libopus/celt/vq.c - nest-cam/4320010/libopus - Git at Google

 /* Copyright (c) 2007-2008 CSIRO
    Copyright (c) 2007-2009 Xiph.Org Foundation
    Written by Jean-Marc Valin */
 /*
    Redistribution and use in source and binary forms, with or without
    modification, are permitted provided that the following conditions
    are met:

    - Redistributions of source code must retain the above copyright
    notice, this list of conditions and the following disclaimer.

    - Redistributions in binary form must reproduce the above copyright
    notice, this list of conditions and the following disclaimer in the
    documentation and/or other materials provided with the distribution.

    THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
    ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
    LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
    A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
    OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
    EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
    PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
    PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
    LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
    NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
    SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

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

 #include "mathops.h"
 #include "cwrs.h"
 #include "vq.h"
 #include "arch.h"
 #include "os_support.h"
 #include "bands.h"
 #include "rate.h"
 #include "pitch.h"

 #ifndef OVERRIDE_vq_exp_rotation1
 static void exp_rotation1(celt_norm *X, int len, int stride, opus_val16 c, opus_val16 s)
 {
    int i;
    opus_val16 ms;
    celt_norm *Xptr;
    Xptr = X;
    ms = NEG16(s);
    for (i=0;i<len-stride;i++)
    {
       celt_norm x1, x2;
       x1 = Xptr[0];
       x2 = Xptr[stride];
       Xptr[stride] = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x2),  s, x1), 15));
       *Xptr++      = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x1), ms, x2), 15));
    }
    Xptr = &X[len-2*stride-1];
    for (i=len-2*stride-1;i>=0;i--)
    {
       celt_norm x1, x2;
       x1 = Xptr[0];
       x2 = Xptr[stride];
       Xptr[stride] = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x2),  s, x1), 15));
       *Xptr--      = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x1), ms, x2), 15));
    }
 }
 #endif /* OVERRIDE_vq_exp_rotation1 */

 static void exp_rotation(celt_norm *X, int len, int dir, int stride, int K, int spread)
 {
    static const int SPREAD_FACTOR[3]={15,10,5};
    int i;
    opus_val16 c, s;
    opus_val16 gain, theta;
    int stride2=0;
    int factor;

    if (2*K>=len || spread==SPREAD_NONE)
       return;
    factor = SPREAD_FACTOR[spread-1];

    gain = celt_div((opus_val32)MULT16_16(Q15_ONE,len),(opus_val32)(len+factor*K));
    theta = HALF16(MULT16_16_Q15(gain,gain));

    c = celt_cos_norm(EXTEND32(theta));
    s = celt_cos_norm(EXTEND32(SUB16(Q15ONE,theta))); /*  sin(theta) */

    if (len>=8*stride)
    {
       stride2 = 1;
       /* This is just a simple (equivalent) way of computing sqrt(len/stride) with rounding.
          It's basically incrementing long as (stride2+0.5)^2 < len/stride. */
       while ((stride2*stride2+stride2)*stride + (stride>>2) < len)
          stride2++;
    }
    /*NOTE: As a minor optimization, we could be passing around log2(B), not B, for both this and for
       extract_collapse_mask().*/
    len = celt_udiv(len, stride);
    for (i=0;i<stride;i++)
    {
       if (dir < 0)
       {
          if (stride2)
             exp_rotation1(X+i*len, len, stride2, s, c);
          exp_rotation1(X+i*len, len, 1, c, s);
       } else {
          exp_rotation1(X+i*len, len, 1, c, -s);
          if (stride2)
             exp_rotation1(X+i*len, len, stride2, s, -c);
       }
    }
 }

 /** Takes the pitch vector and the decoded residual vector, computes the gain
     that will give ||p+g*y||=1 and mixes the residual with the pitch. */
 static void normalise_residual(int * OPUS_RESTRICT iy, celt_norm * OPUS_RESTRICT X,
       int N, opus_val32 Ryy, opus_val16 gain)
 {
    int i;
 #ifdef FIXED_POINT
    int k;
 #endif
    opus_val32 t;
    opus_val16 g;

 #ifdef FIXED_POINT
    k = celt_ilog2(Ryy)>>1;
 #endif
    t = VSHR32(Ryy, 2*(k-7));
    g = MULT16_16_P15(celt_rsqrt_norm(t),gain);

    i=0;
    do
       X[i] = EXTRACT16(PSHR32(MULT16_16(g, iy[i]), k+1));
    while (++i < N);
 }

 static unsigned extract_collapse_mask(int *iy, int N, int B)
 {
    unsigned collapse_mask;
    int N0;
    int i;
    if (B<=1)
       return 1;
    /*NOTE: As a minor optimization, we could be passing around log2(B), not B, for both this and for
       exp_rotation().*/
    N0 = celt_udiv(N, B);
    collapse_mask = 0;
    i=0; do {
       int j;
       unsigned tmp=0;
       j=0; do {
          tmp |= iy[i*N0+j];
       } while (++j<N0);
       collapse_mask |= (tmp!=0)<<i;
    } while (++i<B);
    return collapse_mask;
 }

 unsigned alg_quant(celt_norm *X, int N, int K, int spread, int B, ec_enc *enc
 #ifdef RESYNTH
    , opus_val16 gain
 #endif
    )
 {
    VARDECL(celt_norm, y);
    VARDECL(int, iy);
    VARDECL(opus_val16, signx);
    int i, j;
    opus_val16 s;
    int pulsesLeft;
    opus_val32 sum;
    opus_val32 xy;
    opus_val16 yy;
    unsigned collapse_mask;
    SAVE_STACK;

    celt_assert2(K>0, "alg_quant() needs at least one pulse");
    celt_assert2(N>1, "alg_quant() needs at least two dimensions");

    ALLOC(y, N, celt_norm);
    ALLOC(iy, N, int);
    ALLOC(signx, N, opus_val16);

    exp_rotation(X, N, 1, B, K, spread);

    /* Get rid of the sign */
    sum = 0;
    j=0; do {
       if (X[j]>0)
          signx[j]=1;
       else {
          signx[j]=-1;
          X[j]=-X[j];
       }
       iy[j] = 0;
       y[j] = 0;
    } while (++j<N);

    xy = yy = 0;

    pulsesLeft = K;

    /* Do a pre-search by projecting on the pyramid */
    if (K > (N>>1))
    {
       opus_val16 rcp;
       j=0; do {
          sum += X[j];
       }  while (++j<N);

       /* If X is too small, just replace it with a pulse at 0 */
 #ifdef FIXED_POINT
       if (sum <= K)
 #else
       /* Prevents infinities and NaNs from causing too many pulses
          to be allocated. 64 is an approximation of infinity here. */
       if (!(sum > EPSILON && sum < 64))
 #endif
       {
          X[0] = QCONST16(1.f,14);
          j=1; do
             X[j]=0;
          while (++j<N);
          sum = QCONST16(1.f,14);
       }
       rcp = EXTRACT16(MULT16_32_Q16(K-1, celt_rcp(sum)));
       j=0; do {
 #ifdef FIXED_POINT
          /* It's really important to round *towards zero* here */
          iy[j] = MULT16_16_Q15(X[j],rcp);
 #else
          iy[j] = (int)floor(rcp*X[j]);
 #endif
          y[j] = (celt_norm)iy[j];
          yy = MAC16_16(yy, y[j],y[j]);
          xy = MAC16_16(xy, X[j],y[j]);
          y[j] *= 2;
          pulsesLeft -= iy[j];
       }  while (++j<N);
    }
    celt_assert2(pulsesLeft>=1, "Allocated too many pulses in the quick pass");

    /* This should never happen, but just in case it does (e.g. on silence)
       we fill the first bin with pulses. */
 #ifdef FIXED_POINT_DEBUG
    celt_assert2(pulsesLeft<=N+3, "Not enough pulses in the quick pass");
 #endif
    if (pulsesLeft > N+3)
    {
       opus_val16 tmp = (opus_val16)pulsesLeft;
       yy = MAC16_16(yy, tmp, tmp);
       yy = MAC16_16(yy, tmp, y[0]);
       iy[0] += pulsesLeft;
       pulsesLeft=0;
    }

    s = 1;
    for (i=0;i<pulsesLeft;i++)
    {
       int best_id;
       opus_val32 best_num = -VERY_LARGE16;
       opus_val16 best_den = 0;
 #ifdef FIXED_POINT
       int rshift;
 #endif
 #ifdef FIXED_POINT
       rshift = 1+celt_ilog2(K-pulsesLeft+i+1);
 #endif
       best_id = 0;
       /* The squared magnitude term gets added anyway, so we might as well
          add it outside the loop */
       yy = ADD16(yy, 1);
       j=0;
       do {
          opus_val16 Rxy, Ryy;
          /* Temporary sums of the new pulse(s) */
          Rxy = EXTRACT16(SHR32(ADD32(xy, EXTEND32(X[j])),rshift));
          /* We're multiplying y[j] by two so we don't have to do it here */
          Ryy = ADD16(yy, y[j]);

          /* Approximate score: we maximise Rxy/sqrt(Ryy) (we're guaranteed that
             Rxy is positive because the sign is pre-computed) */
          Rxy = MULT16_16_Q15(Rxy,Rxy);
          /* The idea is to check for num/den >= best_num/best_den, but that way
             we can do it without any division */
          /* OPT: Make sure to use conditional moves here */
          if (MULT16_16(best_den, Rxy) > MULT16_16(Ryy, best_num))
          {
             best_den = Ryy;
             best_num = Rxy;
             best_id = j;
          }
       } while (++j<N);

       /* Updating the sums of the new pulse(s) */
       xy = ADD32(xy, EXTEND32(X[best_id]));
       /* We're multiplying y[j] by two so we don't have to do it here */
       yy = ADD16(yy, y[best_id]);

       /* Only now that we've made the final choice, update y/iy */
       /* Multiplying y[j] by 2 so we don't have to do it everywhere else */
       y[best_id] += 2*s;
       iy[best_id]++;
    }

    /* Put the original sign back */
    j=0;
    do {
       X[j] = MULT16_16(signx[j],X[j]);
       if (signx[j] < 0)
          iy[j] = -iy[j];
    } while (++j<N);
    encode_pulses(iy, N, K, enc);

 #ifdef RESYNTH
    normalise_residual(iy, X, N, yy, gain);
    exp_rotation(X, N, -1, B, K, spread);
 #endif

    collapse_mask = extract_collapse_mask(iy, N, B);
    RESTORE_STACK;
    return collapse_mask;
 }

 /** Decode pulse vector and combine the result with the pitch vector to produce
     the final normalised signal in the current band. */
 unsigned alg_unquant(celt_norm *X, int N, int K, int spread, int B,
       ec_dec *dec, opus_val16 gain)
 {
    opus_val32 Ryy;
    unsigned collapse_mask;
    VARDECL(int, iy);
    SAVE_STACK;

    celt_assert2(K>0, "alg_unquant() needs at least one pulse");
    celt_assert2(N>1, "alg_unquant() needs at least two dimensions");
    ALLOC(iy, N, int);
    Ryy = decode_pulses(iy, N, K, dec);
    normalise_residual(iy, X, N, Ryy, gain);
    exp_rotation(X, N, -1, B, K, spread);
    collapse_mask = extract_collapse_mask(iy, N, B);
    RESTORE_STACK;
    return collapse_mask;
 }

 #ifndef OVERRIDE_renormalise_vector
 void renormalise_vector(celt_norm *X, int N, opus_val16 gain, int arch)
 {
    int i;
 #ifdef FIXED_POINT
    int k;
 #endif
    opus_val32 E;
    opus_val16 g;
    opus_val32 t;
    celt_norm *xptr;
    E = EPSILON + celt_inner_prod(X, X, N, arch);
 #ifdef FIXED_POINT
    k = celt_ilog2(E)>>1;
 #endif
    t = VSHR32(E, 2*(k-7));
    g = MULT16_16_P15(celt_rsqrt_norm(t),gain);

    xptr = X;
    for (i=0;i<N;i++)
    {
       *xptr = EXTRACT16(PSHR32(MULT16_16(g, *xptr), k+1));
       xptr++;
    }
    /*return celt_sqrt(E);*/
 }
 #endif /* OVERRIDE_renormalise_vector */

 int stereo_itheta(const celt_norm *X, const celt_norm *Y, int stereo, int N, int arch)
 {
    int i;
    int itheta;
    opus_val16 mid, side;
    opus_val32 Emid, Eside;

    Emid = Eside = EPSILON;
    if (stereo)
    {
       for (i=0;i<N;i++)
       {
          celt_norm m, s;
          m = ADD16(SHR16(X[i],1),SHR16(Y[i],1));
          s = SUB16(SHR16(X[i],1),SHR16(Y[i],1));
          Emid = MAC16_16(Emid, m, m);
          Eside = MAC16_16(Eside, s, s);
       }
    } else {
       Emid += celt_inner_prod(X, X, N, arch);
       Eside += celt_inner_prod(Y, Y, N, arch);
    }
    mid = celt_sqrt(Emid);
    side = celt_sqrt(Eside);
 #ifdef FIXED_POINT
    /* 0.63662 = 2/pi */
    itheta = MULT16_16_Q15(QCONST16(0.63662f,15),celt_atan2p(side, mid));
 #else
    itheta = (int)floor(.5f+16384*0.63662f*atan2(side,mid));
 #endif

    return itheta;
 }
	/* Copyright (c) 2007-2008 CSIRO
	Copyright (c) 2007-2009 Xiph.Org Foundation
	Written by Jean-Marc Valin */
	/*
	Redistribution and use in source and binary forms, with or without
	modification, are permitted provided that the following conditions
	are met:

	- Redistributions of source code must retain the above copyright
	notice, this list of conditions and the following disclaimer.

	- Redistributions in binary form must reproduce the above copyright
	notice, this list of conditions and the following disclaimer in the
	documentation and/or other materials provided with the distribution.

	THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
	OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
	LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
	NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
	SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

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

	#include "mathops.h"
	#include "cwrs.h"
	#include "vq.h"
	#include "arch.h"
	#include "os_support.h"
	#include "bands.h"
	#include "rate.h"
	#include "pitch.h"

	#ifndef OVERRIDE_vq_exp_rotation1
	static void exp_rotation1(celt_norm *X, int len, int stride, opus_val16 c, opus_val16 s)
	{
	int i;
	opus_val16 ms;
	celt_norm *Xptr;
	Xptr = X;
	ms = NEG16(s);
	for (i=0;i<len-stride;i++)
	{
	celt_norm x1, x2;
	x1 = Xptr[0];
	x2 = Xptr[stride];
	Xptr[stride] = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x2), s, x1), 15));
	*Xptr++ = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x1), ms, x2), 15));
	}
	Xptr = &X[len-2*stride-1];
	for (i=len-2*stride-1;i>=0;i--)
	{
	celt_norm x1, x2;
	x1 = Xptr[0];
	x2 = Xptr[stride];
	Xptr[stride] = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x2), s, x1), 15));
	*Xptr-- = EXTRACT16(PSHR32(MAC16_16(MULT16_16(c, x1), ms, x2), 15));
	}
	}
	#endif /* OVERRIDE_vq_exp_rotation1 */

	static void exp_rotation(celt_norm *X, int len, int dir, int stride, int K, int spread)
	{
	static const int SPREAD_FACTOR[3]={15,10,5};
	int i;
	opus_val16 c, s;
	opus_val16 gain, theta;
	int stride2=0;
	int factor;

	if (2*K>=len \|\| spread==SPREAD_NONE)
	return;
	factor = SPREAD_FACTOR[spread-1];

	gain = celt_div((opus_val32)MULT16_16(Q15_ONE,len),(opus_val32)(len+factor*K));
	theta = HALF16(MULT16_16_Q15(gain,gain));

	c = celt_cos_norm(EXTEND32(theta));
	s = celt_cos_norm(EXTEND32(SUB16(Q15ONE,theta))); /* sin(theta) */

	if (len>=8*stride)
	{
	stride2 = 1;
	/* This is just a simple (equivalent) way of computing sqrt(len/stride) with rounding.
	It's basically incrementing long as (stride2+0.5)^2 < len/stride. */
	while ((stride2stride2+stride2)stride + (stride>>2) < len)
	stride2++;
	}
	/*NOTE: As a minor optimization, we could be passing around log2(B), not B, for both this and for
	extract_collapse_mask().*/
	len = celt_udiv(len, stride);
	for (i=0;i<stride;i++)
	{
	if (dir < 0)
	{
	if (stride2)
	exp_rotation1(X+i*len, len, stride2, s, c);
	exp_rotation1(X+i*len, len, 1, c, s);
	} else {
	exp_rotation1(X+i*len, len, 1, c, -s);
	if (stride2)
	exp_rotation1(X+i*len, len, stride2, s, -c);
	}
	}
	}

	/** Takes the pitch vector and the decoded residual vector, computes the gain
	that will give \|\|p+gy\|\|=1 and mixes the residual with the pitch. /
	static void normalise_residual(int * OPUS_RESTRICT iy, celt_norm * OPUS_RESTRICT X,
	int N, opus_val32 Ryy, opus_val16 gain)
	{
	int i;
	#ifdef FIXED_POINT
	int k;
	#endif
	opus_val32 t;
	opus_val16 g;

	#ifdef FIXED_POINT
	k = celt_ilog2(Ryy)>>1;
	#endif
	t = VSHR32(Ryy, 2*(k-7));
	g = MULT16_16_P15(celt_rsqrt_norm(t),gain);

	i=0;
	do
	X[i] = EXTRACT16(PSHR32(MULT16_16(g, iy[i]), k+1));
	while (++i < N);
	}

	static unsigned extract_collapse_mask(int *iy, int N, int B)
	{
	unsigned collapse_mask;
	int N0;
	int i;
	if (B<=1)
	return 1;
	/*NOTE: As a minor optimization, we could be passing around log2(B), not B, for both this and for
	exp_rotation().*/
	N0 = celt_udiv(N, B);
	collapse_mask = 0;
	i=0; do {
	int j;
	unsigned tmp=0;
	j=0; do {
	tmp \|= iy[i*N0+j];
	} while (++j<N0);
	collapse_mask \|= (tmp!=0)<<i;
	} while (++i<B);
	return collapse_mask;
	}

	unsigned alg_quant(celt_norm X, int N, int K, int spread, int B, ec_enc enc
	#ifdef RESYNTH
	, opus_val16 gain
	#endif
	)
	{
	VARDECL(celt_norm, y);
	VARDECL(int, iy);
	VARDECL(opus_val16, signx);
	int i, j;
	opus_val16 s;
	int pulsesLeft;
	opus_val32 sum;
	opus_val32 xy;
	opus_val16 yy;
	unsigned collapse_mask;
	SAVE_STACK;

	celt_assert2(K>0, "alg_quant() needs at least one pulse");
	celt_assert2(N>1, "alg_quant() needs at least two dimensions");

	ALLOC(y, N, celt_norm);
	ALLOC(iy, N, int);
	ALLOC(signx, N, opus_val16);

	exp_rotation(X, N, 1, B, K, spread);

	/* Get rid of the sign */
	sum = 0;
	j=0; do {
	if (X[j]>0)
	signx[j]=1;
	else {
	signx[j]=-1;
	X[j]=-X[j];
	}
	iy[j] = 0;
	y[j] = 0;
	} while (++j<N);

	xy = yy = 0;

	pulsesLeft = K;

	/* Do a pre-search by projecting on the pyramid */
	if (K > (N>>1))
	{
	opus_val16 rcp;
	j=0; do {
	sum += X[j];
	} while (++j<N);

	/* If X is too small, just replace it with a pulse at 0 */
	#ifdef FIXED_POINT
	if (sum <= K)
	#else
	/* Prevents infinities and NaNs from causing too many pulses
	to be allocated. 64 is an approximation of infinity here. */
	if (!(sum > EPSILON && sum < 64))
	#endif
	{
	X[0] = QCONST16(1.f,14);
	j=1; do
	X[j]=0;
	while (++j<N);
	sum = QCONST16(1.f,14);
	}
	rcp = EXTRACT16(MULT16_32_Q16(K-1, celt_rcp(sum)));
	j=0; do {
	#ifdef FIXED_POINT
	/* It's really important to round towards zero here */
	iy[j] = MULT16_16_Q15(X[j],rcp);
	#else
	iy[j] = (int)floor(rcp*X[j]);
	#endif
	y[j] = (celt_norm)iy[j];
	yy = MAC16_16(yy, y[j],y[j]);
	xy = MAC16_16(xy, X[j],y[j]);
	y[j] *= 2;
	pulsesLeft -= iy[j];
	} while (++j<N);
	}
	celt_assert2(pulsesLeft>=1, "Allocated too many pulses in the quick pass");

	/* This should never happen, but just in case it does (e.g. on silence)
	we fill the first bin with pulses. */
	#ifdef FIXED_POINT_DEBUG
	celt_assert2(pulsesLeft<=N+3, "Not enough pulses in the quick pass");
	#endif
	if (pulsesLeft > N+3)
	{
	opus_val16 tmp = (opus_val16)pulsesLeft;
	yy = MAC16_16(yy, tmp, tmp);
	yy = MAC16_16(yy, tmp, y[0]);
	iy[0] += pulsesLeft;
	pulsesLeft=0;
	}

	s = 1;
	for (i=0;i<pulsesLeft;i++)
	{
	int best_id;
	opus_val32 best_num = -VERY_LARGE16;
	opus_val16 best_den = 0;
	#ifdef FIXED_POINT
	int rshift;
	#endif
	#ifdef FIXED_POINT
	rshift = 1+celt_ilog2(K-pulsesLeft+i+1);
	#endif
	best_id = 0;
	/* The squared magnitude term gets added anyway, so we might as well
	add it outside the loop */
	yy = ADD16(yy, 1);
	j=0;
	do {
	opus_val16 Rxy, Ryy;
	/* Temporary sums of the new pulse(s) */
	Rxy = EXTRACT16(SHR32(ADD32(xy, EXTEND32(X[j])),rshift));
	/* We're multiplying y[j] by two so we don't have to do it here */
	Ryy = ADD16(yy, y[j]);

	/* Approximate score: we maximise Rxy/sqrt(Ryy) (we're guaranteed that
	Rxy is positive because the sign is pre-computed) */
	Rxy = MULT16_16_Q15(Rxy,Rxy);
	/* The idea is to check for num/den >= best_num/best_den, but that way
	we can do it without any division */
	/* OPT: Make sure to use conditional moves here */
	if (MULT16_16(best_den, Rxy) > MULT16_16(Ryy, best_num))
	{
	best_den = Ryy;
	best_num = Rxy;
	best_id = j;
	}
	} while (++j<N);

	/* Updating the sums of the new pulse(s) */
	xy = ADD32(xy, EXTEND32(X[best_id]));
	/* We're multiplying y[j] by two so we don't have to do it here */
	yy = ADD16(yy, y[best_id]);

	/* Only now that we've made the final choice, update y/iy */
	/* Multiplying y[j] by 2 so we don't have to do it everywhere else */
	y[best_id] += 2*s;
	iy[best_id]++;
	}

	/* Put the original sign back */
	j=0;
	do {
	X[j] = MULT16_16(signx[j],X[j]);
	if (signx[j] < 0)
	iy[j] = -iy[j];
	} while (++j<N);
	encode_pulses(iy, N, K, enc);

	#ifdef RESYNTH
	normalise_residual(iy, X, N, yy, gain);
	exp_rotation(X, N, -1, B, K, spread);
	#endif

	collapse_mask = extract_collapse_mask(iy, N, B);
	RESTORE_STACK;
	return collapse_mask;
	}

	/** Decode pulse vector and combine the result with the pitch vector to produce
	the final normalised signal in the current band. */
	unsigned alg_unquant(celt_norm *X, int N, int K, int spread, int B,
	ec_dec *dec, opus_val16 gain)
	{
	opus_val32 Ryy;
	unsigned collapse_mask;
	VARDECL(int, iy);
	SAVE_STACK;

	celt_assert2(K>0, "alg_unquant() needs at least one pulse");
	celt_assert2(N>1, "alg_unquant() needs at least two dimensions");
	ALLOC(iy, N, int);
	Ryy = decode_pulses(iy, N, K, dec);
	normalise_residual(iy, X, N, Ryy, gain);
	exp_rotation(X, N, -1, B, K, spread);
	collapse_mask = extract_collapse_mask(iy, N, B);
	RESTORE_STACK;
	return collapse_mask;
	}

	#ifndef OVERRIDE_renormalise_vector
	void renormalise_vector(celt_norm *X, int N, opus_val16 gain, int arch)
	{
	int i;
	#ifdef FIXED_POINT
	int k;
	#endif
	opus_val32 E;
	opus_val16 g;
	opus_val32 t;
	celt_norm *xptr;
	E = EPSILON + celt_inner_prod(X, X, N, arch);
	#ifdef FIXED_POINT
	k = celt_ilog2(E)>>1;
	#endif
	t = VSHR32(E, 2*(k-7));
	g = MULT16_16_P15(celt_rsqrt_norm(t),gain);

	xptr = X;
	for (i=0;i<N;i++)
	{
	xptr = EXTRACT16(PSHR32(MULT16_16(g, xptr), k+1));
	xptr++;
	}
	/return celt_sqrt(E);/
	}
	#endif /* OVERRIDE_renormalise_vector */

	int stereo_itheta(const celt_norm X, const celt_norm Y, int stereo, int N, int arch)
	{
	int i;
	int itheta;
	opus_val16 mid, side;
	opus_val32 Emid, Eside;

	Emid = Eside = EPSILON;
	if (stereo)
	{
	for (i=0;i<N;i++)
	{
	celt_norm m, s;
	m = ADD16(SHR16(X[i],1),SHR16(Y[i],1));
	s = SUB16(SHR16(X[i],1),SHR16(Y[i],1));
	Emid = MAC16_16(Emid, m, m);
	Eside = MAC16_16(Eside, s, s);
	}
	} else {
	Emid += celt_inner_prod(X, X, N, arch);
	Eside += celt_inner_prod(Y, Y, N, arch);
	}
	mid = celt_sqrt(Emid);
	side = celt_sqrt(Eside);
	#ifdef FIXED_POINT
	/* 0.63662 = 2/pi */
	itheta = MULT16_16_Q15(QCONST16(0.63662f,15),celt_atan2p(side, mid));
	#else
	itheta = (int)floor(.5f+163840.63662fatan2(side,mid));
	#endif

	return itheta;
	}