAY;

        /* Find winner */
        RDmin_Q10 = psSampleState[ 0 ].RD_Q10[ 0 ];
        Winner_ind = 0;
        for( k = 1; k < nStatesDelayedDecision; k++ ) {
            if( psSampleState[ 0 ].RD_Q10[ k ] < RDmin_Q10 ) {
                RDmin_Q10 = psSampleState[ 0 ].RD_Q10[ k ];
                Winner_ind = k;
            }
        }

        /* Increase RD values of expired states */
        {
            uint32x4_t t_u32x4;
            Winner_rand_state = psDelDec->RandState[ last_smple_idx ][ Winner_ind ];
            t_u32x4 = vceqq_s32( vld1q_s32( psDelDec->RandState[ last_smple_idx ] ), vdupq_n_s32( Winner_rand_state ) );
            t_u32x4 = vmvnq_u32( t_u32x4 );
            t_u32x4 = vshrq_n_u32( t_u32x4, 5 );
            tmp1_s32x4 = vld1q_s32( psSampleState[ 0 ].RD_Q10 );
            tmp2_s32x4 = vld1q_s32( psSampleState[ 1 ].RD_Q10 );
            tmp1_s32x4 = vaddq_s32( tmp1_s32x4, vreinterpretq_s32_u32( t_u32x4 ) );
            tmp2_s32x4 = vaddq_s32( tmp2_s32x4, vreinterpretq_s32_u32( t_u32x4 ) );
            vst1q_s32( psSampleState[ 0 ].RD_Q10, tmp1_s32x4 );
            vst1q_s32( psSampleState[ 1 ].RD_Q10, tmp2_s32x4 );

            /* Find worst in first set and best in second set */
            RDmax_Q10 = psSampleState[ 0 ].RD_Q10[ 0 ];
            RDmin_Q10 = psSampleState[ 1 ].RD_Q10[ 0 ];
            RDmax_ind = 0;
            RDmin_ind = 0;
            for( k = 1; k < nStatesDelayedDecision; k++ ) {
                /* find worst in first set */
                if( psSampleState[ 0 ].RD_Q10[ k ] > RDmax_Q10 ) {
                    RDmax_Q10 = psSampleState[ 0 ].RD_Q10[ k ];
                    RDmax_ind = k;
                }
                /* find best in second set */
                if( psSampleState[ 1 ].RD_Q10[ k ] < RDmin_Q10 ) {
                    RDmin_Q10 = psSampleState[ 1 ].RD_Q10[ k ];
                    RDmin_ind = k;
                }
            }
        }

        /* Replace a state if best from second set outperforms worst in first set */
        if( RDmin_Q10 < RDmax_Q10 ) {
            opus_int32 (*ptr)[NEON_MAX_DEL_DEC_STATES] = psDelDec->RandState;
            const int numOthers = (int)( ( sizeof( NSQ_del_decs_struct ) - sizeof( ( (NSQ_del_decs_struct *)0 )->sLPC_Q14 ) )
                / ( NEON_MAX_DEL_DEC_STATES * sizeof( opus_int32 ) ) );
            /* Only ( predictLPCOrder - 1 ) of sLPC_Q14 buffer need to be updated, though the first several     */
            /* useless sLPC_Q14[] will be different comparing with C when predictLPCOrder < NSQ_LPC_BUF_LENGTH. */
            /* Here just update constant ( NSQ_LPC_BUF_LENGTH - 1 ) for simplicity.                             */
            for( j = i + 1; j < i + NSQ_LPC_BUF_LENGTH; j++ ) {
                psDelDec->sLPC_Q14[ j ][ RDmax_ind ] = psDelDec->sLPC_Q14[ j ][ RDmin_ind ];
            }
            for( j = 0; j < numOthers; j++ ) {
                ptr[ j ][ RDmax_ind ] = ptr[ j ][ RDmin_ind ];
            }

            psSampleState[ 0 ].Q_Q10[ RDmax_ind ] = psSampleState[ 1 ].Q_Q10[ RDmin_ind ];
            psSampleState[ 0 ].RD_Q10[ RDmax_ind ] = psSampleState[ 1 ].RD_Q10[ RDmin_ind ];
            psSampleState[ 0 ].xq_Q14[ RDmax_ind ] = psSampleState[ 1 ].xq_Q14[ RDmin_ind ];
            psSampleState[ 0 ].LF_AR_Q14[ RDmax_ind ] = psSampleState[ 1 ].LF_AR_Q14[ RDmin_ind ];
            psSampleState[ 0 ].Diff_Q14[ RDmax_ind ] = psSampleState[ 1 ].Diff_Q14[ RDmin_ind ];
            psSampleState[ 0 ].sLTP_shp_Q14[ RDmax_ind ] = psSampleState[ 1 ].sLTP_shp_Q14[ RDmin_ind ];
            psSampleState[ 0 ].LPC_exc_Q14[ RDmax_ind ] = psSampleState[ 1 ].LPC_exc_Q14[ RDmin_ind ];
        }

        /* Write samples from winner to output and long-term filter states */
        if( subfr > 0 || i >= decisionDelay ) {
            pulses[  i - decisionDelay ] = (opus_int8)silk_RSHIFT_ROUND( psDelDec->Q_Q10[ last_smple_idx ][ Winner_ind ], 10 );
            xq[ i - decisionDelay ] = (opus_int16)silk_SAT16( silk_RSHIFT_ROUND(
                silk_SMULWW( psDelDec->Xq_Q14[ last_smple_idx ][ Winner_ind ], delayedGain_Q10[ last_smple_idx ] ), 8 ) );
            NSQ->sLTP_shp_Q14[ NSQ->sLTP_shp_buf_idx - decisionDelay ] = psDelDec->Shape_Q14[ last_smple_idx ][ Winner_ind ];
            sLTP_Q15[          NSQ->sLTP_buf_idx     - decisionDelay ] = psDelDec->Pred_Q15[  last_smple_idx ][ Winner_ind ];
        }
        NSQ->sLTP_shp_buf_idx++;
        NSQ->sLTP_buf_idx++;

        /* Update states */
        vst1q_s32( psDelDec->LF_AR_Q14, vld1q_s32( psSampleState[ 0 ].LF_AR_Q14 ) );
        vst1q_s32( psDelDec->Diff_Q14, vld1q_s32( psSampleState[ 0 ].Diff_Q14 ) );
        vst1q_s32( psDelDec->sLPC_Q14[ NSQ_LPC_BUF_LENGTH + i ], vld1q_s32( psSampleState[ 0 ].xq_Q14 ) );
        vst1q_s32( psDelDec->Xq_Q14[ *smpl_buf_idx ], vld1q_s32( psSampleState[ 0 ].xq_Q14 ) );
        tmp1_s32x4 = vld1q_s32( psSampleState[ 0 ].Q_Q10 );
        vst1q_s32( psDelDec->Q_Q10[ *smpl_buf_idx ], tmp1_s32x4 );
        vst1q_s32( psDelDec->Pred_Q15[ *smpl_buf_idx ], vshlq_n_s32( vld1q_s32( psSampleState[ 0 ].LPC_exc_Q14 ), 1 ) );
        vst1q_s32( psDelDec->Shape_Q14[ *smpl_buf_idx ], vld1q_s32( psSampleState[ 0 ].sLTP_shp_Q14 ) );
        tmp1_s32x4 = vrshrq_n_s32( tmp1_s32x4, 10 );
        tmp1_s32x4 = vaddq_s32( vld1q_s32( psDelDec->Seed ), tmp1_s32x4 );
        vst1q_s32( psDelDec->Seed, tmp1_s32x4 );
        vst1q_s32( psDelDec->RandState[ *smpl_buf_idx ], tmp1_s32x4 );
        vst1q_s32( psDelDec->RD_Q10, vld1q_s32( psSampleState[ 0 ].RD_Q10 ) );
        delayedGain_Q10[ *smpl_buf_idx ] = Gain_Q10;
    }
    /* Update LPC states */
    silk_memcpy( psDelDec->sLPC_Q14[ 0 ], psDelDec->sLPC_Q14[ length ], NEON_MAX_DEL_DEC_STATES * NSQ_LPC_BUF_LENGTH * sizeof( opus_int32 ) );

    RESTORE_STACK;
}

static OPUS_INLINE void silk_SMULWB_8_neon(
    const opus_int16 *a,
    const int32x2_t  b,
    opus_int32       *o
)
{
    const int16x8_t a_s16x8 = vld1q_s16( a );
    int32x4_t o0_s32x4, o1_s32x4;

    o0_s32x4 = vshll_n_s16( vget_low_s16( a_s16x8 ), 15 );
    o1_s32x4 = vshll_n_s16( vget_high_s16( a_s16x8 ), 15 );
    o0_s32x4 = vqdmulhq_lane_s32( o0_s32x4, b, 0 );
    o1_s32x4 = vqdmulhq_lane_s32( o1_s32x4, b, 0 );
    vst1q_s32( o, o0_s32x4 );
    vst1q_s32( o + 4, o1_s32x4 );
}

/* Only works when ( b >= -65536 ) && ( b < 65536 ). */
static OPUS_INLINE void silk_SMULWW_small_b_4_neon(
    opus_int32       *a,
    const int32x2_t  b_s32x2)
{
    int32x4_t o_s32x4;

    o_s32x4 = vld1q_s32( a );
    o_s32x4 = vqdmulhq_lane_s32( o_s32x4, b_s32x2, 0 );
    vst1q_s32( a, o_s32x4 );
}

/* Only works when ( b >= -65536 ) && ( b < 65536 ). */
static OPUS_INLINE void silk_SMULWW_small_b_8_neon(
    opus_int32       *a,
    const int32x2_t  b_s32x2
)
{
    int32x4_t o0_s32x4, o1_s32x4;

    o0_s32x4 = vld1q_s32( a );
    o1_s32x4 = vld1q_s32( a + 4 );
    o0_s32x4 = vqdmulhq_lane_s32( o0_s32x4, b_s32x2, 0 );
    o1_s32x4 = vqdmulhq_lane_s32( o1_s32x4, b_s32x2, 0 );
    vst1q_s32( a, o0_s32x4 );
    vst1q_s32( a + 4, o1_s32x4 );
}

static OPUS_INLINE void silk_SMULWW_4_neon(
    opus_int32       *a,
    const int32x2_t  b_s32x2)
{
    int32x4_t a_s32x4, o_s32x4;

    a_s32x4 = vld1q_s32( a );
    o_s32x4 = vqdmulhq_lane_s32( a_s32x4, b_s32x2, 0 );
    o_s32x4 = vmlaq_lane_s32( o_s32x4, a_s32x4, b_s32x2, 1 );
    vst1q_s32( a, o_s32x4 );
}

static OPUS_INLINE void silk_SMULWW_8_neon(
    opus_int32       *a,
    const int32x2_t  b_s32x2
)
{
    int32x4_t a0_s32x4, a1_s32x4, o0_s32x4, o1_s32x4;

    a0_s32x4 = vld1q_s32( a );
    a1_s32x4 = vld1q_s32( a + 4 );
    o0_s32x4 = vqdmulhq_lane_s32( a0_s32x4, b_s32x2, 0 );
    o1_s32x4 = vqdmulhq_lane_s32( a1_s32x4, b_s32x2, 0 );
    o0_s32x4 = vmlaq_lane_s32( o0_s32x4, a0_s32x4, b_s32x2, 1 );
    o1_s32x4 = vmlaq_lane_s32( o1_s32x4, a1_s32x4, b_s32x2, 1 );
    vst1q_s32( a, o0_s32x4 );
    vst1q_s32( a + 4, o1_s32x4 );
}

static OPUS_INLINE void silk_SMULWW_loop_neon(
    const opus_int16 *a,
    const opus_int32 b,
    opus_int32       *o,
    const opus_int   loop_num
)
{
    opus_int i;
    int32x2_t b_s32x2;

    b_s32x2 = vdup_n_s32( b );
    for( i = 0; i < loop_num - 7; i += 8 ) {
        silk_SMULWB_8_neon( a + i, b_s32x2, o + i );
    }
    for( ; i < loop_num; i++ ) {
        o[ i ] = silk_SMULWW( a[ i ], b );
    }
}

static OPUS_INLINE void silk_nsq_del_dec_scale_states_neon(
    const silk_encoder_state *psEncC,               /* I    Encoder State                       */
    silk_nsq_state      *NSQ,                       /* I/O  NSQ state                           */
    NSQ_del_decs_struct psDelDec[],                 /* I/O  Delayed decision states             */
    const opus_int16    x16[],                      /* I    Input                               */
    opus_int32          x_sc_Q10[],                 /* O    Input scaled with 1/Gain in Q10     */
    const opus_int16    sLTP[],                     /* I    Re-whitened LTP state in Q0         */
    opus_int32          sLTP_Q15[],                 /* O    LTP state matching scaled input     */
    opus_int            subfr,                      /* I    Subframe number                     */
    const opus_int      LTP_scale_Q14,              /* I    LTP state scaling                   */
    const opus_int32    Gains_Q16[ MAX_NB_SUBFR ],  /* I                                        */
    const opus_int      pitchL[ MAX_NB_SUBFR ],     /* I    Pitch lag                           */
    const opus_int      signal_type,                /* I    Signal type                         */
    const opus_int      decisionDelay               /* I    Decision delay                      */
)
{
    opus_int            i, lag;
    opus_int32          gain_adj_Q16, inv_gain_Q31, inv_gain_Q26;

    lag          = pitchL[ subfr ];
    inv_gain_Q31 = silk_INVERSE32_varQ( silk_max( Gains_Q16[ subfr ], 1 ), 47 );
    silk_assert( inv_gain_Q31 != 0 );

    /* Scale input */
    inv_gain_Q26 = silk_RSHIFT_ROUND( inv_gain_Q31, 5 );
    silk_SMULWW_loop_neon( x16, inv_gain_Q26, x_sc_Q10, psEncC->subfr_length );

    /* After rewhitening the LTP state is un-scaled, so scale with inv_gain_Q16 */
    if( NSQ->rewhite_flag ) {
        if( subfr == 0 ) {
            /* Do LTP downscaling */
            inv_gain_Q31 = silk_LSHIFT( silk_SMULWB( inv_gain_Q31, LTP_scale_Q14 ), 2 );
        }
        silk_SMULWW_loop_neon( sLTP + NSQ->sLTP_buf_idx - lag - LTP_ORDER / 2, inv_gain_Q31, sLTP_Q15 + NSQ->sLTP_buf_idx - lag - LTP_ORDER / 2, lag + LTP_ORDER / 2 );
    }

    /* Adjust for changing gain */
    if( Gains_Q16[ subfr ] != NSQ->prev_gain_Q16 ) {
        int32x2_t gain_adj_Q16_s32x2;
        gain_adj_Q16 = silk_DIV32_varQ( NSQ->prev_gain_Q16, Gains_Q16[ subfr ], 16 );

        /* Scale long-term shaping state */
        if( ( gain_adj_Q16 >= -65536 ) && ( gain_adj_Q16 < 65536 ) ) {
            gain_adj_Q16_s32x2 = vdup_n_s32( silk_LSHIFT32( gain_adj_Q16, 15 ) );
            for( i = NSQ->sLTP_shp_buf_idx - psEncC->ltp_mem_length; i < NSQ->sLTP_shp_buf_idx - 7; i += 8 ) {
                silk_SMULWW_small_b_8_neon( NSQ->sLTP_shp_Q14 + i, gain_adj_Q16_s32x2 );
            }
            for( ; i < NSQ->sLTP_shp_buf_idx; i++ ) {
                NSQ->sLTP_shp_Q14[ i ] = silk_SMULWW( gain_adj_Q16, NSQ->sLTP_shp_Q14[ i ] );
            }

            /* Scale long-term prediction state */
            if( signal_type == TYPE_VOICED && NSQ->rewhite_flag == 0 ) {
                for( i = NSQ->sLTP_buf_idx - lag - LTP_ORDER / 2; i < NSQ->sLTP_buf_idx - decisionDelay - 7; i += 8 ) {
                    silk_SMULWW_small_b_8_neon( sLTP_Q15 + i, gain_adj_Q16_s32x2 );
                }
                for( ; i < NSQ->sLTP_buf_idx - decisionDelay; i++ ) {
                    sLTP_Q15[ i ] = silk_SMULWW( gain_adj_Q16, sLTP_Q15[ i ] );
                }
            }

            /* Scale scalar states */
            silk_SMULWW_small_b_4_neon( psDelDec->LF_AR_Q14, gain_adj_Q16_s32x2 );
            silk_SMULWW_small_b_4_neon( psDelDec->Diff_Q14,  gain_adj_Q16_s32x2 );

            /* Scale short-term prediction and shaping states */
            for( i = 0; i < NSQ_LPC_BUF_LENGTH; i++ ) {
                silk_SMULWW_small_b_4_neon( psDelDec->sLPC_Q14[ i ], gain_adj_Q16_s32x2 );
            }

            for( i = 0; i < MAX_SHAPE_LPC_ORDER; i++ ) {
                silk_SMULWW_small_b_4_neon( psDelDec->sAR2_Q14[ i ], gain_adj_Q16_s32x2 );
            }

            for( i = 0; i < DECISION_DELAY; i++ ) {
                silk_SMULWW_small_b_4_neon( psDelDec->Pred_Q15[  i ], gain_adj_Q16_s32x2 );
                silk_SMULWW_small_b_4_neon( psDelDec->Shape_Q14[ i ], gain_adj_Q16_s32x2 );
            }
        } else {
            gain_adj_Q16_s32x2 = vdup_n_s32( silk_LSHIFT32( gain_adj_Q16 & 0x0000FFFF, 15 ) );
            gain_adj_Q16_s32x2 = vset_lane_s32( gain_adj_Q16 >> 16, gain_adj_Q16_s32x2, 1 );
            for( i = NSQ->sLTP_shp_buf_idx - psEncC->ltp_mem_length; i < NSQ->sLTP_shp_buf_idx - 7; i += 8 ) {
                silk_SMULWW_8_neon( NSQ->sLTP_shp_Q14 + i, gain_adj_Q16_s32x2 );
            }
            for( ; i < NSQ->sLTP_shp_buf_idx; i++ ) {
                NSQ->sLTP_shp_Q14[ i ] = silk_SMULWW( gain_adj_Q16, NSQ->sLTP_shp_Q14[ i ] );
            }

            /* Scale long-term prediction state */
            if( signal_type == TYPE_VOICED && NSQ->rewhite_flag == 0 ) {
                for( i = NSQ->sLTP_buf_idx - lag - LTP_ORDER / 2; i < NSQ->sLTP_buf_idx - decisionDelay - 7; i += 8 ) {
                    silk_SMULWW_8_neon( sLTP_Q15 + i, gain_adj_Q16_s32x2 );
                }
                for( ; i < NSQ->sLTP_buf_idx - decisionDelay; i++ ) {
                    sLTP_Q15[ i ] = silk_SMULWW( gain_adj_Q16, sLTP_Q15[ i ] );
                }
            }

            /* Scale scalar states */
            silk_SMULWW_4_neon( psDelDec->LF_AR_Q14, gain_adj_Q16_s32x2 );
            silk_SMULWW_4_neon( psDelDec->Diff_Q14,  gain_adj_Q16_s32x2 );

            /* Scale short-term prediction and shaping states */
            for( i = 0; i < NSQ_LPC_BUF_LENGTH; i++ ) {
                silk_SMULWW_4_neon( psDelDec->sLPC_Q14[ i ], gain_adj_Q16_s32x2 );
            }

            for( i = 0; i < MAX_SHAPE_LPC_ORDER; i++ ) {
                silk_SMULWW_4_neon( psDelDec->sAR2_Q14[ i ], gain_adj_Q16_s32x2 );
            }

            for( i = 0; i < DECISION_DELAY; i++ ) {
                silk_SMULWW_4_neon( psDelDec->Pred_Q15[  i ], gain_adj_Q16_s32x2 );
                silk_SMULWW_4_neon( psDelDec->Shape_Q14[ i ], gain_adj_Q16_s32x2 );
            }
        }

        /* Save inverse gain */
        NSQ->prev_gain_Q16 = Gains_Q16[ subfr ];
    }
}