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482 lines
13 KiB
C
482 lines
13 KiB
C
/*
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* parse.c
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*
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* Copyright (C) Aaron Holtzman - May 1999
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*
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* This file is part of ac3dec, a free Dolby AC-3 stream decoder.
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*
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* ac3dec is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2, or (at your option)
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* any later version.
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*
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* ac3dec is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with GNU Make; see the file COPYING. If not, write to
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* the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.
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*
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*
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*/
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#include <stdlib.h>
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#include <stdio.h>
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#include "ac3.h"
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#include "ac3_internal.h"
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#include "bitstream.h"
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#include "stats.h"
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#include "debug.h"
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#include "crc.h"
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#include "parse.h"
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/* Misc LUT */
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static const uint16_t nfchans[8] = {2,1,2,3,3,4,4,5};
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struct frmsize_s
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{
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uint16_t bit_rate;
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uint16_t frm_size[3];
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};
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static const struct frmsize_s frmsizecod_tbl[64] =
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{
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{ 32 ,{64 ,69 ,96 } },
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{ 32 ,{64 ,70 ,96 } },
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{ 40 ,{80 ,87 ,120 } },
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{ 40 ,{80 ,88 ,120 } },
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{ 48 ,{96 ,104 ,144 } },
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{ 48 ,{96 ,105 ,144 } },
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{ 56 ,{112 ,121 ,168 } },
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{ 56 ,{112 ,122 ,168 } },
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{ 64 ,{128 ,139 ,192 } },
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{ 64 ,{128 ,140 ,192 } },
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{ 80 ,{160 ,174 ,240 } },
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{ 80 ,{160 ,175 ,240 } },
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{ 96 ,{192 ,208 ,288 } },
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{ 96 ,{192 ,209 ,288 } },
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{ 112 ,{224 ,243 ,336 } },
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{ 112 ,{224 ,244 ,336 } },
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{ 128 ,{256 ,278 ,384 } },
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{ 128 ,{256 ,279 ,384 } },
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{ 160 ,{320 ,348 ,480 } },
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{ 160 ,{320 ,349 ,480 } },
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{ 192 ,{384 ,417 ,576 } },
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{ 192 ,{384 ,418 ,576 } },
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{ 224 ,{448 ,487 ,672 } },
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{ 224 ,{448 ,488 ,672 } },
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{ 256 ,{512 ,557 ,768 } },
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{ 256 ,{512 ,558 ,768 } },
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{ 320 ,{640 ,696 ,960 } },
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{ 320 ,{640 ,697 ,960 } },
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{ 384 ,{768 ,835 ,1152 } },
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{ 384 ,{768 ,836 ,1152 } },
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{ 448 ,{896 ,975 ,1344 } },
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{ 448 ,{896 ,976 ,1344 } },
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{ 512 ,{1024 ,1114 ,1536 } },
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{ 512 ,{1024 ,1115 ,1536 } },
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{ 576 ,{1152 ,1253 ,1728 } },
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{ 576 ,{1152 ,1254 ,1728 } },
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{ 640 ,{1280 ,1393 ,1920 } },
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{ 640 ,{1280 ,1394 ,1920 } }
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};
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/* Parse a syncinfo structure, minus the sync word */
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void parse_syncinfo(syncinfo_t *syncinfo, uint8_t *data)
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{
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//
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// We need to read in the entire syncinfo struct (0x0b77 + 24 bits)
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// in order to determine how big the frame is
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//
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// Get the sampling rate
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syncinfo->fscod = (data[2] >> 6) & 0x3;
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if(syncinfo->fscod == 3) {
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//invalid sampling rate code
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return;
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}
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else if(syncinfo->fscod == 2)
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syncinfo->sampling_rate = 32000;
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else if(syncinfo->fscod == 1)
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syncinfo->sampling_rate = 44100;
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else
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syncinfo->sampling_rate = 48000;
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// Get the frame size code
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syncinfo->frmsizecod = data[2] & 0x3f;
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// Calculate the frame size and bitrate
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syncinfo->frame_size =
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frmsizecod_tbl[syncinfo->frmsizecod].frm_size[syncinfo->fscod];
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syncinfo->bit_rate = frmsizecod_tbl[syncinfo->frmsizecod].bit_rate;
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}
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/**
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* This routine fills a bsi struct from the AC3 stream
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**/
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void parse_bsi(bsi_t *bsi)
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{
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/* Check the AC-3 version number */
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bsi->bsid = bitstream_get(5);
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/* Get the audio service provided by the steram */
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bsi->bsmod = bitstream_get(3);
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/* Get the audio coding mode (ie how many channels)*/
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bsi->acmod = bitstream_get(3);
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/* Predecode the number of full bandwidth channels as we use this
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* number a lot */
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bsi->nfchans = nfchans[bsi->acmod];
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/* If it is in use, get the centre channel mix level */
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if ((bsi->acmod & 0x1) && (bsi->acmod != 0x1))
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bsi->cmixlev = bitstream_get(2);
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/* If it is in use, get the surround channel mix level */
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if (bsi->acmod & 0x4)
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bsi->surmixlev = bitstream_get(2);
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/* Get the dolby surround mode if in 2/0 mode */
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if(bsi->acmod == 0x2)
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bsi->dsurmod= bitstream_get(2);
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/* Is the low frequency effects channel on? */
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bsi->lfeon = bitstream_get(1);
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/* Get the dialogue normalization level */
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bsi->dialnorm = bitstream_get(5);
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/* Does compression gain exist? */
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if ((bsi->compre = bitstream_get(1))) {
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/* Get compression gain */
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bsi->compr = bitstream_get(8);
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}
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/* Does language code exist? */
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if ((bsi->langcode = bitstream_get(1))) {
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/* Get langauge code */
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bsi->langcod = bitstream_get(8);
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}
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/* Does audio production info exist? */
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if ((bsi->audprodie = bitstream_get(1))) {
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/* Get mix level */
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bsi->mixlevel = bitstream_get(5);
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/* Get room type */
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bsi->roomtyp = bitstream_get(2);
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}
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/* If we're in dual mono mode then get some extra info */
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if (!bsi->acmod) {
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/* Get the dialogue normalization level two */
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bsi->dialnorm2 = bitstream_get(5);
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/* Does compression gain two exist? */
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if ((bsi->compr2e = bitstream_get(1))) {
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/* Get compression gain two */
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bsi->compr2 = bitstream_get(8);
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}
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/* Does language code two exist? */
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if ((bsi->langcod2e = bitstream_get(1))) {
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/* Get langauge code two */
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bsi->langcod2 = bitstream_get(8);
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}
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/* Does audio production info two exist? */
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if ((bsi->audprodi2e = bitstream_get(1))) {
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/* Get mix level two */
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bsi->mixlevel2 = bitstream_get(5);
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/* Get room type two */
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bsi->roomtyp2 = bitstream_get(2);
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}
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}
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/* Get the copyright bit */
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bsi->copyrightb = bitstream_get(1);
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/* Get the original bit */
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bsi->origbs = bitstream_get(1);
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/* Does timecode one exist? */
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if ((bsi->timecod1e = bitstream_get(1)))
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bsi->timecod1 = bitstream_get(14);
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/* Does timecode two exist? */
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if ((bsi->timecod2e = bitstream_get(1)))
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bsi->timecod2 = bitstream_get(14);
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/* Does addition info exist? */
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if ((bsi->addbsie = bitstream_get(1))) {
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uint32_t i;
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/* Get how much info is there */
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bsi->addbsil = bitstream_get(6);
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/* Get the additional info */
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for(i=0;i<(bsi->addbsil + 1);i++)
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bsi->addbsi[i] = bitstream_get(8);
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}
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stats_print_bsi(bsi);
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}
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/* More pain inducing parsing */
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void parse_audblk(bsi_t *bsi,audblk_t *audblk)
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{
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int i,j;
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for (i=0; i < bsi->nfchans; i++) {
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/* Is this channel an interleaved 256 + 256 block ? */
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audblk->blksw[i] = bitstream_get(1);
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}
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for (i=0;i < bsi->nfchans; i++) {
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/* Should we dither this channel? */
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audblk->dithflag[i] = bitstream_get(1);
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}
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/* Does dynamic range control exist? */
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if ((audblk->dynrnge = bitstream_get(1))) {
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/* Get dynamic range info */
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audblk->dynrng = bitstream_get(8);
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}
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/* If we're in dual mono mode then get the second channel DR info */
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if (bsi->acmod == 0) {
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/* Does dynamic range control two exist? */
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if ((audblk->dynrng2e = bitstream_get(1))) {
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/* Get dynamic range info */
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audblk->dynrng2 = bitstream_get(8);
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}
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}
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/* Does coupling strategy exist? */
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if ((audblk->cplstre = bitstream_get(1))) {
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/* Is coupling turned on? */
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if ((audblk->cplinu = bitstream_get(1))) {
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for(i=0;i < bsi->nfchans; i++)
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audblk->chincpl[i] = bitstream_get(1);
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if(bsi->acmod == 0x2)
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audblk->phsflginu = bitstream_get(1);
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audblk->cplbegf = bitstream_get(4);
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audblk->cplendf = bitstream_get(4);
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audblk->ncplsubnd = (audblk->cplendf + 2) - audblk->cplbegf + 1;
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/* Calculate the start and end bins of the coupling channel */
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audblk->cplstrtmant = (audblk->cplbegf * 12) + 37 ;
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audblk->cplendmant = ((audblk->cplendf + 3) * 12) + 37;
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/* The number of combined subbands is ncplsubnd minus each combined
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* band */
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audblk->ncplbnd = audblk->ncplsubnd;
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for(i=1; i< audblk->ncplsubnd; i++) {
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audblk->cplbndstrc[i] = bitstream_get(1);
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audblk->ncplbnd -= audblk->cplbndstrc[i];
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}
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}
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}
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if(audblk->cplinu) {
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/* Loop through all the channels and get their coupling co-ords */
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for(i=0;i < bsi->nfchans;i++) {
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if(!audblk->chincpl[i])
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continue;
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/* Is there new coupling co-ordinate info? */
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if ((audblk->cplcoe[i] = bitstream_get(1))) {
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audblk->mstrcplco[i] = bitstream_get(2);
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for(j=0;j < audblk->ncplbnd; j++) {
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audblk->cplcoexp[i][j] = bitstream_get(4);
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audblk->cplcomant[i][j] = bitstream_get(4);
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}
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}
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}
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/* If we're in dual mono mode, there's going to be some phase info */
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if( (bsi->acmod == 0x2) && audblk->phsflginu &&
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(audblk->cplcoe[0] || audblk->cplcoe[1])) {
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for(j=0;j < audblk->ncplbnd; j++)
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audblk->phsflg[j] = bitstream_get(1);
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}
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}
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/* If we're in dual mono mode, there may be a rematrix strategy */
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if(bsi->acmod == 0x2) {
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if ((audblk->rematstr = bitstream_get(1))) {
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if (!audblk->cplinu) {
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for(i = 0; i < 4; i++)
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audblk->rematflg[i] = bitstream_get(1);
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}
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if((audblk->cplbegf > 2) && audblk->cplinu) {
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for(i = 0; i < 4; i++)
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audblk->rematflg[i] = bitstream_get(1);
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}
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if((audblk->cplbegf <= 2) && audblk->cplinu) {
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for(i = 0; i < 3; i++)
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audblk->rematflg[i] = bitstream_get(1);
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}
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if((audblk->cplbegf == 0) && audblk->cplinu)
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for(i = 0; i < 2; i++)
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audblk->rematflg[i] = bitstream_get(1);
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}
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}
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if (audblk->cplinu) {
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/* Get the coupling channel exponent strategy */
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audblk->cplexpstr = bitstream_get(2);
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audblk->ncplgrps = (audblk->cplendmant - audblk->cplstrtmant) /
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(3 << (audblk->cplexpstr-1));
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}
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for(i = 0; i < bsi->nfchans; i++)
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audblk->chexpstr[i] = bitstream_get(2);
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/* Get the exponent strategy for lfe channel */
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if(bsi->lfeon)
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audblk->lfeexpstr = bitstream_get(1);
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/* Determine the bandwidths of all the fbw channels */
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for(i = 0; i < bsi->nfchans; i++) {
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uint16_t grp_size;
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if(audblk->chexpstr[i] != EXP_REUSE) {
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if (audblk->cplinu && audblk->chincpl[i]) {
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audblk->endmant[i] = audblk->cplstrtmant;
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} else {
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audblk->chbwcod[i] = bitstream_get(6);
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audblk->endmant[i] = ((audblk->chbwcod[i] + 12) * 3) + 37;
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}
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/* Calculate the number of exponent groups to fetch */
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grp_size = 3 * (1 << (audblk->chexpstr[i] - 1));
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audblk->nchgrps[i] = (audblk->endmant[i] - 1 + (grp_size - 3)) / grp_size;
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}
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}
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/* Get the coupling exponents if they exist */
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if(audblk->cplinu && (audblk->cplexpstr != EXP_REUSE)) {
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audblk->cplabsexp = bitstream_get(4);
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for(i=0;i< audblk->ncplgrps;i++)
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audblk->cplexps[i] = bitstream_get(7);
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}
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/* Get the fwb channel exponents */
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for(i=0;i < bsi->nfchans; i++) {
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if(audblk->chexpstr[i] != EXP_REUSE) {
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audblk->exps[i][0] = bitstream_get(4);
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for(j=1;j<=audblk->nchgrps[i];j++)
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audblk->exps[i][j] = bitstream_get(7);
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audblk->gainrng[i] = bitstream_get(2);
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}
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}
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/* Get the lfe channel exponents */
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if(bsi->lfeon && (audblk->lfeexpstr != EXP_REUSE)) {
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audblk->lfeexps[0] = bitstream_get(4);
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audblk->lfeexps[1] = bitstream_get(7);
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audblk->lfeexps[2] = bitstream_get(7);
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}
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/* Get the parametric bit allocation parameters */
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audblk->baie = bitstream_get(1);
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if(audblk->baie) {
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audblk->sdcycod = bitstream_get(2);
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audblk->fdcycod = bitstream_get(2);
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audblk->sgaincod = bitstream_get(2);
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audblk->dbpbcod = bitstream_get(2);
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audblk->floorcod = bitstream_get(3);
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}
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/* Get the SNR off set info if it exists */
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audblk->snroffste = bitstream_get(1);
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if(audblk->snroffste) {
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audblk->csnroffst = bitstream_get(6);
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if(audblk->cplinu) {
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audblk->cplfsnroffst = bitstream_get(4);
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audblk->cplfgaincod = bitstream_get(3);
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}
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for(i = 0;i < bsi->nfchans; i++) {
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audblk->fsnroffst[i] = bitstream_get(4);
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audblk->fgaincod[i] = bitstream_get(3);
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}
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if(bsi->lfeon) {
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audblk->lfefsnroffst = bitstream_get(4);
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audblk->lfefgaincod = bitstream_get(3);
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}
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}
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/* Get coupling leakage info if it exists */
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if(audblk->cplinu) {
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audblk->cplleake = bitstream_get(1);
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if(audblk->cplleake) {
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audblk->cplfleak = bitstream_get(3);
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audblk->cplsleak = bitstream_get(3);
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}
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}
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/* Get the delta bit alloaction info */
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audblk->deltbaie = bitstream_get(1);
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if(audblk->deltbaie) {
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if(audblk->cplinu)
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audblk->cpldeltbae = bitstream_get(2);
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for(i = 0;i < bsi->nfchans; i++)
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audblk->deltbae[i] = bitstream_get(2);
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if (audblk->cplinu && (audblk->cpldeltbae == DELTA_BIT_NEW)) {
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audblk->cpldeltnseg = bitstream_get(3);
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for(i = 0;i < audblk->cpldeltnseg + 1; i++) {
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audblk->cpldeltoffst[i] = bitstream_get(5);
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audblk->cpldeltlen[i] = bitstream_get(4);
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audblk->cpldeltba[i] = bitstream_get(3);
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}
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}
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for(i = 0;i < bsi->nfchans; i++) {
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if (audblk->deltbae[i] == DELTA_BIT_NEW) {
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audblk->deltnseg[i] = bitstream_get(3);
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for(j = 0; j < audblk->deltnseg[i] + 1; j++) {
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audblk->deltoffst[i][j] = bitstream_get(5);
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audblk->deltlen[i][j] = bitstream_get(4);
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audblk->deltba[i][j] = bitstream_get(3);
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}
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}
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}
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}
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/* Check to see if there's any dummy info to get */
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if((audblk->skiple = bitstream_get(1))) {
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uint16_t skip_data;
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audblk->skipl = bitstream_get(9);
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for (i = 0; i < audblk->skipl; i++) {
|
|
skip_data = bitstream_get(8);
|
|
}
|
|
}
|
|
|
|
stats_print_audblk(bsi,audblk);
|
|
}
|