2011-09-14 19:08:43 +00:00
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/**
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** Supermodel
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** A Sega Model 3 Arcade Emulator.
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** Copyright 2011 Bart Trzynadlowski, Nik Henson
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**
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** This file is part of Supermodel.
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**
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** Supermodel is free software: you can redistribute it and/or modify it under
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** the terms of the GNU General Public License as published by the Free
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** Software Foundation, either version 3 of the License, or (at your option)
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** any later version.
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**
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** Supermodel is distributed in the hope that it will be useful, but WITHOUT
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** ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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** FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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** more details.
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**
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** You should have received a copy of the GNU General Public License along
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** with Supermodel. If not, see <http://www.gnu.org/licenses/>.
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**/
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/*
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* getdata.cpp
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*
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* Amp library internal module.
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*/
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2011-07-31 02:37:31 +00:00
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/* this file is a part of amp software, (C) tomislav uzelac 1996,1997
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*/
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/* getdata.c scalefactor & huffman data extraction
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*
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* Created by: tomislav uzelac Apr 1996
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* Last modified by: tomislav uzelac Feb 27 1997
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*/
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#include "amp.h"
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2017-10-05 02:14:02 +00:00
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#include "amp_audio.h"
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2011-07-31 02:37:31 +00:00
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#include "getbits.h"
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#include "huffman.h"
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#define GETDATA
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#include "getdata.h"
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/* layer3 scalefactor decoding. should we check for the number
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* of bits read, just in case?
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*/
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int decode_scalefactors(struct SIDE_INFO *info,struct AUDIO_HEADER *header,int gr,int ch)
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{
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int sfb,window;
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int slen1,slen2;
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int i1,i2,i=0;
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int j,k;
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if (header->ID==1) {
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/* this is MPEG-1 scalefactors format, quite different than
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* the MPEG-2 format.
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*/
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slen1=t_slen1[info->scalefac_compress[gr][ch]];
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slen2=t_slen2[info->scalefac_compress[gr][ch]];
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i1=3*slen1;
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i2=3*slen2;
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if (info->window_switching_flag[gr][ch] && info->block_type[gr][ch]==2) {
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if (info->mixed_block_flag[gr][ch]) {
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for (sfb=0;sfb<8;sfb++) {
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scalefac_l[gr][ch][sfb]=getbits(slen1);
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i+=slen1;
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}
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for (sfb=3;sfb<6;sfb++) {
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for (window=0;window<3;window++)
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scalefac_s[gr][ch][sfb][window]=getbits(slen1);
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i+=i1;
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}
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for (;sfb<12;sfb++) {
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for (window=0;window<3;window++)
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scalefac_s[gr][ch][sfb][window]=getbits(slen2);
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i+=i2;
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}
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} else { /* !mixed_block_flag */
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for (sfb=0;sfb<6;sfb++) {
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for (window=0;window<3;window++)
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scalefac_s[gr][ch][sfb][window]=getbits(slen1);
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i+=i1;
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}
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for (;sfb<12;sfb++) {
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for (window=0;window<3;window++)
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scalefac_s[gr][ch][sfb][window]=getbits(slen2);
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i+=i2;
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}
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}
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for (window=0;window<3;window++)
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scalefac_s[gr][ch][12][window]=0;
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} else { /* block_type!=2 */
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if ( !info->scfsi[ch][0] || !gr )
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for (sfb=0;sfb<6;sfb++) {
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scalefac_l[gr][ch][sfb]=getbits(slen1);
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i+=slen1;
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}
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else for (sfb=0;sfb<6;sfb++) {
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scalefac_l[1][ch][sfb]=scalefac_l[0][ch][sfb];
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}
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if ( !info->scfsi[ch][1] || !gr )
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for (sfb=6;sfb<11;sfb++) {
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scalefac_l[gr][ch][sfb]=getbits(slen1);
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i+=slen1;
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}
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else for (sfb=6;sfb<11;sfb++) {
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scalefac_l[1][ch][sfb]=scalefac_l[0][ch][sfb];
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}
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if ( !info->scfsi[ch][2] || !gr )
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for (sfb=11;sfb<16;sfb++) {
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scalefac_l[gr][ch][sfb]=getbits(slen2);
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i+=slen2;
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}
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else for (sfb=11;sfb<16;sfb++) {
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scalefac_l[1][ch][sfb]=scalefac_l[0][ch][sfb];
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}
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if ( !info->scfsi[ch][3] || !gr )
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for (sfb=16;sfb<21;sfb++) {
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scalefac_l[gr][ch][sfb]=getbits(slen2);
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i+=slen2;
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}
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else for (sfb=16;sfb<21;sfb++) {
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scalefac_l[1][ch][sfb]=scalefac_l[0][ch][sfb];
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}
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scalefac_l[gr][ch][21]=0;
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}
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} else { /* ID==0 */
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int index=0,index2,spooky_index;
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int slen[6],nr_of_sfb[6]; /* actually, there's four of each, not five, labelled 1 through 4, but
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* what's a word of storage compared to one's sanity. so [0] is irellevant.
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*/
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/* ok, so we got 3 indexes.
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* spooky_index - indicates whether we use the normal set of slen eqs and nr_of_sfb tables
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* or the one for the right channel of intensity stereo coded frame
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* index - corresponds to the value of scalefac_compress, as listed in the standard
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* index2 - 0 for long blocks, 1 for short wo/ mixed_block_flag, 2 for short with it
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*/
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if ( (header->mode_extension==1 || header->mode_extension==3) && ch==1) { /* right ch... */
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int int_scalefac_compress=info->scalefac_compress[0][ch]>>1;
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intensity_scale=info->scalefac_compress[0][1]&1;
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spooky_index=1;
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if (int_scalefac_compress < 180) {
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slen[1]=int_scalefac_compress/36;
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slen[2]=(int_scalefac_compress%36)/6;
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slen[3]=(int_scalefac_compress%36)%6;
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slen[4]=0;
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info->preflag[0][ch]=0;
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index=0;
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}
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if ( 180 <= int_scalefac_compress && int_scalefac_compress < 244) {
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slen[1]=((int_scalefac_compress-180)%64)>>4;
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slen[2]=((int_scalefac_compress-180)%16)>>2;
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slen[3]=(int_scalefac_compress-180)%4;
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slen[4]=0;
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info->preflag[0][ch]=0;
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index=1;
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}
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if ( 244 <= int_scalefac_compress && int_scalefac_compress < 255) {
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slen[1]=(int_scalefac_compress-244)/3;
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slen[2]=(int_scalefac_compress-244)%3;
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slen[3]=0;
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slen[4]=0;
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info->preflag[0][ch]=0;
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index=2;
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}
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} else { /* the usual */
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spooky_index=0;
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if (info->scalefac_compress[0][ch] < 400) {
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slen[1]=(info->scalefac_compress[0][ch]>>4)/5;
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slen[2]=(info->scalefac_compress[0][ch]>>4)%5;
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slen[3]=(info->scalefac_compress[0][ch]%16)>>2;
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slen[4]=info->scalefac_compress[0][ch]%4;
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info->preflag[0][ch]=0;
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index=0;
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}
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if (info->scalefac_compress[0][ch] >= 400 && info->scalefac_compress[0][ch] < 500) {
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slen[1]=((info->scalefac_compress[0][ch]-400)>>2)/5;
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slen[2]=((info->scalefac_compress[0][ch]-400)>>2)%5;
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slen[3]=(info->scalefac_compress[0][ch]-400)%4;
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slen[4]=0;
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info->preflag[0][ch]=0;
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index=1;
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}
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if (info->scalefac_compress[0][ch] >= 500 && info->scalefac_compress[0][ch] < 512) {
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slen[1]=(info->scalefac_compress[0][ch]-500)/3;
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slen[2]=(info->scalefac_compress[0][ch]-500)%3;
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slen[3]=0;
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slen[4]=0;
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info->preflag[0][ch]=1;
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index=2;
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}
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}
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if (info->window_switching_flag[0][ch] && info->block_type[0][ch]==2)
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if (info->mixed_block_flag[0][ch]) index2=2;
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else index2=1;
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else index2=0;
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for (j=1;j<=4;j++) nr_of_sfb[j]=spooky_table[spooky_index][index][index2][j-1];
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/* now we'll do some actual scalefactor extraction, and a little more.
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* for each scalefactor band we'll set the value of is_max to indicate
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* illegal is_pos, since with MPEG2 it's not 'hardcoded' to 7.
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*/
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if (!info->window_switching_flag[0][ch] || (info->window_switching_flag[0][ch] && info->block_type[0][ch]!=2)) {
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sfb=0;
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for (j=1;j<=4;j++)
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for (k=0;k<nr_of_sfb[j];k++) {
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scalefac_l[0][ch][sfb]=getbits(slen[j]);
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i+=slen[j];
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if (ch) is_max[sfb]=(1<<slen[j])-1;
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sfb++;
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}
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} else if (info->block_type[0][ch]==2)
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{
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if (!info->mixed_block_flag[0][ch]) {
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sfb=0;
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for (j=1;j<=4;j++)
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for (k=0;k<nr_of_sfb[j];k+=3) {
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/* we assume here that nr_of_sfb is divisible by 3. it is.
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*/
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scalefac_s[0][ch][sfb][0]=getbits(slen[j]);
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scalefac_s[0][ch][sfb][1]=getbits(slen[j]);
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scalefac_s[0][ch][sfb][2]=getbits(slen[j]);
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i+=3*slen[j];
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if (ch) is_max[sfb+6]=(1<<slen[j])-1;
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sfb++;
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}
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} else {
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/* what we do here is:
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* 1. assume that for every fs, the two lowest subbands are equal to the
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* six lowest scalefactor bands for long blocks/MPEG2. they are.
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* 2. assume that for every fs, the two lowest subbands are equal to the
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* three lowest scalefactor bands for short blocks. they are.
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*/
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sfb=0;
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for (k=0;k<6;k++) {
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scalefac_l[0][ch][sfb]=getbits(slen[1]);
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i+=slen[j];
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if (ch) is_max[sfb]=(1<<slen[1])-1;
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sfb++;
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}
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nr_of_sfb[1]-=6;
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sfb=3;
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for (j=1;j<=4;j++)
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for (k=0;k<nr_of_sfb[j];k+=3) {
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scalefac_s[0][ch][sfb][0]=getbits(slen[j]);
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scalefac_s[0][ch][sfb][1]=getbits(slen[j]);
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scalefac_s[0][ch][sfb][2]=getbits(slen[j]);
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i+=3*slen[j];
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if (ch) is_max[sfb+6]=(1<<slen[j])-1;
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sfb++;
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}
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}
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}
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}
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return i;
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}
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