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98a27a8a84
FFmpeg/libavcodec/ac3dec.c
Justin Ruggles 98a27a8a84 AC-3 decoder, soc revision 38, Aug 7 00:03:00 2006 UTC by cloud9 
major code cleanup.
correct implementation of imdct.
implemented imdct for block switching also.
when coupling is not in use all the
ac3 streams are decoded correctly.
but when coupling is in use there is a bug.
i am currently finding the root of the bug.
if anybody can help.

Originally committed as revision 9657 to svn://svn.ffmpeg.org/ffmpeg/trunk
2007-07-14 15:56:55 +00:00

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/* AC3 Audio Decoder.
*
* Copyright (c) 2006 Kartikey Mahendra BHATT (bhattkm at gmail dot com).
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <stdio.h>
#include <stddef.h>
#include <math.h>
#include <inttypes.h>
#include <string.h>
#define ALT_BITSTREAM_READER
#include "ac3tab.h"
#include "ac3.h"
#include "ac3_decoder.h"
#include "avcodec.h"
#include "bitstream.h"
#include "dsputil.h"
#include "avutil.h"
#include "common.h"
#include "math.h"
#define N 512 /* constant for IMDCT Block size */
#define MAX_CHANNELS 6
#define BLOCK_SIZE 256
#define AUDIO_BLOCKS 6
/* Exponent strategies. */
#define AC3_EXPSTR_D15 0x01
#define AC3_EXPSTR_D25 0x02
#define AC3_EXPSTR_D45 0x03
#define AC3_EXPSTR_REUSE 0x00
/* Bit allocation strategies. */
#define AC3_DBASTR_NEW 0x01
#define AC3_DBASTR_NONE 0x02
#define AC3_DBASTR_RESERVED 0x03
#define AC3_DBASTR_REUSE 0x00
/* Output and input configurations. */
#define AC3_OUTPUT_UNMODIFIED 0x01
#define AC3_OUTPUT_MONO 0x02
#define AC3_OUTPUT_STEREO 0x04
#define AC3_OUTPUT_DOLBY 0x08
#define AC3_OUTPUT_LFEON 0x10
#define AC3_INPUT_DUALMONO 0x00
#define AC3_INPUT_MONO 0x01
#define AC3_INPUT_STEREO 0x02
#define AC3_INPUT_3F 0x03
#define AC3_INPUT_2F_1R 0x04
#define AC3_INPUT_3F_1R 0x05
#define AC3_INPUT_2F_2R 0x06
#define AC3_INPUT_3F_2R 0x07
/* Mersenne Twister */
#define NMT 624
#define MMT 397
#define MATRIX_A 0x9908b0df
#define UPPER_MASK 0x80000000
#define LOWER_MASK 0x7fffffff
typedef struct {
uint32_t mt[NMT];
int mti;
} dither_state;
/* Mersenne Twister */
typedef struct {
uint32_t flags;
uint16_t crc1;
uint8_t fscod;
uint8_t acmod;
uint8_t cmixlev;
uint8_t surmixlev;
uint8_t dsurmod;
uint8_t blksw;
uint8_t dithflag;
uint8_t cplinu;
uint8_t chincpl;
uint8_t phsflginu;
uint8_t cplbegf;
uint8_t cplendf;
uint8_t cplcoe;
uint32_t cplbndstrc;
uint8_t rematstr;
uint8_t rematflg;
uint8_t cplexpstr;
uint8_t lfeexpstr;
uint8_t chexpstr[5];
uint8_t sdcycod;
uint8_t fdcycod;
uint8_t sgaincod;
uint8_t dbpbcod;
uint8_t floorcod;
uint8_t csnroffst;
uint8_t cplfsnroffst;
uint8_t cplfgaincod;
uint8_t fsnroffst[5];
uint8_t fgaincod[5];
uint8_t lfefsnroffst;
uint8_t lfefgaincod;
uint8_t cplfleak;
uint8_t cplsleak;
uint8_t cpldeltbae;
uint8_t deltbae[5];
uint8_t cpldeltnseg;
uint8_t cpldeltoffst[8];
uint8_t cpldeltlen[8];
uint8_t cpldeltba[8];
uint8_t deltnseg[5];
uint8_t deltoffst[5][8];
uint8_t deltlen[5][8];
uint8_t deltba[5][8];
/* Derived Attributes. */
int sampling_rate;
int bit_rate;
int frame_size;
int nfchans;
int lfeon;
float chcoeffs[6];
float cplco[5][18];
int ncplbnd;
int ncplsubnd;
int cplstrtmant;
int cplendmant;
int endmant[5];
uint8_t dcplexps[256];
uint8_t dexps[5][256];
uint8_t dlfeexps[256];
uint8_t cplbap[256];
uint8_t bap[5][256];
uint8_t lfebap[256];
int blkoutput;
DECLARE_ALIGNED_16(float, transform_coeffs[MAX_CHANNELS][BLOCK_SIZE]);
/* For IMDCT. */
FFTContext fft_64; //N/8 point IFFT context
FFTContext fft_128; //N/4 point IFFT context
DECLARE_ALIGNED_16(float, output[MAX_CHANNELS][BLOCK_SIZE]);
DECLARE_ALIGNED_16(float, delay[MAX_CHANNELS][BLOCK_SIZE]);
DECLARE_ALIGNED_16(float, tmp_imdct[BLOCK_SIZE]);
DECLARE_ALIGNED_16(float, tmp_output[BLOCK_SIZE * 2]);
/* Miscellaneous. */
GetBitContext gb;
dither_state dith_state;
} AC3DecodeContext;
/* BEGIN Mersenne Twister Code. */
static void dither_seed(dither_state *state, uint32_t seed)
{
if (seed == 0)
seed = 0x1f2e3d4c;
state->mt[0] = seed;
for (state->mti = 1; state->mti < NMT; state->mti++)
state->mt[state->mti] = ((69069 * state->mt[state->mti - 1]) + 1);
}
static uint32_t dither_uint32(dither_state *state)
{
uint32_t y;
static const uint32_t mag01[2] = { 0x00, MATRIX_A };
int kk;
if (state->mti >= NMT) {
for (kk = 0; kk < NMT - MMT; kk++) {
y = (state->mt[kk] & UPPER_MASK) | (state->mt[kk + 1] & LOWER_MASK);
state->mt[kk] = state->mt[kk + MMT] ^ (y >> 1) ^ mag01[y & 0x01];
}
for (;kk < NMT - 1; kk++) {
y = (state->mt[kk] & UPPER_MASK) | (state->mt[kk + 1] & LOWER_MASK);
state->mt[kk] = state->mt[kk + (MMT - NMT)] ^ (y >> 1) ^ mag01[y & 0x01];
}
y = (state->mt[NMT - 1] & UPPER_MASK) | (state->mt[0] & LOWER_MASK);
state->mt[NMT - 1] = state->mt[MMT - 1] ^ (y >> 1) ^ mag01[y & 0x01];
state->mti = 0;
}
y = state->mt[state->mti++];
y ^= (y >> 11);
y ^= ((y << 7) & 0x9d2c5680);
y ^= ((y << 15) & 0xefc60000);
y ^= (y >> 18);
return y;
}
static inline int16_t dither_int16(dither_state *state)
{
return ((dither_uint32(state) << 16) >> 16);
}
/* END Mersenne Twister */
static void generate_quantizers_table(int16_t quantizers[], int level, int length)
{
int i;
for (i = 0; i < length; i++)
quantizers[i] = ((2 * i - level + 1) << 15) / level;
}
static void generate_quantizers_table_1(int16_t quantizers[], int level, int length1, int length2, int size)
{
int i, j;
int16_t v;
for (i = 0; i < length1; i++) {
v = ((2 * i - level + 1) << 15) / level;
for (j = 0; j < length2; j++)
quantizers[i * length2 + j] = v;
}
for (i = length1 * length2; i < size; i++)
quantizers[i] = 0;
}
static void generate_quantizers_table_2(int16_t quantizers[], int level, int length1, int length2, int size)
{
int i, j;
int16_t v;
for (i = 0; i < length1; i++) {
v = ((2 * (i % level) - level + 1) << 15) / level;
for (j = 0; j < length2; j++)
quantizers[i * length2 + j] = v;
}
for (i = length1 * length2; i < size; i++)
quantizers[i] = 0;
}
static void generate_quantizers_table_3(int16_t quantizers[], int level, int length1, int length2, int size)
{
int i, j;
for (i = 0; i < length1; i++)
for (j = 0; j < length2; j++)
quantizers[i * length2 + j] = ((2 * (j % level) - level + 1) << 15) / level;
for (i = length1 * length2; i < size; i++)
quantizers[i] = 0;
}
static void ac3_tables_init(void)
{
int i, j, k, l, v;
float alpha;
/* compute bndtab and masktab from bandsz */
k = 0;
l = 0;
for(i=0;i<50;i++) {
bndtab[i] = l;
v = bndsz[i];
for(j=0;j<v;j++) masktab[k++]=i;
l += v;
}
masktab[253] = masktab[254] = masktab[255] = 0;
bndtab[50] = 0;
/* Exponent Decoding Tables */
for (i = 0; i < 5; i++) {
v = i - 2;
for (j = 0; j < 25; j++)
exp_1[i * 25 + j] = v;
}
for (i = 0; i < 25; i++) {
v = (i % 5) - 2;
for (j = 0; j < 5; j++)
exp_2[i * 5 + j] = v;
}
for (i = 0; i < 25; i++) {
v = -2;
for (j = 0; j < 5; j++)
exp_3[i * 5 + j] = v++;
}
for (i = 125; i < 128; i++)
exp_1[i] = exp_2[i] = exp_3[i] = 25;
/* End Exponent Decoding Tables */
/* Quantizer ungrouping tables. */
// for level-3 quantizers
generate_quantizers_table_1(l3_quantizers_1, 3, 3, 9, 32);
generate_quantizers_table_2(l3_quantizers_2, 3, 9, 3, 32);
generate_quantizers_table_3(l3_quantizers_3, 3, 9, 3, 32);
//for level-5 quantizers
generate_quantizers_table_1(l5_quantizers_1, 5, 5, 25, 128);
generate_quantizers_table_2(l5_quantizers_2, 5, 25, 5, 128);
generate_quantizers_table_3(l5_quantizers_3, 5, 25, 5, 128);
//for level-7 quantizers
generate_quantizers_table(l7_quantizers, 7, 7);
//for level-4 quantizers
generate_quantizers_table_2(l11_quantizers_1, 11, 11, 11, 128);
generate_quantizers_table_3(l11_quantizers_2, 11, 11, 11, 128);
//for level-15 quantizers
generate_quantizers_table(l15_quantizers, 15, 15);
/* Twiddle Factors for IMDCT. */
for(i = 0; i < N / 4; i++) {
alpha = 2 * M_PI * (8 * i + 1) / (8 * N);
x_cos1[i] = -cos(alpha);
x_sin1[i] = -sin(alpha);
}
for (i = 0; i < N / 8; i++) {
alpha = 2 * M_PI * (8 * i + 1) / (4 * N);
x_cos2[i] = -cos(alpha);
x_sin2[i] = -sin(alpha);
}
}
static int ac3_decode_init(AVCodecContext *avctx)
{
AC3DecodeContext *ctx = avctx->priv_data;
ac3_tables_init();
ff_fft_init(&ctx->fft_64, 6, 1);
ff_fft_init(&ctx->fft_128, 7, 1);
dither_seed(&ctx->dith_state, 0);
return 0;
}
static int ac3_synchronize(uint8_t *buf, int buf_size)
{
int i;
for (i = 0; i < buf_size - 1; i++)
if (buf[i] == 0x0b && buf[i + 1] == 0x77)
return i;
return -1;
}
//Returns -1 when 'fscod' is not valid;
static int ac3_parse_sync_info(AC3DecodeContext *ctx)
{
GetBitContext *gb = &ctx->gb;
int frmsizecod, bsid;
memset (ctx, sizeof (AC3DecodeContext), 0);
skip_bits(gb, 16); //skip the sync_word, sync_info->sync_word = get_bits(gb, 16);
ctx->crc1 = get_bits(gb, 16);
ctx->fscod = get_bits(gb, 2);
if (ctx->fscod == 0x03)
return 0;
frmsizecod = get_bits(gb, 6);
if (frmsizecod >= 38)
return 0;
ctx->sampling_rate = ac3_freqs[ctx->fscod];
ctx->bit_rate = ac3_bitratetab[frmsizecod >> 1];
/* we include it here in order to determine validity of ac3 frame */
bsid = get_bits(gb, 5);
if (bsid > 0x08)
return 0;
skip_bits(gb, 3); //skip the bsmod, bsi->bsmod = get_bits(gb, 3);
switch (ctx->fscod) {
case 0x00:
ctx->frame_size = 4 * ctx->bit_rate;
return ctx->frame_size;
case 0x01:
ctx->frame_size = 2 * (320 * ctx->bit_rate / 147 + (frmsizecod & 1));
return ctx->frame_size;
case 0x02:
ctx->frame_size = 6 * ctx->bit_rate;
return ctx->frame_size;
}
/* never reached */
return 0;
}
static void ac3_parse_bsi(AC3DecodeContext *ctx)
{
GetBitContext *gb = &ctx->gb;
int i;
ctx->cmixlev = 0;
ctx->surmixlev = 0;
ctx->dsurmod = 0;
ctx->nfchans = 0;
ctx->cpldeltbae = AC3_DBASTR_NONE;
ctx->cpldeltnseg = 0;
for (i = 0; i < 5; i++) {
ctx->deltbae[i] = AC3_DBASTR_NONE;
ctx->deltnseg[i] = 0;
}
ctx->acmod = get_bits(gb, 3);
ctx->nfchans = nfchans_tbl[ctx->acmod];
if (ctx->acmod & 0x01 && ctx->acmod != 0x01)
ctx->cmixlev = get_bits(gb, 2);
if (ctx->acmod & 0x04)
ctx->surmixlev = get_bits(gb, 2);
if (ctx->acmod == 0x02)
ctx->dsurmod = get_bits(gb, 2);
ctx->lfeon = get_bits1(gb);
i = !(ctx->acmod);
do {
skip_bits(gb, 5); //skip dialog normalization
if (get_bits1(gb))
skip_bits(gb, 8); //skip compression
if (get_bits1(gb))
skip_bits(gb, 8); //skip language code
if (get_bits1(gb))
skip_bits(gb, 7); //skip audio production information
} while (i--);
skip_bits(gb, 2); //skip copyright bit and original bitstream bit
if (get_bits1(gb))
skip_bits(gb, 14); //skip timecode1
if (get_bits1(gb))
skip_bits(gb, 14); //skip timecode2
if (get_bits1(gb)) {
i = get_bits(gb, 6); //additional bsi length
do {
skip_bits(gb, 8);
} while(i--);
}
}
/* Decodes the grouped exponents and stores them
* in decoded exponents (dexps).
* The code is derived from liba52.
* Uses liba52 tables.
*/
static int decode_exponents(GetBitContext *gb, int expstr, int ngrps, uint8_t absexp, uint8_t *dexps)
{
int exps;
av_log(NULL, AV_LOG_INFO, "%d\n", ngrps);
while (ngrps--) {
exps = get_bits(gb, 7);
absexp += exp_1[exps];
if (absexp > 24) {
av_log(NULL, AV_LOG_ERROR, "Absolute Exponent > 24, ngrp = %d\n", ngrps);
return -ngrps;
}
switch (expstr) {
case AC3_EXPSTR_D45:
*(dexps++) = absexp;
*(dexps++) = absexp;
case AC3_EXPSTR_D25:
*(dexps++) = absexp;
case AC3_EXPSTR_D15:
*(dexps++) = absexp;
}
absexp += exp_2[exps];
if (absexp > 24) {
av_log(NULL, AV_LOG_ERROR, "Absolute Exponent > 24, ngrp = %d\n", ngrps);
return -ngrps;
}
switch (expstr) {
case AC3_EXPSTR_D45:
*(dexps++) = absexp;
*(dexps++) = absexp;
case AC3_EXPSTR_D25:
*(dexps++) = absexp;
case AC3_EXPSTR_D15:
*(dexps++) = absexp;
}
absexp += exp_3[exps];
if (absexp > 24) {
av_log(NULL, AV_LOG_ERROR, "Absolute Exponent > 24, ngrp = %d\n", ngrps);
return -ngrps;
}
switch (expstr) {
case AC3_EXPSTR_D45:
*(dexps++) = absexp;
*(dexps++) = absexp;
case AC3_EXPSTR_D25:
*(dexps++) = absexp;
case AC3_EXPSTR_D15:
*(dexps++) = absexp;
}
}
return 0;
}
static inline int logadd(int a, int b)
{
int c = a - b;
int address;
address = FFMIN(ABS(c) >> 1, 255);
if (c >= 0)
return (a + latab[address]);
else
return (b + latab[address]);
}
static inline int calc_lowcomp(int a, int b0, int b1, int bin)
{
if (bin < 7) {
if ((b0 + 256) == b1)
a = 384;
else if (b0 > b1)
a = FFMAX(0, a - 64);
}
else if (bin < 20) {
if ((b0 + 256) == b1)
a = 320;
else if (b0 > b1)
a = FFMAX(0, a - 64);
}
else
a = FFMAX(0, a - 128);
return a;
}
/* do the bit allocation for chnl.
* chnl = 0 to 4 - fbw channel
* chnl = 5 coupling channel
* chnl = 6 lfe channel
*/
static void do_bit_allocation1(AC3DecodeContext *ctx, int chnl)
{
int sdecay, fdecay, sgain, dbknee, floor;
int lowcomp = 0, fgain = 0, snroffset = 0, fastleak = 0, slowleak = 0;
int psd[256], bndpsd[50], excite[50], mask[50], delta;
int start = 0, end = 0, bin = 0, i = 0, j = 0, k = 0, lastbin = 0, bndstrt = 0;
int bndend = 0, begin = 0, deltnseg = 0, band = 0, seg = 0, address = 0;
int fscod = ctx->fscod;
uint8_t *exps, *deltoffst = 0, *deltlen = 0, *deltba = 0;
uint8_t *baps;
int do_delta = 0;
/* initialization */
sdecay = sdecaytab[ctx->sdcycod];
fdecay = fdecaytab[ctx->fdcycod];
sgain = sgaintab[ctx->sgaincod];
dbknee = dbkneetab[ctx->dbpbcod];
floor = floortab[ctx->floorcod];
if (chnl == 5) {
start = ctx->cplstrtmant;
end = ctx->cplendmant;
fgain = fgaintab[ctx->cplfgaincod];
snroffset = (((ctx->csnroffst - 15) << 4) + ctx->cplfsnroffst) << 2;
fastleak = (ctx->cplfleak << 8) + 768;
slowleak = (ctx->cplsleak << 8) + 768;
exps = ctx->dcplexps;
baps = ctx->cplbap;
if (ctx->cpldeltbae == AC3_DBASTR_NEW) {
do_delta = 1;
deltnseg = ctx->cpldeltnseg;
deltoffst = ctx->cpldeltoffst;
deltlen = ctx->cpldeltlen;
deltba = ctx->cpldeltba;
}
}
else if (chnl == 6) {
start = 0;
end = 7;
lowcomp = 0;
fastleak = 0;
slowleak = 0;
fgain = fgaintab[ctx->lfefgaincod];
snroffset = (((ctx->csnroffst - 15) << 4) + ctx->lfefsnroffst) << 2;
exps = ctx->dlfeexps;
baps = ctx->lfebap;
}
else {
start = 0;
end = ctx->endmant[chnl];
lowcomp = 0;
fastleak = 0;
slowleak = 0;
fgain = fgaintab[ctx->fgaincod[chnl]];
snroffset = (((ctx->csnroffst - 15) << 4) + ctx->fsnroffst[chnl]) << 2;
exps = ctx->dexps[chnl];
baps = ctx->bap[chnl];
if (ctx->deltbae[chnl] == AC3_DBASTR_NEW) {
do_delta = 1;
deltnseg = ctx->deltnseg[chnl];
deltoffst = ctx->deltoffst[chnl];
deltlen = ctx->deltlen[chnl];
deltba = ctx->deltba[chnl];
}
}
for (bin = start; bin < end; bin++) /* exponent mapping into psd */
psd[bin] = (3072 - ((int)(exps[bin]) << 7));
/* psd integration */
j = start;
k = masktab[start];
do {
lastbin = FFMIN(bndtab[k] + bndsz[k], end);
bndpsd[k] = psd[j];
j++;
for (i = j; i < lastbin; i++) {
bndpsd[k] = logadd(bndpsd[k], psd[j]);
j++;
}
k++;
} while (end > lastbin);
/* compute the excite function */
bndstrt = masktab[start];
bndend = masktab[end - 1] + 1;
if (bndstrt == 0) {
lowcomp = calc_lowcomp(lowcomp, bndpsd[0], bndpsd[1], 0);
excite[0] = bndpsd[0] - fgain - lowcomp;
lowcomp = calc_lowcomp(lowcomp, bndpsd[1], bndpsd[2], 1);
excite[1] = bndpsd[1] - fgain - lowcomp;
begin = 7;
for (bin = 2; bin < 7; bin++) {
if (!(chnl == 6 && bin == 6))
lowcomp = calc_lowcomp(lowcomp, bndpsd[bin], bndpsd[bin + 1], bin);
fastleak = bndpsd[bin] - fgain;
slowleak = bndpsd[bin] - sgain;
excite[bin] = fastleak - lowcomp;
if (!(chnl == 6 && bin == 6))
if (bndpsd[bin] <= bndpsd[bin + 1]) {
begin = bin + 1;
break;
}
}
for (bin = begin; bin < FFMIN(bndend, 22); bin++) {
if (!(chnl == 6 && bin == 6))
lowcomp = calc_lowcomp(lowcomp, bndpsd[bin], bndpsd[bin + 1], bin);
fastleak -= fdecay;
fastleak = FFMAX(fastleak, bndpsd[bin] - fgain);
slowleak -= sdecay;
slowleak = FFMAX(slowleak, bndpsd[bin] - sgain);
excite[bin] = FFMAX(fastleak - lowcomp, slowleak);
}
begin = 22;
}
else {
begin = bndstrt;
}
for (bin = begin; bin < bndend; bin++) {
fastleak -= fdecay;
fastleak = FFMAX(fastleak, bndpsd[bin] - fgain);
slowleak -= sdecay;
slowleak = FFMAX(slowleak, bndpsd[bin] - sgain);
excite[bin] = FFMAX(fastleak, slowleak);
}
/* compute the masking curve */
for (bin = bndstrt; bin < bndend; bin++) {
if (bndpsd[bin] < dbknee)
excite[bin] += ((dbknee - bndpsd[bin]) >> 2);
mask[bin] = FFMAX(excite[bin], hth[bin][fscod]);
}
/* apply the delta bit allocation */
if (do_delta) {
band = 0;
for (seg = 0; seg < deltnseg + 1; seg++) {
band += (int)(deltoffst[seg]);
if ((int)(deltba[seg]) >= 4)
delta = ((int)(deltba[seg]) - 3) << 7;
else
delta = ((int)(deltba[seg]) - 4) << 7;
for (k = 0; k < (int)(deltlen[seg]); k++) {
mask[band] += delta;
band++;
}
}
}
/*compute the bit allocation */
i = start;
j = masktab[start];
do {
lastbin = FFMIN(bndtab[j] + bndsz[j], end);
mask[j] -= snroffset;
mask[j] -= floor;
if (mask[j] < 0)
mask[j] = 0;
mask[j] &= 0x1fe0;
mask[j] += floor;
for (k = i; k < lastbin; k++) {
address = (psd[i] - mask[j]) >> 5;
address = FFMIN(63, FFMAX(0, address));
baps[i] = baptab[address];
i++;
}
j++;
} while (end > lastbin);
}
static void do_bit_allocation(AC3DecodeContext *ctx, int flags)
{
int i, zerosnroffst = 1;
if (!flags) /* bit allocation is not required */
return;
/* Check if snroffsets are zero. */
if ((ctx->csnroffst) || (ctx->chincpl && ctx->cplfsnroffst) ||
(ctx->lfeon && ctx->lfefsnroffst))
zerosnroffst = 0;
if (zerosnroffst)
for (i = 0; i < ctx->nfchans; i++)
if (ctx->fsnroffst[i]) {
zerosnroffst = 0;
break;
}
if (zerosnroffst) {
memset(ctx->cplbap, 0, sizeof (ctx->cplbap));
for (i = 0; i < ctx->nfchans; i++)
memset(ctx->bap[i], 0, sizeof (ctx->bap[i]));
memset(ctx->lfebap, 0, sizeof (ctx->lfebap));
return;
}
/* perform bit allocation */
if (ctx->cplinu && (flags & 64))
do_bit_allocation1(ctx, 5);
for (i = 0; i < ctx->nfchans; i++)
if (flags & (1 << i))
do_bit_allocation1(ctx, i);
if (ctx->lfeon && (flags & 32))
do_bit_allocation1(ctx, 6);
}
typedef struct { /* grouped mantissas for 3-level 5-leve and 11-level quantization */
int16_t l3_quantizers[3];
int16_t l5_quantizers[3];
int16_t l11_quantizers[2];
int l3ptr;
int l5ptr;
int l11ptr;
int bits;
} mant_groups;
#define TRANSFORM_COEFF(tc, m, e, f) (tc) = (m) * (f)[(e)]
/* Get the transform coefficients for coupling channel and uncouple channels.
* The coupling transform coefficients starts at the the cplstrtmant, which is
* equal to endmant[ch] for fbw channels. Hence we can uncouple channels before
* getting transform coefficients for the channel.
*/
static int get_transform_coeffs_cpling(AC3DecodeContext *ctx, mant_groups *m)
{
GetBitContext *gb = &ctx->gb;
int ch, bin, start, end, cplbndstrc, bnd, gcode, tbap;
float cplcos[5], cplcoeff;
uint8_t *exps = ctx->dcplexps;
uint8_t *bap = ctx->cplbap;
int bits_consumed = m->bits;
cplbndstrc = ctx->cplbndstrc;
start = ctx->cplstrtmant;
bnd = 0;
while (start < ctx->cplendmant) {
end = start + 12;
while (cplbndstrc & 1) {
end += 12;
cplbndstrc >>= 1;
}
cplbndstrc >>= 1;
for (ch = 0; ch < ctx->nfchans; ch++)
cplcos[ch] = ctx->chcoeffs[ch] * ctx->cplco[ch][bnd];
bnd++;
while (start < end) {
tbap = bap[start];
switch(tbap) {
case 0:
for (ch = 0; ch < ctx->nfchans; ctx++)
if (((ctx->chincpl) >> ch) & 1) {
if (((ctx->dithflag) >> ch) & 1) {
TRANSFORM_COEFF(cplcoeff, dither_int16(&ctx->dith_state), exps[start], scale_factors);
ctx->transform_coeffs[ch + 1][start] = cplcoeff * cplcos[ch];
} else
ctx->transform_coeffs[ch + 1][start] = 0;
}
start++;
continue;
case 1:
if (m->l3ptr > 2) {
gcode = get_bits(gb, 5);
/*if (gcode > 26)
return -1;*/
m->l3_quantizers[0] = l3_quantizers_1[gcode];
m->l3_quantizers[1] = l3_quantizers_2[gcode];
m->l3_quantizers[2] = l3_quantizers_3[gcode];
m->l3ptr = 0;
m->bits += 5;
}
TRANSFORM_COEFF(cplcoeff, m->l3_quantizers[m->l3ptr++], exps[start], scale_factors);
break;
case 2:
if (m->l5ptr > 2) {
gcode = get_bits(gb, 7);
/*if (gcode > 124)
return -1;*/
m->l5_quantizers[0] = l5_quantizers_1[gcode];
m->l5_quantizers[1] = l5_quantizers_2[gcode];
m->l5_quantizers[2] = l5_quantizers_3[gcode];
m->l5ptr = 0;
m->bits += 7;
}
TRANSFORM_COEFF(cplcoeff, m->l5_quantizers[m->l5ptr++], exps[start], scale_factors);
break;
case 3:
gcode = get_bits(gb, 3);
/*if (gcode > 6)
return -1;*/
m->bits += 3;
TRANSFORM_COEFF(cplcoeff, l7_quantizers[gcode], exps[start], scale_factors);
break;
case 4:
if (m->l11ptr > 1) {
gcode = get_bits(gb, 7);
/*if (gcode > 120)
return -1;*/
m->l11_quantizers[0] = l11_quantizers_1[gcode];
m->l11_quantizers[1] = l11_quantizers_2[gcode];
m->l11ptr = 0;
m->bits += 7;
}
TRANSFORM_COEFF(cplcoeff, m->l11_quantizers[m->l11ptr++], exps[start], scale_factors);
break;
case 5:
gcode = get_bits(gb, 4);
/*if (gcode > 14)
return -1;*/
m->bits += 4;
TRANSFORM_COEFF(cplcoeff, l15_quantizers[gcode], exps[start], scale_factors);
break;
default:
m->bits += qntztab[bap[bin]];
TRANSFORM_COEFF(cplcoeff, get_bits(gb, qntztab[tbap]) << (16 - qntztab[tbap]),
exps[bin], scale_factors);
}
for (ch = 0; ch < ctx->nfchans; ch++)
if ((ctx->chincpl >> ch) & 1)
ctx->transform_coeffs[ch][bin] = cplcoeff * cplcos[ch];
start++;
}
}
bits_consumed = m->bits - bits_consumed;
av_log(NULL, AV_LOG_INFO, "\tbits consumed by coupling = %d\n", bits_consumed);
return 0;
}
/* Get the transform coefficients for particular channel */
static int get_transform_coeffs_ch(uint8_t *exps, uint8_t *bap, float chcoeff,
float *coeffs, int start, int end, int dith_flag, GetBitContext *gb,
dither_state *state, mant_groups *m)
{
int i;
int gcode;
int tbap;
float factors[25];
int bits_consumed = m->bits;
for (i = 0; i < 25; i++)
factors[i] = scale_factors[i] * chcoeff;
for (i = start; i < end; i++) {
tbap = bap[i];
switch (tbap) {
case 0:
if (!dith_flag) {
coeffs[i] = 0;
continue;
}
else {
TRANSFORM_COEFF(coeffs[i], dither_int16(state), exps[i], factors);
coeffs[i] *= LEVEL_PLUS_3DB;
continue;
}
case 1:
if (m->l3ptr > 2) {
gcode = get_bits(gb, 5);
/*if (gcode > 26)
return -1;*/
m->l3_quantizers[0] = l3_quantizers_1[gcode];
m->l3_quantizers[1] = l3_quantizers_2[gcode];
m->l3_quantizers[2] = l3_quantizers_3[gcode];
m->l3ptr = 0;
m->bits += 5;
}
TRANSFORM_COEFF(coeffs[i], m->l3_quantizers[m->l3ptr++], exps[i], factors);
continue;
case 2:
if (m->l5ptr > 2) {
gcode = get_bits(gb, 7);
/*if (gcode > 124)
return -1;*/
m->l5_quantizers[0] = l5_quantizers_1[gcode];
m->l5_quantizers[1] = l5_quantizers_2[gcode];
m->l5_quantizers[2] = l5_quantizers_3[gcode];
m->l5ptr = 0;
m->bits += 7;
}
TRANSFORM_COEFF(coeffs[i], m->l5_quantizers[m->l5ptr++], exps[i], factors);
continue;
case 3:
gcode = get_bits(gb, 3);
/*if (gcode > 6)
return -1; */
m->bits += 3;
TRANSFORM_COEFF(coeffs[i], l7_quantizers[gcode], exps[i], factors);
continue;
case 4:
if (m->l11ptr > 1) {
gcode = get_bits(gb, 7);
/*if (gcode > 120)
return -1;*/
m->l11_quantizers[0] = l11_quantizers_1[gcode];
m->l11_quantizers[1] = l11_quantizers_2[gcode];
m->l11ptr = 0;
m->bits += 7;
}
TRANSFORM_COEFF(coeffs[i], m->l11_quantizers[m->l11ptr++], exps[i], factors);
continue;
case 5:
gcode = get_bits(gb, 4);
/*if (gcode > 14)
return -1;*/
m->bits += 4;
TRANSFORM_COEFF(coeffs[i], l15_quantizers[gcode], exps[i], factors);
continue;
default:
m->bits += qntztab[bap[i]];
TRANSFORM_COEFF(coeffs[i], get_bits(gb, qntztab[tbap]) << (16 - qntztab[tbap]), exps[i], factors);
continue;
}
}
bits_consumed = m->bits - bits_consumed;
av_log(NULL, AV_LOG_INFO, "\tbits consumed by channel = %d\n", bits_consumed);
return 0;
}
static int get_transform_coeffs(AC3DecodeContext * ctx)
{
int i, end;
int got_cplchan = 0;
int dithflag = 0;
mant_groups m;
m.l3ptr = m.l5ptr = m.l11ptr = 3;
m.bits = 0;
for (i = 0; i < ctx->nfchans; i++) {
dithflag = (ctx->dithflag >> i) & 1;
/* transform coefficients for individual channel */
if (get_transform_coeffs_ch(ctx->dexps[i], ctx->bap[i], ctx->chcoeffs[i], ctx->transform_coeffs[i + 1],
0, ctx->endmant[i], dithflag, &ctx->gb, &ctx->dith_state, &m))
return -1;
/* tranform coefficients for coupling channels */
if ((ctx->chincpl >> i) & 1) {
if (!got_cplchan) {
if (get_transform_coeffs_cpling(ctx, &m)) {
av_log(NULL, AV_LOG_ERROR, "error in decoupling channels\n");
return -1;
}
got_cplchan = 1;
}
end = ctx->cplendmant;
} else
end = ctx->endmant[i];
do
ctx->transform_coeffs[i + 1][end] = 0;
while(++end < 256);
}
if (ctx->lfeon) {
if (get_transform_coeffs_ch(ctx->dlfeexps, ctx->lfebap, 1.0f, ctx->transform_coeffs[0], 0, 7, 0, &ctx->gb, &ctx->dith_state, &m))
return -1;
for (i = 7; i < 256; i++) {
ctx->transform_coeffs[0][i] = 0;
}
}
av_log(NULL, AV_LOG_INFO, "bits consumed by get_transform_coeffs = %d\n", m.bits);
return 0;
}
static void do_rematrixing1(AC3DecodeContext *ctx, int start, int end)
{
float tmp0, tmp1;
while (start < end) {
tmp0 = ctx->transform_coeffs[1][start];
tmp1 = ctx->transform_coeffs[2][start];
ctx->transform_coeffs[1][start] = tmp0 + tmp1;
ctx->transform_coeffs[2][start] = tmp0 - tmp1;
start++;
}
}
static void do_rematrixing(AC3DecodeContext *ctx)
{
uint8_t bnd1 = 13, bnd2 = 25, bnd3 = 37, bnd4 = 61;
uint8_t bndend;
bndend = FFMIN(ctx->endmant[0], ctx->endmant[1]);
if (ctx->rematflg & 1)
do_rematrixing1(ctx, bnd1, bnd2);
if (ctx->rematflg & 2)
do_rematrixing1(ctx, bnd2, bnd3);
if (ctx->rematflg & 4) {
if (ctx->cplbegf > 0 && ctx->cplbegf <= 2 && (ctx->chincpl))
do_rematrixing1(ctx, bnd3, bndend);
else {
do_rematrixing1(ctx, bnd3, bnd4);
if (ctx->rematflg & 8)
do_rematrixing1(ctx, bnd4, bndend);
}
}
}
static void get_downmix_coeffs(AC3DecodeContext *ctx)
{
int from = ctx->acmod;
int to = ctx->blkoutput;
float clev = clevs[ctx->cmixlev];
float slev = slevs[ctx->surmixlev];
if (to == AC3_OUTPUT_UNMODIFIED)
return;
switch (from) {
case AC3_INPUT_DUALMONO:
switch (to) {
case AC3_OUTPUT_MONO:
case AC3_OUTPUT_STEREO: /* We Assume that sum of both mono channels is requested */
ctx->chcoeffs[0] *= LEVEL_MINUS_6DB;
ctx->chcoeffs[1] *= LEVEL_MINUS_6DB;
break;
}
break;
case AC3_INPUT_MONO:
switch (to) {
case AC3_OUTPUT_STEREO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
break;
}
break;
case AC3_INPUT_STEREO:
switch (to) {
case AC3_OUTPUT_MONO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[1] *= LEVEL_MINUS_3DB;
break;
}
break;
case AC3_INPUT_3F:
switch (to) {
case AC3_OUTPUT_MONO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[2] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[1] *= clev * LEVEL_PLUS_3DB;
break;
case AC3_OUTPUT_STEREO:
ctx->chcoeffs[1] *= clev;
break;
}
break;
case AC3_INPUT_2F_1R:
switch (to) {
case AC3_OUTPUT_MONO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[1] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[2] *= slev * LEVEL_MINUS_3DB;
break;
case AC3_OUTPUT_STEREO:
ctx->chcoeffs[2] *= slev * LEVEL_MINUS_3DB;
break;
case AC3_OUTPUT_DOLBY:
ctx->chcoeffs[2] *= LEVEL_MINUS_3DB;
break;
}
break;
case AC3_INPUT_3F_1R:
switch (to) {
case AC3_OUTPUT_MONO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[2] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[1] *= clev * LEVEL_PLUS_3DB;
ctx->chcoeffs[3] *= slev * LEVEL_MINUS_3DB;
break;
case AC3_OUTPUT_STEREO:
ctx->chcoeffs[1] *= clev;
ctx->chcoeffs[3] *= slev * LEVEL_MINUS_3DB;
break;
case AC3_OUTPUT_DOLBY:
ctx->chcoeffs[1] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[3] *= LEVEL_MINUS_3DB;
break;
}
break;
case AC3_INPUT_2F_2R:
switch (to) {
case AC3_OUTPUT_MONO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[1] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[2] *= slev * LEVEL_MINUS_3DB;
ctx->chcoeffs[3] *= slev * LEVEL_MINUS_3DB;
break;
case AC3_OUTPUT_STEREO:
ctx->chcoeffs[2] *= slev;
ctx->chcoeffs[3] *= slev;
break;
case AC3_OUTPUT_DOLBY:
ctx->chcoeffs[2] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[3] *= LEVEL_MINUS_3DB;
break;
}
break;
case AC3_INPUT_3F_2R:
switch (to) {
case AC3_OUTPUT_MONO:
ctx->chcoeffs[0] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[2] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[1] *= clev * LEVEL_PLUS_3DB;
ctx->chcoeffs[3] *= slev * LEVEL_MINUS_3DB;
ctx->chcoeffs[4] *= slev * LEVEL_MINUS_3DB;
break;
case AC3_OUTPUT_STEREO:
ctx->chcoeffs[1] *= clev;
ctx->chcoeffs[3] *= slev;
ctx->chcoeffs[4] *= slev;
break;
case AC3_OUTPUT_DOLBY:
ctx->chcoeffs[1] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[3] *= LEVEL_MINUS_3DB;
ctx->chcoeffs[4] *= LEVEL_MINUS_3DB;
break;
}
break;
}
}
static inline void mix_dualmono_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] += output[2][i];
memset(output[2], 0, sizeof(output[2]));
}
static inline void mix_dualmono_to_stereo(AC3DecodeContext *ctx)
{
int i;
float tmp;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
tmp = output[1][i] + output[2][i];
output[1][i] = output[2][i] = tmp;
}
}
static inline void upmix_mono_to_stereo(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[2][i] = output[1][i];
}
static inline void mix_stereo_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] += output[2][i];
memset(output[2], 0, sizeof(output[2]));
}
static inline void mix_3f_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] += (output[2][i] + output[3][i]);
memset(output[2], 0, sizeof(output[2]));
memset(output[3], 0, sizeof(output[3]));
}
static inline void mix_3f_to_stereo(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += output[2][i];
output[2][i] += output[3][i];
}
memset(output[3], 0, sizeof(output[3]));
}
static inline void mix_2f_1r_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] += (output[2][i] + output[3][i]);
memset(output[2], 0, sizeof(output[2]));
memset(output[3], 0, sizeof(output[3]));
}
static inline void mix_2f_1r_to_stereo(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += output[2][i];
output[2][i] += output[3][i];
}
memset(output[3], 0, sizeof(output[3]));
}
static inline void mix_2f_1r_to_dolby(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] -= output[3][i];
output[2][i] += output[3][i];
}
memset(output[3], 0, sizeof(output[3]));
}
static inline void mix_3f_1r_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] = (output[2][i] + output[3][i] + output[4][i]);
memset(output[2], 0, sizeof(output[2]));
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
}
static inline void mix_3f_1r_to_stereo(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += (output[2][i] + output[4][i]);
output[2][i] += (output[3][i] + output[4][i]);
}
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
}
static inline void mix_3f_1r_to_dolby(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += (output[2][i] - output[4][i]);
output[2][i] += (output[3][i] + output[4][i]);
}
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
}
static inline void mix_2f_2r_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] = (output[2][i] + output[3][i] + output[4][i]);
memset(output[2], 0, sizeof(output[2]));
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
}
static inline void mix_2f_2r_to_stereo(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += output[3][i];
output[2][i] += output[4][i];
}
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
}
static inline void mix_2f_2r_to_dolby(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] -= output[3][i];
output[2][i] += output[4][i];
}
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
}
static inline void mix_3f_2r_to_mono(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++)
output[1][i] += (output[2][i] + output[3][i] + output[4][i] + output[5][i]);
memset(output[2], 0, sizeof(output[2]));
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
memset(output[5], 0, sizeof(output[5]));
}
static inline void mix_3f_2r_to_stereo(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += (output[2][i] + output[4][i]);
output[2][i] += (output[3][i] + output[5][i]);
}
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
memset(output[5], 0, sizeof(output[5]));
}
static inline void mix_3f_2r_to_dolby(AC3DecodeContext *ctx)
{
int i;
float (*output)[BLOCK_SIZE] = ctx->output;
for (i = 0; i < 256; i++) {
output[1][i] += (output[2][i] - output[4][i] - output[5][i]);
output[2][i] += (output[3][i] + output[4][i] + output[5][i]);
}
memset(output[3], 0, sizeof(output[3]));
memset(output[4], 0, sizeof(output[4]));
memset(output[5], 0, sizeof(output[5]));
}
static void do_downmix(AC3DecodeContext *ctx)
{
int from = ctx->acmod;
int to = ctx->blkoutput;
switch (from) {
case AC3_INPUT_DUALMONO:
switch (to) {
case AC3_OUTPUT_MONO:
mix_dualmono_to_mono(ctx);
break;
case AC3_OUTPUT_STEREO: /* We assume that sum of both mono channels is requested */
mix_dualmono_to_stereo(ctx);
break;
}
break;
case AC3_INPUT_MONO:
switch (to) {
case AC3_OUTPUT_STEREO:
upmix_mono_to_stereo(ctx);
break;
}
break;
case AC3_INPUT_STEREO:
switch (to) {
case AC3_OUTPUT_MONO:
mix_stereo_to_mono(ctx);
break;
}
break;
case AC3_INPUT_3F:
switch (to) {
case AC3_OUTPUT_MONO:
mix_3f_to_mono(ctx);
break;
case AC3_OUTPUT_STEREO:
mix_3f_to_stereo(ctx);
break;
}
break;
case AC3_INPUT_2F_1R:
switch (to) {
case AC3_OUTPUT_MONO:
mix_2f_1r_to_mono(ctx);
break;
case AC3_OUTPUT_STEREO:
mix_2f_1r_to_stereo(ctx);
break;
case AC3_OUTPUT_DOLBY:
mix_2f_1r_to_dolby(ctx);
break;
}
break;
case AC3_INPUT_3F_1R:
switch (to) {
case AC3_OUTPUT_MONO:
mix_3f_1r_to_mono(ctx);
break;
case AC3_OUTPUT_STEREO:
mix_3f_1r_to_stereo(ctx);
break;
case AC3_OUTPUT_DOLBY:
mix_3f_1r_to_dolby(ctx);
break;
}
break;
case AC3_INPUT_2F_2R:
switch (to) {
case AC3_OUTPUT_MONO:
mix_2f_2r_to_mono(ctx);
break;
case AC3_OUTPUT_STEREO:
mix_2f_2r_to_stereo(ctx);
break;
case AC3_OUTPUT_DOLBY:
mix_2f_2r_to_dolby(ctx);
break;
}
break;
case AC3_INPUT_3F_2R:
switch (to) {
case AC3_OUTPUT_MONO:
mix_3f_2r_to_mono(ctx);
break;
case AC3_OUTPUT_STEREO:
mix_3f_2r_to_stereo(ctx);
break;
case AC3_OUTPUT_DOLBY:
mix_3f_2r_to_dolby(ctx);
break;
}
break;
}
}
static void dump_floats(const char *name, int prec, const float *tab, int n)
{
int i;
av_log(NULL, AV_LOG_INFO, "%s[%d]:\n", name, n);
for(i=0;i<n;i++) {
if ((i & 7) == 0)
av_log(NULL, AV_LOG_INFO, "%4d: ", i);
av_log(NULL, AV_LOG_INFO, " %8.*f", prec, tab[i]);
if ((i & 7) == 7)
av_log(NULL, AV_LOG_INFO, "\n");
}
if ((i & 7) != 0)
av_log(NULL, AV_LOG_INFO, "\n");
}
#define CMUL(pre, pim, are, aim, bre, bim) \
{\
float _are = (are);\
float _aim = (aim);\
float _bre = (bre);\
float _bim = (bim);\
(pre) = _are * _bre - _aim * _bim;\
(pim) = _are * _bim + _aim * _bre;\
}
static void do_imdct_256(FFTContext *fft_ctx, float *coeffs, float *output,
float *delay, float *tmp_imdct, float *tmp_output)
{
int k, n2, n4, n8;
float x1[128], x2[128];
FFTComplex *z1 = (FFTComplex *)tmp_imdct;
FFTComplex *z2 = (FFTComplex *)(tmp_imdct + 128);
n2 = N / 2;
n4 = N / 4;
n8 = N / 8;
for (k = 0; k < n4; k++) {
x1[k] = coeffs[2 * k];
x2[k] = coeffs[2 * k + 1];
}
/* Pre IFFT Complex Multiply Step. */
for (k = 0; k < n8; k++) {
CMUL(z1[k].re, z1[k].im, x1[n4 - 2 * k - 1], x1[2 * k], x_cos2[k], x_sin2[k]);
CMUL(z2[k].re, z2[k].im, x2[n4 - 2 * k - 1], x2[2 * k], x_cos2[k], x_sin2[k]);
}
/* Permutation needed before calling ff_fft_calc. */
ff_fft_permute(fft_ctx, z1);
ff_fft_permute(fft_ctx, z2);
/* N/8 pointe complex IFFT. */
ff_fft_calc(fft_ctx, z1);
ff_fft_calc(fft_ctx, z2);
/* Post IFFT Complex Multiply Step. */
for (k = 0; k < n8; k++) {
CMUL(z1[k].re, z1[k].im, z1[k].re, z1[k].im, x_cos2[k], x_sin2[k]);
CMUL(z2[k].re, z2[k].im, z2[k].re, z2[k].im, x_cos2[k], x_sin2[k]);
}
/* Windowing and de-interleaving step. */
for (k = 0; k < n8; k++) {
tmp_output[2 * k] = -z1[k].im * window[2 * k];
tmp_output[2 * k + 1] = z1[n8 - k - 1].re * window[2 * k + 1];
tmp_output[n4 + 2 * k] = -z1[k].re * window[n4 + 2 * k];
tmp_output[n4 + 2 * k + 1] = z1[n8 - k - 1].im * window[n4 + 2 * k + 1];
tmp_output[n2 + 2 * k] = -z2[k].re * window[n2 - 2 * k - 1];
tmp_output[n2 + 2* k + 1] = z2[n8 - k - 1].im * window[n2 - 2 * k - 2];
tmp_output[3 * n4 + 2 * k] = z2[k].im * window[n4 - 2 * k - 1] ;
tmp_output[3 * n4 + 2 * k + 1] = -z2[n8 - k - 1].re * window[n4 - 2 * k - 2] ;
}
/* Overlap and add step. */
for (k = 0; k < n2; k++) {
output[k] = 2 * (tmp_output[k] + delay[k]);
delay[k] = tmp_output[n2 + k];
}
}
static void do_imdct_512(FFTContext *fft_ctx, float *coeffs, float *output,
float *delay, float *tmp_imdct, float *tmp_output)
{
int k, n2, n4, n8;
FFTComplex *z = (FFTComplex *)tmp_imdct;
n2 = N / 2;
n4 = N / 4;
n8 = N / 8;
/* Pre IFFT Complex Multiply Step. */
for (k = 0; k < n4; k++)
CMUL(z[k].re, z[k].im, coeffs[n2 - 2 * k - 1], coeffs[2 * k], x_cos1[k], x_sin1[k]);
/* Permutation needed before calling ff_fft_calc. */
ff_fft_permute(fft_ctx, z);
/* N/4 pointe complex IFFT. */
ff_fft_calc(fft_ctx, z);
/* Post IFFT Complex Multiply Step. */
for (k = 0; k < n4; k++)
CMUL(z[k].re, z[k].im, z[k].re, z[k].im, x_cos1[k], x_sin1[k]);
/* Windowing and de-interleaving step. */
for (k = 0; k < n8; k++) {
tmp_output[2 * k] = -z[n8 + k].im * window[2 * k];
tmp_output[2 * k + 1] = z[n8 - k - 1].re * window[2 * k + 1];
tmp_output[n4 + 2 * k] = -z[k].re * window[n4 + 2 * k];
tmp_output[n4 + 2 * k + 1] = z[n4 - k - 1].im * window[n4 + 2 * k + 1];
tmp_output[n2 + 2 * k] = -z[n8 + k].re * window[n2 - 2 * k - 1];
tmp_output[n2 + 2* k + 1] = z[n8 - k - 1].im * window[n2 - 2 * k - 2];
tmp_output[3 * n4 + 2 * k] = z[k].im * window[n4 - 2 * k - 1] ;
tmp_output[3 * n4 + 2 * k + 1] = -z[n4 - k - 1].re * window[n4 - 2 * k - 2] ;
}
/* Overlap and add step. */
for (k = 0; k < n2; k++) {
output[k] = 2 * (tmp_output[k] + delay[k]);
delay[k] = tmp_output[n2 + k];
}
}
static inline void do_imdct(AC3DecodeContext *ctx)
{
int i;
if (ctx->blkoutput & AC3_OUTPUT_LFEON) {
do_imdct_512(&ctx->fft_128, ctx->transform_coeffs[0], ctx->output[0],
ctx->delay[0], ctx->tmp_imdct, ctx->tmp_output);
}
for (i = 0; i < ctx->nfchans + 1; i++) {
if (!(((ctx->blksw) >> i) & 1)) {
do_imdct_512(&ctx->fft_128, ctx->transform_coeffs[i + 1], ctx->output[i + 1],
ctx->delay[i + 1], ctx->tmp_imdct, ctx->tmp_output);
} else {
do_imdct_256(&ctx->fft_64, ctx->transform_coeffs[i + 1], ctx->output[i + 1],
ctx->delay[i + 1], ctx->tmp_imdct, ctx->tmp_output);
}
}
}
static int ac3_parse_audio_block(AC3DecodeContext * ctx)
{
int nfchans = ctx->nfchans;
int acmod = ctx->acmod;
int i, bnd, rbnd, seg, grpsize;
GetBitContext *gb = &ctx->gb;
int bit_alloc_flags = 0;
float drange, tmpco;
uint8_t *dexps;
int mstrcplco, cplcoexp, cplcomant, sbnd, cplbndstrc;
int dynrng, chbwcod, ngrps, cplabsexp, skipl;
for (i = 0; i < 5; i++)
ctx->chcoeffs[i] = 1.0;
for (i = 0; i < nfchans; i++) /*block switch flag */
ctx->blksw |= get_bits1(gb) << i;
for (i = 0; i < nfchans; i++) /* dithering flag */
ctx->dithflag |= get_bits1(gb) << i;
if (get_bits1(gb)) { /* dynamic range */
dynrng = get_bits(gb, 8);
drange = ((((dynrng & 0x1f) | 0x20) << 13) * scale_factors[3 - (dynrng >> 5)]);
for (i = 0; i < nfchans; i++)
ctx->chcoeffs[i] *= drange;
}
if (acmod == 0x00 && get_bits1(gb)) { /* dynamic range 1+1 mode */
dynrng = get_bits(gb, 8);
drange = ((((dynrng & 0x1f) | 0x20) << 13) * scale_factors[3 - (dynrng >> 5)]);
ctx->chcoeffs[1] *= drange;
}
get_downmix_coeffs(ctx);
if (get_bits1(gb)) { /* coupling strategy */
ctx->cplinu = get_bits1(gb);
if (ctx->cplinu) { /* coupling in use */
ctx->chincpl = 0;
for (i = 0; i < nfchans; i++)
ctx->chincpl |= get_bits1(gb) << i;
if (acmod == 0x00 || acmod == 0x01) //atleast two shared channels required
return -1;
if (acmod == 0x02)
ctx->phsflginu = get_bits1(gb); //phase flag in use
ctx->cplbegf = get_bits(gb, 4);
ctx->cplendf = get_bits(gb, 4);
if (3 + ctx->cplendf - ctx->cplbegf < 0) {
av_log(NULL, AV_LOG_ERROR, "cplendf = %d < cplbegf = %d\n", ctx->cplendf, ctx->cplbegf);
return -1;
}
ctx->ncplbnd = ctx->ncplsubnd = 3 + ctx->cplendf - ctx->cplbegf;
ctx->cplstrtmant = ctx->cplbegf * 12 + 37;
ctx->cplendmant = ctx->cplendf * 12 + 73;
ctx->cplbndstrc = 0;
for (i = 0; i < ctx->ncplsubnd - 1; i++) /* coupling band structure */
if (get_bits1(gb)) {
ctx->cplbndstrc |= 1 << i;
ctx->ncplbnd--;
}
}
}
if (ctx->cplinu) {
ctx->cplcoe = 0;
for (i = 0; i < nfchans; i++)
if ((ctx->chincpl) >> i & 1)
if (get_bits1(gb)) { /* coupling co-ordinates */
ctx->cplcoe = 1;
mstrcplco = 3 * get_bits(gb, 2);
cplbndstrc = ctx->cplbndstrc;
for (bnd = 0; bnd < ctx->ncplbnd; bnd++) {
cplcoexp = get_bits(gb, 4);
cplcomant = get_bits(gb, 4);
if (cplcoexp == 15)
cplcomant <<= 14;
else
cplcomant = (cplcomant | 0x10) << 13;
ctx->cplco[i][bnd] = cplcomant * scale_factors[cplcoexp + mstrcplco];
}
}
if (acmod == 0x02 && ctx->phsflginu && ctx->cplcoe)
for (bnd = 0; bnd < ctx->ncplbnd; bnd++)
if (get_bits1(gb))
ctx->cplco[1][bnd] = -ctx->cplco[1][bnd];
}
if (acmod == 0x02) {/* rematrixing */
ctx->rematstr = get_bits1(gb);
if (ctx->rematstr) {
ctx->rematflg = 0;
if (!(ctx->cplinu) || ctx->cplbegf > 2)
for (rbnd = 0; rbnd < 4; rbnd++)
ctx->rematflg |= get_bits1(gb) << rbnd;
if (ctx->cplbegf > 0 && ctx->cplbegf <= 2 && ctx->cplinu)
for (rbnd = 0; rbnd < 3; rbnd++)
ctx->rematflg |= get_bits1(gb) << rbnd;
if (ctx->cplbegf == 0 && ctx->cplinu)
for (rbnd = 0; rbnd < 2; rbnd++)
ctx->rematflg |= get_bits1(gb) << rbnd;
}
}
ctx->cplexpstr = AC3_EXPSTR_REUSE;
ctx->lfeexpstr = AC3_EXPSTR_REUSE;
if (ctx->cplinu) /* coupling exponent strategy */
ctx->cplexpstr = get_bits(gb, 2);
for (i = 0; i < nfchans; i++) /* channel exponent strategy */
ctx->chexpstr[i] = get_bits(gb, 2);
if (ctx->lfeon) /* lfe exponent strategy */
ctx->lfeexpstr = get_bits1(gb);
for (i = 0; i < nfchans; i++) /* channel bandwidth code */
if (ctx->chexpstr[i] != AC3_EXPSTR_REUSE) {
if ((ctx->chincpl >> i) & 1)
ctx->endmant[i] = ctx->cplstrtmant;
else {
chbwcod = get_bits(gb, 6);
if (chbwcod > 60) {
av_log(NULL, AV_LOG_ERROR, "chbwcod = %d > 60", chbwcod);
return -1;
}
ctx->endmant[i] = chbwcod * 3 + 73;
av_log(NULL, AV_LOG_INFO, "i = %d \t chbwcod = %d \t endmant = %d\n", i, chbwcod, ctx->endmant[i]);
}
}
if (ctx->cplexpstr != AC3_EXPSTR_REUSE) {/* coupling exponents */
bit_alloc_flags |= 64;
cplabsexp = get_bits(gb, 4) << 1;
ngrps = (ctx->cplendmant - ctx->cplstrtmant) / (3 << (ctx->cplexpstr - 1));
if (decode_exponents(gb, ctx->cplexpstr, ngrps, cplabsexp, ctx->dcplexps + ctx->cplstrtmant)) {
av_log(NULL, AV_LOG_ERROR, "error decoding coupling exponents\n");
return -1;
}
}
for (i = 0; i < nfchans; i++) /* fbw channel exponents */
if (ctx->chexpstr[i] != AC3_EXPSTR_REUSE) {
bit_alloc_flags |= 1 << i;
grpsize = 3 << (ctx->chexpstr[i] - 1);
ngrps = (ctx->endmant[i] + grpsize - 4) / grpsize;
dexps = ctx->dexps[i];
dexps[0] = get_bits(gb, 4);
if (decode_exponents(gb, ctx->chexpstr[i], ngrps, dexps[0], dexps + 1)) {
av_log(NULL, AV_LOG_ERROR, "error decoding channel %d exponents\n", i);
return -1;
}
skip_bits(gb, 2); /* skip gainrng */
}
if (ctx->lfeexpstr != AC3_EXPSTR_REUSE) { /* lfe exponents */
bit_alloc_flags |= 32;
ctx->dlfeexps[0] = get_bits(gb, 4);
if (decode_exponents(gb, ctx->lfeexpstr, 2, ctx->dlfeexps[0], ctx->dlfeexps + 1)) {
av_log(NULL, AV_LOG_ERROR, "error decoding lfe exponents\n");
return -1;
}
}
if (get_bits1(gb)) { /* bit allocation information */
bit_alloc_flags |= 127;
ctx->sdcycod = get_bits(gb, 2);
ctx->fdcycod = get_bits(gb, 2);
ctx->sgaincod = get_bits(gb, 2);
ctx->dbpbcod = get_bits(gb, 2);
ctx->floorcod = get_bits(gb, 3);
}
if (get_bits1(gb)) { /* snroffset */
bit_alloc_flags |= 127;
ctx->csnroffst = get_bits(gb, 6);
if (ctx->cplinu) { /* couling fine snr offset and fast gain code */
ctx->cplfsnroffst = get_bits(gb, 4);
ctx->cplfgaincod = get_bits(gb, 3);
}
for (i = 0; i < nfchans; i++) { /* channel fine snr offset and fast gain code */
ctx->fsnroffst[i] = get_bits(gb, 4);
ctx->fgaincod[i] = get_bits(gb, 3);
}
if (ctx->lfeon) { /* lfe fine snr offset and fast gain code */
ctx->lfefsnroffst = get_bits(gb, 4);
ctx->lfefgaincod = get_bits(gb, 3);
}
}
ctx->cplfleak = 0;
ctx->cplsleak = 0;
if (ctx->cplinu && get_bits1(gb)) { /* coupling leak information */
bit_alloc_flags |= 64;
ctx->cplfleak = get_bits(gb, 3);
ctx->cplsleak = get_bits(gb, 3);
}
if (get_bits1(gb)) { /* delta bit allocation information */
bit_alloc_flags |= 127;
if (ctx->cplinu) {
ctx->cpldeltbae = get_bits(gb, 2);
if (ctx->cpldeltbae == AC3_DBASTR_RESERVED) {
av_log(NULL, AV_LOG_ERROR, "coupling delta bit allocation strategy reserved\n");
return -1;
}
}
for (i = 0; i < nfchans; i++) {
ctx->deltbae[i] = get_bits(gb, 2);
if (ctx->deltbae[i] == AC3_DBASTR_RESERVED) {
av_log(NULL, AV_LOG_ERROR, "delta bit allocation strategy reserved\n");
return -1;
}
}
if (ctx->cplinu)
if (ctx->cpldeltbae == AC3_DBASTR_NEW) { /*coupling delta offset, len and bit allocation */
ctx->cpldeltnseg = get_bits(gb, 3);
for (seg = 0; seg <= ctx->cpldeltnseg; seg++) {
ctx->cpldeltoffst[seg] = get_bits(gb, 5);
ctx->cpldeltlen[seg] = get_bits(gb, 4);
ctx->cpldeltba[seg] = get_bits(gb, 3);
}
}
for (i = 0; i < nfchans; i++)
if (ctx->deltbae[i] == AC3_DBASTR_NEW) {/*channel delta offset, len and bit allocation */
ctx->deltnseg[i] = get_bits(gb, 3);
for (seg = 0; seg <= ctx->deltnseg[i]; seg++) {
ctx->deltoffst[i][seg] = get_bits(gb, 5);
ctx->deltlen[i][seg] = get_bits(gb, 4);
ctx->deltba[i][seg] = get_bits(gb, 3);
}
}
}
do_bit_allocation (ctx, bit_alloc_flags); /* perform the bit allocation */
if (get_bits1(gb)) { /* unused dummy data */
skipl = get_bits(gb, 9);
while(skipl--)
skip_bits(gb, 8);
}
/* unpack the transform coefficients
* * this also uncouples channels if coupling is in use.
*/
if (get_transform_coeffs(ctx)) {
av_log(NULL, AV_LOG_ERROR, "Error in routine get_transform_coeffs\n");
return -1;
}
/*for (i = 0; i < nfchans; i++)
dump_floats("channel transform coefficients", 10, ctx->transform_coeffs[i + 1], BLOCK_SIZE);*/
/* recover coefficients if rematrixing is in use */
if (ctx->rematflg)
do_rematrixing(ctx);
do_imdct(ctx);
/*for(i = 0; i < nfchans; i++)
dump_floats("channel output", 10, ctx->output[i + 1], BLOCK_SIZE);*/
do_downmix(ctx);
return 0;
}
static inline int16_t convert(float f)
{
int a;
a = lrintf(f * 32767.0);
return ((int16_t)a);
}
static int frame_count = 0;
static int ac3_decode_frame(AVCodecContext * avctx, void *data, int *data_size, uint8_t *buf, int buf_size)
{
AC3DecodeContext *ctx = (AC3DecodeContext *)avctx->priv_data;
int frame_start;
int16_t *out_samples = (int16_t *)data;
int i, j, k, value;
av_log(NULL, AV_LOG_INFO, "decoding frame %d buf_size = %d\n", frame_count++, buf_size);
//Synchronize the frame.
frame_start = ac3_synchronize(buf, buf_size);
if (frame_start == -1) {
av_log(avctx, AV_LOG_ERROR, "frame is not synchronized\n");
*data_size = 0;
return buf_size;
}
//Initialize the GetBitContext with the start of valid AC3 Frame.
init_get_bits(&(ctx->gb), buf + frame_start, (buf_size - frame_start) * 8);
//Parse the syncinfo.
//If 'fscod' or 'bsid' is not valid the decoder shall mute as per the standard.
if (!ac3_parse_sync_info(ctx)) {
av_log(avctx, AV_LOG_ERROR, "\n");
*data_size = 0;
return buf_size;
}
//Check for the errors.
/* if (ac3_error_check(ctx)) {
*data_size = 0;
return -1;
} */
//Parse the BSI.
//If 'bsid' is not valid decoder shall not decode the audio as per the standard.
ac3_parse_bsi(ctx);
avctx->sample_rate = ctx->sampling_rate;
avctx->bit_rate = ctx->bit_rate;
avctx->channels = 0;
if (avctx->channels == 0) {
ctx->blkoutput |= AC3_OUTPUT_UNMODIFIED;
avctx->channels = ctx->nfchans;
} else if (ctx->nfchans + ctx->lfeon < avctx->channels) {
av_log(avctx, AV_LOG_INFO, "ac3_decoder: AC3 Source Channels Are Less Then Specified %d: Output to %d Channels\n",
avctx->channels, ctx->nfchans + ctx->lfeon);
avctx->channels = ctx->nfchans;
ctx->blkoutput |= AC3_OUTPUT_UNMODIFIED;
} else if (avctx->channels == 1) {
ctx->blkoutput |= AC3_OUTPUT_MONO;
} else if (avctx->channels == 2) {
if (ctx->dsurmod == 0x02)
ctx->blkoutput |= AC3_OUTPUT_DOLBY;
else
ctx->blkoutput |= AC3_OUTPUT_STEREO;
}
if (ctx->lfeon) {
avctx->channels++;
ctx->blkoutput |= AC3_OUTPUT_LFEON;
}
av_log(avctx, AV_LOG_INFO, "channels = %d \t bit rate = %d \t sampling rate = %d \n", avctx->channels, avctx->bit_rate * 1000, avctx->sample_rate);
//Parse the Audio Blocks.
for (i = 0; i < AUDIO_BLOCKS; i++) {
if (ac3_parse_audio_block(ctx)) {
av_log(avctx, AV_LOG_ERROR, "error parsing the audio block\n");
*data_size = 0;
return ctx->frame_size;
}
j = ((ctx->blkoutput & AC3_OUTPUT_LFEON) ? 0 : 1);
for (k = 0; k < BLOCK_SIZE; k++) {
j = ((ctx->blkoutput & AC3_OUTPUT_LFEON) ? 0 : 1);
for (;j < avctx->channels + 1; j++) {
value = convert(ctx->output[j][k]);
*(out_samples++) = value;
}
}
}
*data_size = AUDIO_BLOCKS * BLOCK_SIZE * avctx->channels * sizeof (int16_t);
return ctx->frame_size;
}
static int ac3_decode_end(AVCodecContext *ctx)
{
return 0;
}
AVCodec lgpl_ac3_decoder = {
"ac3",
CODEC_TYPE_AUDIO,
CODEC_ID_AC3,
sizeof (AC3DecodeContext),
ac3_decode_init,
NULL,
ac3_decode_end,
ac3_decode_frame,
};
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