640 lines
21 KiB
C
640 lines
21 KiB
C
/* Copyright (c) 2007-2008 CSIRO
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Copyright (c) 2007-2009 Xiph.Org Foundation
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Written by Jean-Marc Valin */
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/*
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions
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are met:
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- Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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- Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in the
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documentation and/or other materials provided with the distribution.
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
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OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
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EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
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PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
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PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
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LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
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NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
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SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include <math.h>
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#include "modes.h"
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#include "cwrs.h"
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#include "arch.h"
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#include "os_support.h"
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#include "entcode.h"
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#include "rate.h"
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static const unsigned char LOG2_FRAC_TABLE[24]={
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0,
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8,13,
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16,19,21,23,
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24,26,27,28,29,30,31,32,
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32,33,34,34,35,36,36,37,37
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};
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#ifdef CUSTOM_MODES
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/*Determines if V(N,K) fits in a 32-bit unsigned integer.
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N and K are themselves limited to 15 bits.*/
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static int fits_in32(int _n, int _k)
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{
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static const opus_int16 maxN[15] = {
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32767, 32767, 32767, 1476, 283, 109, 60, 40,
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29, 24, 20, 18, 16, 14, 13};
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static const opus_int16 maxK[15] = {
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32767, 32767, 32767, 32767, 1172, 238, 95, 53,
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36, 27, 22, 18, 16, 15, 13};
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if (_n>=14)
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{
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if (_k>=14)
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return 0;
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else
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return _n <= maxN[_k];
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} else {
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return _k <= maxK[_n];
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}
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}
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void compute_pulse_cache(CELTMode *m, int LM)
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{
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int C;
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int i;
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int j;
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int curr=0;
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int nbEntries=0;
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int entryN[100], entryK[100], entryI[100];
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const opus_int16 *eBands = m->eBands;
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PulseCache *cache = &m->cache;
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opus_int16 *cindex;
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unsigned char *bits;
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unsigned char *cap;
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cindex = (opus_int16 *)opus_alloc(sizeof(cache->index[0])*m->nbEBands*(LM+2));
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cache->index = cindex;
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/* Scan for all unique band sizes */
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for (i=0;i<=LM+1;i++)
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{
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for (j=0;j<m->nbEBands;j++)
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{
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int k;
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int N = (eBands[j+1]-eBands[j])<<i>>1;
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cindex[i*m->nbEBands+j] = -1;
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/* Find other bands that have the same size */
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for (k=0;k<=i;k++)
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{
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int n;
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for (n=0;n<m->nbEBands && (k!=i || n<j);n++)
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{
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if (N == (eBands[n+1]-eBands[n])<<k>>1)
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{
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cindex[i*m->nbEBands+j] = cindex[k*m->nbEBands+n];
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break;
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}
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}
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}
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if (cache->index[i*m->nbEBands+j] == -1 && N!=0)
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{
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int K;
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entryN[nbEntries] = N;
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K = 0;
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while (fits_in32(N,get_pulses(K+1)) && K<MAX_PSEUDO)
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K++;
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entryK[nbEntries] = K;
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cindex[i*m->nbEBands+j] = curr;
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entryI[nbEntries] = curr;
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curr += K+1;
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nbEntries++;
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}
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}
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}
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bits = (unsigned char *)opus_alloc(sizeof(unsigned char)*curr);
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cache->bits = bits;
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cache->size = curr;
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/* Compute the cache for all unique sizes */
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for (i=0;i<nbEntries;i++)
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{
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unsigned char *ptr = bits+entryI[i];
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opus_int16 tmp[CELT_MAX_PULSES+1];
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get_required_bits(tmp, entryN[i], get_pulses(entryK[i]), BITRES);
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for (j=1;j<=entryK[i];j++)
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ptr[j] = tmp[get_pulses(j)]-1;
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ptr[0] = entryK[i];
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}
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/* Compute the maximum rate for each band at which we'll reliably use as
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many bits as we ask for. */
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cache->caps = cap = (unsigned char *)opus_alloc(sizeof(cache->caps[0])*(LM+1)*2*m->nbEBands);
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for (i=0;i<=LM;i++)
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{
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for (C=1;C<=2;C++)
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{
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for (j=0;j<m->nbEBands;j++)
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{
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int N0;
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int max_bits;
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N0 = m->eBands[j+1]-m->eBands[j];
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/* N=1 bands only have a sign bit and fine bits. */
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if (N0<<i == 1)
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max_bits = C*(1+MAX_FINE_BITS)<<BITRES;
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else
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{
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const unsigned char *pcache;
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opus_int32 num;
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opus_int32 den;
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int LM0;
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int N;
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int offset;
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int ndof;
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int qb;
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int k;
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LM0 = 0;
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/* Even-sized bands bigger than N=2 can be split one more time.
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As of commit 44203907 all bands >1 are even, including custom modes.*/
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if (N0 > 2)
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{
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N0>>=1;
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LM0--;
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}
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/* N0=1 bands can't be split down to N<2. */
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else if (N0 <= 1)
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{
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LM0=IMIN(i,1);
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N0<<=LM0;
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}
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/* Compute the cost for the lowest-level PVQ of a fully split
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band. */
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pcache = bits + cindex[(LM0+1)*m->nbEBands+j];
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max_bits = pcache[pcache[0]]+1;
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/* Add in the cost of coding regular splits. */
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N = N0;
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for(k=0;k<i-LM0;k++){
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max_bits <<= 1;
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/* Offset the number of qtheta bits by log2(N)/2
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+ QTHETA_OFFSET compared to their "fair share" of
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total/N */
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offset = ((m->logN[j]+((LM0+k)<<BITRES))>>1)-QTHETA_OFFSET;
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/* The number of qtheta bits we'll allocate if the remainder
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is to be max_bits.
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The average measured cost for theta is 0.89701 times qb,
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approximated here as 459/512. */
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num=459*(opus_int32)((2*N-1)*offset+max_bits);
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den=((opus_int32)(2*N-1)<<9)-459;
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qb = IMIN((num+(den>>1))/den, 57);
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celt_assert(qb >= 0);
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max_bits += qb;
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N <<= 1;
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}
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/* Add in the cost of a stereo split, if necessary. */
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if (C==2)
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{
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max_bits <<= 1;
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offset = ((m->logN[j]+(i<<BITRES))>>1)-(N==2?QTHETA_OFFSET_TWOPHASE:QTHETA_OFFSET);
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ndof = 2*N-1-(N==2);
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/* The average measured cost for theta with the step PDF is
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0.95164 times qb, approximated here as 487/512. */
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num = (N==2?512:487)*(opus_int32)(max_bits+ndof*offset);
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den = ((opus_int32)ndof<<9)-(N==2?512:487);
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qb = IMIN((num+(den>>1))/den, (N==2?64:61));
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celt_assert(qb >= 0);
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max_bits += qb;
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}
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/* Add the fine bits we'll use. */
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/* Compensate for the extra DoF in stereo */
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ndof = C*N + ((C==2 && N>2) ? 1 : 0);
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/* Offset the number of fine bits by log2(N)/2 + FINE_OFFSET
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compared to their "fair share" of total/N */
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offset = ((m->logN[j] + (i<<BITRES))>>1)-FINE_OFFSET;
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/* N=2 is the only point that doesn't match the curve */
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if (N==2)
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offset += 1<<BITRES>>2;
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/* The number of fine bits we'll allocate if the remainder is
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to be max_bits. */
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num = max_bits+ndof*offset;
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den = (ndof-1)<<BITRES;
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qb = IMIN((num+(den>>1))/den, MAX_FINE_BITS);
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celt_assert(qb >= 0);
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max_bits += C*qb<<BITRES;
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}
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max_bits = (4*max_bits/(C*((m->eBands[j+1]-m->eBands[j])<<i)))-64;
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celt_assert(max_bits >= 0);
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celt_assert(max_bits < 256);
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*cap++ = (unsigned char)max_bits;
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}
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}
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}
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}
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#endif /* CUSTOM_MODES */
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#define ALLOC_STEPS 6
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static OPUS_INLINE int interp_bits2pulses(const CELTMode *m, int start, int end, int skip_start,
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const int *bits1, const int *bits2, const int *thresh, const int *cap, opus_int32 total, opus_int32 *_balance,
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int skip_rsv, int *intensity, int intensity_rsv, int *dual_stereo, int dual_stereo_rsv, int *bits,
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int *ebits, int *fine_priority, int C, int LM, ec_ctx *ec, int encode, int prev, int signalBandwidth)
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{
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opus_int32 psum;
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int lo, hi;
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int i, j;
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int logM;
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int stereo;
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int codedBands=-1;
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int alloc_floor;
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opus_int32 left, percoeff;
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int done;
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opus_int32 balance;
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SAVE_STACK;
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alloc_floor = C<<BITRES;
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stereo = C>1;
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logM = LM<<BITRES;
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lo = 0;
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hi = 1<<ALLOC_STEPS;
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for (i=0;i<ALLOC_STEPS;i++)
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{
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int mid = (lo+hi)>>1;
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psum = 0;
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done = 0;
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for (j=end;j-->start;)
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{
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int tmp = bits1[j] + (mid*(opus_int32)bits2[j]>>ALLOC_STEPS);
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if (tmp >= thresh[j] || done)
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{
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done = 1;
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/* Don't allocate more than we can actually use */
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psum += IMIN(tmp, cap[j]);
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} else {
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if (tmp >= alloc_floor)
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psum += alloc_floor;
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}
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}
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if (psum > total)
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hi = mid;
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else
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lo = mid;
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}
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psum = 0;
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/*printf ("interp bisection gave %d\n", lo);*/
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done = 0;
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for (j=end;j-->start;)
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{
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int tmp = bits1[j] + (lo*bits2[j]>>ALLOC_STEPS);
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if (tmp < thresh[j] && !done)
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{
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if (tmp >= alloc_floor)
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tmp = alloc_floor;
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else
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tmp = 0;
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} else
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done = 1;
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/* Don't allocate more than we can actually use */
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tmp = IMIN(tmp, cap[j]);
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bits[j] = tmp;
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psum += tmp;
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}
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/* Decide which bands to skip, working backwards from the end. */
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for (codedBands=end;;codedBands--)
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{
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int band_width;
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int band_bits;
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int rem;
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j = codedBands-1;
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/* Never skip the first band, nor a band that has been boosted by
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dynalloc.
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In the first case, we'd be coding a bit to signal we're going to waste
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all the other bits.
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In the second case, we'd be coding a bit to redistribute all the bits
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we just signaled should be cocentrated in this band. */
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if (j<=skip_start)
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{
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/* Give the bit we reserved to end skipping back. */
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total += skip_rsv;
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break;
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}
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/*Figure out how many left-over bits we would be adding to this band.
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This can include bits we've stolen back from higher, skipped bands.*/
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left = total-psum;
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percoeff = celt_udiv(left, m->eBands[codedBands]-m->eBands[start]);
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left -= (m->eBands[codedBands]-m->eBands[start])*percoeff;
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rem = IMAX(left-(m->eBands[j]-m->eBands[start]),0);
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band_width = m->eBands[codedBands]-m->eBands[j];
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band_bits = (int)(bits[j] + percoeff*band_width + rem);
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/*Only code a skip decision if we're above the threshold for this band.
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Otherwise it is force-skipped.
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This ensures that we have enough bits to code the skip flag.*/
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if (band_bits >= IMAX(thresh[j], alloc_floor+(1<<BITRES)))
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{
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if (encode)
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{
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/*This if() block is the only part of the allocation function that
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is not a mandatory part of the bitstream: any bands we choose to
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skip here must be explicitly signaled.*/
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/*Choose a threshold with some hysteresis to keep bands from
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fluctuating in and out.*/
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#ifdef FUZZING
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if ((rand()&0x1) == 0)
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#else
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if (codedBands<=start+2 || (band_bits > ((j<prev?7:9)*band_width<<LM<<BITRES)>>4 && j<=signalBandwidth))
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#endif
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{
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ec_enc_bit_logp(ec, 1, 1);
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break;
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}
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ec_enc_bit_logp(ec, 0, 1);
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} else if (ec_dec_bit_logp(ec, 1)) {
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break;
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}
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/*We used a bit to skip this band.*/
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psum += 1<<BITRES;
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band_bits -= 1<<BITRES;
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}
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/*Reclaim the bits originally allocated to this band.*/
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psum -= bits[j]+intensity_rsv;
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if (intensity_rsv > 0)
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intensity_rsv = LOG2_FRAC_TABLE[j-start];
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psum += intensity_rsv;
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if (band_bits >= alloc_floor)
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{
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/*If we have enough for a fine energy bit per channel, use it.*/
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psum += alloc_floor;
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bits[j] = alloc_floor;
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} else {
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/*Otherwise this band gets nothing at all.*/
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bits[j] = 0;
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}
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}
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celt_assert(codedBands > start);
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/* Code the intensity and dual stereo parameters. */
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if (intensity_rsv > 0)
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{
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if (encode)
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{
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*intensity = IMIN(*intensity, codedBands);
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ec_enc_uint(ec, *intensity-start, codedBands+1-start);
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}
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else
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*intensity = start+ec_dec_uint(ec, codedBands+1-start);
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}
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else
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*intensity = 0;
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if (*intensity <= start)
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{
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total += dual_stereo_rsv;
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dual_stereo_rsv = 0;
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}
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if (dual_stereo_rsv > 0)
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{
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if (encode)
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ec_enc_bit_logp(ec, *dual_stereo, 1);
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else
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*dual_stereo = ec_dec_bit_logp(ec, 1);
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}
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else
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*dual_stereo = 0;
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/* Allocate the remaining bits */
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left = total-psum;
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percoeff = celt_udiv(left, m->eBands[codedBands]-m->eBands[start]);
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left -= (m->eBands[codedBands]-m->eBands[start])*percoeff;
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for (j=start;j<codedBands;j++)
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bits[j] += ((int)percoeff*(m->eBands[j+1]-m->eBands[j]));
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for (j=start;j<codedBands;j++)
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{
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int tmp = (int)IMIN(left, m->eBands[j+1]-m->eBands[j]);
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bits[j] += tmp;
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left -= tmp;
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}
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/*for (j=0;j<end;j++)printf("%d ", bits[j]);printf("\n");*/
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balance = 0;
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for (j=start;j<codedBands;j++)
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{
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int N0, N, den;
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int offset;
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int NClogN;
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opus_int32 excess, bit;
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celt_assert(bits[j] >= 0);
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N0 = m->eBands[j+1]-m->eBands[j];
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N=N0<<LM;
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bit = (opus_int32)bits[j]+balance;
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if (N>1)
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{
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excess = MAX32(bit-cap[j],0);
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bits[j] = bit-excess;
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/* Compensate for the extra DoF in stereo */
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den=(C*N+ ((C==2 && N>2 && !*dual_stereo && j<*intensity) ? 1 : 0));
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NClogN = den*(m->logN[j] + logM);
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/* Offset for the number of fine bits by log2(N)/2 + FINE_OFFSET
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compared to their "fair share" of total/N */
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offset = (NClogN>>1)-den*FINE_OFFSET;
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/* N=2 is the only point that doesn't match the curve */
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if (N==2)
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offset += den<<BITRES>>2;
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/* Changing the offset for allocating the second and third
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fine energy bit */
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if (bits[j] + offset < den*2<<BITRES)
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offset += NClogN>>2;
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else if (bits[j] + offset < den*3<<BITRES)
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offset += NClogN>>3;
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/* Divide with rounding */
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ebits[j] = IMAX(0, (bits[j] + offset + (den<<(BITRES-1))));
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ebits[j] = celt_udiv(ebits[j], den)>>BITRES;
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/* Make sure not to bust */
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if (C*ebits[j] > (bits[j]>>BITRES))
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ebits[j] = bits[j] >> stereo >> BITRES;
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/* More than that is useless because that's about as far as PVQ can go */
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ebits[j] = IMIN(ebits[j], MAX_FINE_BITS);
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/* If we rounded down or capped this band, make it a candidate for the
|
|
final fine energy pass */
|
|
fine_priority[j] = ebits[j]*(den<<BITRES) >= bits[j]+offset;
|
|
|
|
/* Remove the allocated fine bits; the rest are assigned to PVQ */
|
|
bits[j] -= C*ebits[j]<<BITRES;
|
|
|
|
} else {
|
|
/* For N=1, all bits go to fine energy except for a single sign bit */
|
|
excess = MAX32(0,bit-(C<<BITRES));
|
|
bits[j] = bit-excess;
|
|
ebits[j] = 0;
|
|
fine_priority[j] = 1;
|
|
}
|
|
|
|
/* Fine energy can't take advantage of the re-balancing in
|
|
quant_all_bands().
|
|
Instead, do the re-balancing here.*/
|
|
if(excess > 0)
|
|
{
|
|
int extra_fine;
|
|
int extra_bits;
|
|
extra_fine = IMIN(excess>>(stereo+BITRES),MAX_FINE_BITS-ebits[j]);
|
|
ebits[j] += extra_fine;
|
|
extra_bits = extra_fine*C<<BITRES;
|
|
fine_priority[j] = extra_bits >= excess-balance;
|
|
excess -= extra_bits;
|
|
}
|
|
balance = excess;
|
|
|
|
celt_assert(bits[j] >= 0);
|
|
celt_assert(ebits[j] >= 0);
|
|
}
|
|
/* Save any remaining bits over the cap for the rebalancing in
|
|
quant_all_bands(). */
|
|
*_balance = balance;
|
|
|
|
/* The skipped bands use all their bits for fine energy. */
|
|
for (;j<end;j++)
|
|
{
|
|
ebits[j] = bits[j] >> stereo >> BITRES;
|
|
celt_assert(C*ebits[j]<<BITRES == bits[j]);
|
|
bits[j] = 0;
|
|
fine_priority[j] = ebits[j]<1;
|
|
}
|
|
RESTORE_STACK;
|
|
return codedBands;
|
|
}
|
|
|
|
int compute_allocation(const CELTMode *m, int start, int end, const int *offsets, const int *cap, int alloc_trim, int *intensity, int *dual_stereo,
|
|
opus_int32 total, opus_int32 *balance, int *pulses, int *ebits, int *fine_priority, int C, int LM, ec_ctx *ec, int encode, int prev, int signalBandwidth)
|
|
{
|
|
int lo, hi, len, j;
|
|
int codedBands;
|
|
int skip_start;
|
|
int skip_rsv;
|
|
int intensity_rsv;
|
|
int dual_stereo_rsv;
|
|
VARDECL(int, bits1);
|
|
VARDECL(int, bits2);
|
|
VARDECL(int, thresh);
|
|
VARDECL(int, trim_offset);
|
|
SAVE_STACK;
|
|
|
|
total = IMAX(total, 0);
|
|
len = m->nbEBands;
|
|
skip_start = start;
|
|
/* Reserve a bit to signal the end of manually skipped bands. */
|
|
skip_rsv = total >= 1<<BITRES ? 1<<BITRES : 0;
|
|
total -= skip_rsv;
|
|
/* Reserve bits for the intensity and dual stereo parameters. */
|
|
intensity_rsv = dual_stereo_rsv = 0;
|
|
if (C==2)
|
|
{
|
|
intensity_rsv = LOG2_FRAC_TABLE[end-start];
|
|
if (intensity_rsv>total)
|
|
intensity_rsv = 0;
|
|
else
|
|
{
|
|
total -= intensity_rsv;
|
|
dual_stereo_rsv = total>=1<<BITRES ? 1<<BITRES : 0;
|
|
total -= dual_stereo_rsv;
|
|
}
|
|
}
|
|
ALLOC(bits1, len, int);
|
|
ALLOC(bits2, len, int);
|
|
ALLOC(thresh, len, int);
|
|
ALLOC(trim_offset, len, int);
|
|
|
|
for (j=start;j<end;j++)
|
|
{
|
|
/* Below this threshold, we're sure not to allocate any PVQ bits */
|
|
thresh[j] = IMAX((C)<<BITRES, (3*(m->eBands[j+1]-m->eBands[j])<<LM<<BITRES)>>4);
|
|
/* Tilt of the allocation curve */
|
|
trim_offset[j] = C*(m->eBands[j+1]-m->eBands[j])*(alloc_trim-5-LM)*(end-j-1)
|
|
*(1<<(LM+BITRES))>>6;
|
|
/* Giving less resolution to single-coefficient bands because they get
|
|
more benefit from having one coarse value per coefficient*/
|
|
if ((m->eBands[j+1]-m->eBands[j])<<LM==1)
|
|
trim_offset[j] -= C<<BITRES;
|
|
}
|
|
lo = 1;
|
|
hi = m->nbAllocVectors - 1;
|
|
do
|
|
{
|
|
int done = 0;
|
|
int psum = 0;
|
|
int mid = (lo+hi) >> 1;
|
|
for (j=end;j-->start;)
|
|
{
|
|
int bitsj;
|
|
int N = m->eBands[j+1]-m->eBands[j];
|
|
bitsj = C*N*m->allocVectors[mid*len+j]<<LM>>2;
|
|
if (bitsj > 0)
|
|
bitsj = IMAX(0, bitsj + trim_offset[j]);
|
|
bitsj += offsets[j];
|
|
if (bitsj >= thresh[j] || done)
|
|
{
|
|
done = 1;
|
|
/* Don't allocate more than we can actually use */
|
|
psum += IMIN(bitsj, cap[j]);
|
|
} else {
|
|
if (bitsj >= C<<BITRES)
|
|
psum += C<<BITRES;
|
|
}
|
|
}
|
|
if (psum > total)
|
|
hi = mid - 1;
|
|
else
|
|
lo = mid + 1;
|
|
/*printf ("lo = %d, hi = %d\n", lo, hi);*/
|
|
}
|
|
while (lo <= hi);
|
|
hi = lo--;
|
|
/*printf ("interp between %d and %d\n", lo, hi);*/
|
|
for (j=start;j<end;j++)
|
|
{
|
|
int bits1j, bits2j;
|
|
int N = m->eBands[j+1]-m->eBands[j];
|
|
bits1j = C*N*m->allocVectors[lo*len+j]<<LM>>2;
|
|
bits2j = hi>=m->nbAllocVectors ?
|
|
cap[j] : C*N*m->allocVectors[hi*len+j]<<LM>>2;
|
|
if (bits1j > 0)
|
|
bits1j = IMAX(0, bits1j + trim_offset[j]);
|
|
if (bits2j > 0)
|
|
bits2j = IMAX(0, bits2j + trim_offset[j]);
|
|
if (lo > 0)
|
|
bits1j += offsets[j];
|
|
bits2j += offsets[j];
|
|
if (offsets[j]>0)
|
|
skip_start = j;
|
|
bits2j = IMAX(0,bits2j-bits1j);
|
|
bits1[j] = bits1j;
|
|
bits2[j] = bits2j;
|
|
}
|
|
codedBands = interp_bits2pulses(m, start, end, skip_start, bits1, bits2, thresh, cap,
|
|
total, balance, skip_rsv, intensity, intensity_rsv, dual_stereo, dual_stereo_rsv,
|
|
pulses, ebits, fine_priority, C, LM, ec, encode, prev, signalBandwidth);
|
|
RESTORE_STACK;
|
|
return codedBands;
|
|
}
|
|
|