1
0
mirror of https://github.com/FFmpeg/FFmpeg.git synced 2024-11-21 10:55:51 +02:00
FFmpeg/libavcodec/eac3dec.c

608 lines
22 KiB
C

/*
* E-AC-3 decoder
* Copyright (c) 2007 Bartlomiej Wolowiec <bartek.wolowiec@gmail.com>
* Copyright (c) 2008 Justin Ruggles
*
* This file is part of Libav.
*
* Libav 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 2.1 of the License, or (at your option) any later version.
*
* Libav 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 Libav; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*
* There are several features of E-AC-3 that this decoder does not yet support.
*
* Enhanced Coupling
* No known samples exist. If any ever surface, this feature should not be
* too difficult to implement.
*
* Reduced Sample Rates
* No known samples exist. The spec also does not give clear information
* on how this is to be implemented.
*
* Dependent Streams
* Only the independent stream is currently decoded. Any dependent
* streams are skipped. We have only come across two examples of this, and
* they are both just test streams, one for HD-DVD and the other for
* Blu-ray.
*
* Transient Pre-noise Processing
* This is side information which a decoder should use to reduce artifacts
* caused by transients. There are samples which are known to have this
* information, but this decoder currently ignores it.
*/
#include "avcodec.h"
#include "internal.h"
#include "aac_ac3_parser.h"
#include "ac3.h"
#include "ac3_parser.h"
#include "ac3dec.h"
#include "ac3dec_data.h"
#include "eac3_data.h"
/** gain adaptive quantization mode */
typedef enum {
EAC3_GAQ_NO =0,
EAC3_GAQ_12,
EAC3_GAQ_14,
EAC3_GAQ_124
} EAC3GaqMode;
#define EAC3_SR_CODE_REDUCED 3
void ff_eac3_apply_spectral_extension(AC3DecodeContext *s)
{
int bin, bnd, ch, i;
uint8_t wrapflag[SPX_MAX_BANDS]={1,0,}, num_copy_sections, copy_sizes[SPX_MAX_BANDS];
float rms_energy[SPX_MAX_BANDS];
/* Set copy index mapping table. Set wrap flags to apply a notch filter at
wrap points later on. */
bin = s->spx_dst_start_freq;
num_copy_sections = 0;
for (bnd = 0; bnd < s->num_spx_bands; bnd++) {
int copysize;
int bandsize = s->spx_band_sizes[bnd];
if (bin + bandsize > s->spx_src_start_freq) {
copy_sizes[num_copy_sections++] = bin - s->spx_dst_start_freq;
bin = s->spx_dst_start_freq;
wrapflag[bnd] = 1;
}
for (i = 0; i < bandsize; i += copysize) {
if (bin == s->spx_src_start_freq) {
copy_sizes[num_copy_sections++] = bin - s->spx_dst_start_freq;
bin = s->spx_dst_start_freq;
}
copysize = FFMIN(bandsize - i, s->spx_src_start_freq - bin);
bin += copysize;
}
}
copy_sizes[num_copy_sections++] = bin - s->spx_dst_start_freq;
for (ch = 1; ch <= s->fbw_channels; ch++) {
if (!s->channel_uses_spx[ch])
continue;
/* Copy coeffs from normal bands to extension bands */
bin = s->spx_src_start_freq;
for (i = 0; i < num_copy_sections; i++) {
memcpy(&s->transform_coeffs[ch][bin],
&s->transform_coeffs[ch][s->spx_dst_start_freq],
copy_sizes[i]*sizeof(float));
bin += copy_sizes[i];
}
/* Calculate RMS energy for each SPX band. */
bin = s->spx_src_start_freq;
for (bnd = 0; bnd < s->num_spx_bands; bnd++) {
int bandsize = s->spx_band_sizes[bnd];
float accum = 0.0f;
for (i = 0; i < bandsize; i++) {
float coeff = s->transform_coeffs[ch][bin++];
accum += coeff * coeff;
}
rms_energy[bnd] = sqrtf(accum / bandsize);
}
/* Apply a notch filter at transitions between normal and extension
bands and at all wrap points. */
if (s->spx_atten_code[ch] >= 0) {
const float *atten_tab = ff_eac3_spx_atten_tab[s->spx_atten_code[ch]];
bin = s->spx_src_start_freq - 2;
for (bnd = 0; bnd < s->num_spx_bands; bnd++) {
if (wrapflag[bnd]) {
float *coeffs = &s->transform_coeffs[ch][bin];
coeffs[0] *= atten_tab[0];
coeffs[1] *= atten_tab[1];
coeffs[2] *= atten_tab[2];
coeffs[3] *= atten_tab[1];
coeffs[4] *= atten_tab[0];
}
bin += s->spx_band_sizes[bnd];
}
}
/* Apply noise-blended coefficient scaling based on previously
calculated RMS energy, blending factors, and SPX coordinates for
each band. */
bin = s->spx_src_start_freq;
for (bnd = 0; bnd < s->num_spx_bands; bnd++) {
float nscale = s->spx_noise_blend[ch][bnd] * rms_energy[bnd] * (1.0f / INT32_MIN);
float sscale = s->spx_signal_blend[ch][bnd];
for (i = 0; i < s->spx_band_sizes[bnd]; i++) {
float noise = nscale * (int32_t)av_lfg_get(&s->dith_state);
s->transform_coeffs[ch][bin] *= sscale;
s->transform_coeffs[ch][bin++] += noise;
}
}
}
}
/** lrint(M_SQRT2*cos(2*M_PI/12)*(1<<23)) */
#define COEFF_0 10273905LL
/** lrint(M_SQRT2*cos(0*M_PI/12)*(1<<23)) = lrint(M_SQRT2*(1<<23)) */
#define COEFF_1 11863283LL
/** lrint(M_SQRT2*cos(5*M_PI/12)*(1<<23)) */
#define COEFF_2 3070444LL
/**
* Calculate 6-point IDCT of the pre-mantissas.
* All calculations are 24-bit fixed-point.
*/
static void idct6(int pre_mant[6])
{
int tmp;
int even0, even1, even2, odd0, odd1, odd2;
odd1 = pre_mant[1] - pre_mant[3] - pre_mant[5];
even2 = ( pre_mant[2] * COEFF_0) >> 23;
tmp = ( pre_mant[4] * COEFF_1) >> 23;
odd0 = ((pre_mant[1] + pre_mant[5]) * COEFF_2) >> 23;
even0 = pre_mant[0] + (tmp >> 1);
even1 = pre_mant[0] - tmp;
tmp = even0;
even0 = tmp + even2;
even2 = tmp - even2;
tmp = odd0;
odd0 = tmp + pre_mant[1] + pre_mant[3];
odd2 = tmp + pre_mant[5] - pre_mant[3];
pre_mant[0] = even0 + odd0;
pre_mant[1] = even1 + odd1;
pre_mant[2] = even2 + odd2;
pre_mant[3] = even2 - odd2;
pre_mant[4] = even1 - odd1;
pre_mant[5] = even0 - odd0;
}
void ff_eac3_decode_transform_coeffs_aht_ch(AC3DecodeContext *s, int ch)
{
int bin, blk, gs;
int end_bap, gaq_mode;
GetBitContext *gbc = &s->gbc;
int gaq_gain[AC3_MAX_COEFS];
gaq_mode = get_bits(gbc, 2);
end_bap = (gaq_mode < 2) ? 12 : 17;
/* if GAQ gain is used, decode gain codes for bins with hebap between
8 and end_bap */
gs = 0;
if (gaq_mode == EAC3_GAQ_12 || gaq_mode == EAC3_GAQ_14) {
/* read 1-bit GAQ gain codes */
for (bin = s->start_freq[ch]; bin < s->end_freq[ch]; bin++) {
if (s->bap[ch][bin] > 7 && s->bap[ch][bin] < end_bap)
gaq_gain[gs++] = get_bits1(gbc) << (gaq_mode-1);
}
} else if (gaq_mode == EAC3_GAQ_124) {
/* read 1.67-bit GAQ gain codes (3 codes in 5 bits) */
int gc = 2;
for (bin = s->start_freq[ch]; bin < s->end_freq[ch]; bin++) {
if (s->bap[ch][bin] > 7 && s->bap[ch][bin] < 17) {
if (gc++ == 2) {
int group_code = get_bits(gbc, 5);
if (group_code > 26) {
av_log(s->avctx, AV_LOG_WARNING, "GAQ gain group code out-of-range\n");
group_code = 26;
}
gaq_gain[gs++] = ff_ac3_ungroup_3_in_5_bits_tab[group_code][0];
gaq_gain[gs++] = ff_ac3_ungroup_3_in_5_bits_tab[group_code][1];
gaq_gain[gs++] = ff_ac3_ungroup_3_in_5_bits_tab[group_code][2];
gc = 0;
}
}
}
}
gs=0;
for (bin = s->start_freq[ch]; bin < s->end_freq[ch]; bin++) {
int hebap = s->bap[ch][bin];
int bits = ff_eac3_bits_vs_hebap[hebap];
if (!hebap) {
/* zero-mantissa dithering */
for (blk = 0; blk < 6; blk++) {
s->pre_mantissa[ch][bin][blk] = (av_lfg_get(&s->dith_state) & 0x7FFFFF) - 0x400000;
}
} else if (hebap < 8) {
/* Vector Quantization */
int v = get_bits(gbc, bits);
for (blk = 0; blk < 6; blk++) {
s->pre_mantissa[ch][bin][blk] = ff_eac3_mantissa_vq[hebap][v][blk] << 8;
}
} else {
/* Gain Adaptive Quantization */
int gbits, log_gain;
if (gaq_mode != EAC3_GAQ_NO && hebap < end_bap) {
log_gain = gaq_gain[gs++];
} else {
log_gain = 0;
}
gbits = bits - log_gain;
for (blk = 0; blk < 6; blk++) {
int mant = get_sbits(gbc, gbits);
if (log_gain && mant == -(1 << (gbits-1))) {
/* large mantissa */
int b;
int mbits = bits - (2 - log_gain);
mant = get_sbits(gbc, mbits);
mant <<= (23 - (mbits - 1));
/* remap mantissa value to correct for asymmetric quantization */
if (mant >= 0)
b = 1 << (23 - log_gain);
else
b = ff_eac3_gaq_remap_2_4_b[hebap-8][log_gain-1] << 8;
mant += ((ff_eac3_gaq_remap_2_4_a[hebap-8][log_gain-1] * (int64_t)mant) >> 15) + b;
} else {
/* small mantissa, no GAQ, or Gk=1 */
mant <<= 24 - bits;
if (!log_gain) {
/* remap mantissa value for no GAQ or Gk=1 */
mant += (ff_eac3_gaq_remap_1[hebap-8] * (int64_t)mant) >> 15;
}
}
s->pre_mantissa[ch][bin][blk] = mant;
}
}
idct6(s->pre_mantissa[ch][bin]);
}
}
int ff_eac3_parse_header(AC3DecodeContext *s)
{
int i, blk, ch;
int ac3_exponent_strategy, parse_aht_info, parse_spx_atten_data;
int parse_transient_proc_info;
int num_cpl_blocks;
GetBitContext *gbc = &s->gbc;
/* An E-AC-3 stream can have multiple independent streams which the
application can select from. each independent stream can also contain
dependent streams which are used to add or replace channels. */
if (s->frame_type == EAC3_FRAME_TYPE_DEPENDENT) {
avpriv_request_sample(s->avctx, "Dependent substream decoding");
return AAC_AC3_PARSE_ERROR_FRAME_TYPE;
} else if (s->frame_type == EAC3_FRAME_TYPE_RESERVED) {
av_log(s->avctx, AV_LOG_ERROR, "Reserved frame type\n");
return AAC_AC3_PARSE_ERROR_FRAME_TYPE;
}
/* The substream id indicates which substream this frame belongs to. each
independent stream has its own substream id, and the dependent streams
associated to an independent stream have matching substream id's. */
if (s->substreamid) {
/* only decode substream with id=0. skip any additional substreams. */
avpriv_request_sample(s->avctx, "Additional substreams");
return AAC_AC3_PARSE_ERROR_FRAME_TYPE;
}
if (s->bit_alloc_params.sr_code == EAC3_SR_CODE_REDUCED) {
/* The E-AC-3 specification does not tell how to handle reduced sample
rates in bit allocation. The best assumption would be that it is
handled like AC-3 DolbyNet, but we cannot be sure until we have a
sample which utilizes this feature. */
avpriv_request_sample(s->avctx, "Reduced sampling rate");
return AVERROR_PATCHWELCOME;
}
skip_bits(gbc, 5); // skip bitstream id
/* volume control params */
for (i = 0; i < (s->channel_mode ? 1 : 2); i++) {
skip_bits(gbc, 5); // skip dialog normalization
if (get_bits1(gbc)) {
skip_bits(gbc, 8); // skip compression gain word
}
}
/* dependent stream channel map */
if (s->frame_type == EAC3_FRAME_TYPE_DEPENDENT) {
if (get_bits1(gbc)) {
skip_bits(gbc, 16); // skip custom channel map
}
}
/* mixing metadata */
if (get_bits1(gbc)) {
/* center and surround mix levels */
if (s->channel_mode > AC3_CHMODE_STEREO) {
s->preferred_downmix = get_bits(gbc, 2);
if (s->channel_mode & 1) {
/* if three front channels exist */
s->center_mix_level_ltrt = get_bits(gbc, 3);
s->center_mix_level = get_bits(gbc, 3);
}
if (s->channel_mode & 4) {
/* if a surround channel exists */
s->surround_mix_level_ltrt = av_clip(get_bits(gbc, 3), 3, 7);
s->surround_mix_level = av_clip(get_bits(gbc, 3), 3, 7);
}
}
/* lfe mix level */
if (s->lfe_on && (s->lfe_mix_level_exists = get_bits1(gbc))) {
s->lfe_mix_level = get_bits(gbc, 5);
}
/* info for mixing with other streams and substreams */
if (s->frame_type == EAC3_FRAME_TYPE_INDEPENDENT) {
for (i = 0; i < (s->channel_mode ? 1 : 2); i++) {
// TODO: apply program scale factor
if (get_bits1(gbc)) {
skip_bits(gbc, 6); // skip program scale factor
}
}
if (get_bits1(gbc)) {
skip_bits(gbc, 6); // skip external program scale factor
}
/* skip mixing parameter data */
switch(get_bits(gbc, 2)) {
case 1: skip_bits(gbc, 5); break;
case 2: skip_bits(gbc, 12); break;
case 3: {
int mix_data_size = (get_bits(gbc, 5) + 2) << 3;
skip_bits_long(gbc, mix_data_size);
break;
}
}
/* skip pan information for mono or dual mono source */
if (s->channel_mode < AC3_CHMODE_STEREO) {
for (i = 0; i < (s->channel_mode ? 1 : 2); i++) {
if (get_bits1(gbc)) {
/* note: this is not in the ATSC A/52B specification
reference: ETSI TS 102 366 V1.1.1
section: E.1.3.1.25 */
skip_bits(gbc, 8); // skip pan mean direction index
skip_bits(gbc, 6); // skip reserved paninfo bits
}
}
}
/* skip mixing configuration information */
if (get_bits1(gbc)) {
for (blk = 0; blk < s->num_blocks; blk++) {
if (s->num_blocks == 1 || get_bits1(gbc)) {
skip_bits(gbc, 5);
}
}
}
}
}
/* informational metadata */
if (get_bits1(gbc)) {
s->bitstream_mode = get_bits(gbc, 3);
skip_bits(gbc, 2); // skip copyright bit and original bitstream bit
if (s->channel_mode == AC3_CHMODE_STEREO) {
s->dolby_surround_mode = get_bits(gbc, 2);
s->dolby_headphone_mode = get_bits(gbc, 2);
}
if (s->channel_mode >= AC3_CHMODE_2F2R) {
s->dolby_surround_ex_mode = get_bits(gbc, 2);
}
for (i = 0; i < (s->channel_mode ? 1 : 2); i++) {
if (get_bits1(gbc)) {
skip_bits(gbc, 8); // skip mix level, room type, and A/D converter type
}
}
if (s->bit_alloc_params.sr_code != EAC3_SR_CODE_REDUCED) {
skip_bits1(gbc); // skip source sample rate code
}
}
/* converter synchronization flag
If frames are less than six blocks, this bit should be turned on
once every 6 blocks to indicate the start of a frame set.
reference: RFC 4598, Section 2.1.3 Frame Sets */
if (s->frame_type == EAC3_FRAME_TYPE_INDEPENDENT && s->num_blocks != 6) {
skip_bits1(gbc); // skip converter synchronization flag
}
/* original frame size code if this stream was converted from AC-3 */
if (s->frame_type == EAC3_FRAME_TYPE_AC3_CONVERT &&
(s->num_blocks == 6 || get_bits1(gbc))) {
skip_bits(gbc, 6); // skip frame size code
}
/* additional bitstream info */
if (get_bits1(gbc)) {
int addbsil = get_bits(gbc, 6);
for (i = 0; i < addbsil + 1; i++) {
skip_bits(gbc, 8); // skip additional bit stream info
}
}
/* audio frame syntax flags, strategy data, and per-frame data */
if (s->num_blocks == 6) {
ac3_exponent_strategy = get_bits1(gbc);
parse_aht_info = get_bits1(gbc);
} else {
/* less than 6 blocks, so use AC-3-style exponent strategy syntax, and
do not use AHT */
ac3_exponent_strategy = 1;
parse_aht_info = 0;
}
s->snr_offset_strategy = get_bits(gbc, 2);
parse_transient_proc_info = get_bits1(gbc);
s->block_switch_syntax = get_bits1(gbc);
if (!s->block_switch_syntax)
memset(s->block_switch, 0, sizeof(s->block_switch));
s->dither_flag_syntax = get_bits1(gbc);
if (!s->dither_flag_syntax) {
for (ch = 1; ch <= s->fbw_channels; ch++)
s->dither_flag[ch] = 1;
}
s->dither_flag[CPL_CH] = s->dither_flag[s->lfe_ch] = 0;
s->bit_allocation_syntax = get_bits1(gbc);
if (!s->bit_allocation_syntax) {
/* set default bit allocation parameters */
s->bit_alloc_params.slow_decay = ff_ac3_slow_decay_tab[2];
s->bit_alloc_params.fast_decay = ff_ac3_fast_decay_tab[1];
s->bit_alloc_params.slow_gain = ff_ac3_slow_gain_tab [1];
s->bit_alloc_params.db_per_bit = ff_ac3_db_per_bit_tab[2];
s->bit_alloc_params.floor = ff_ac3_floor_tab [7];
}
s->fast_gain_syntax = get_bits1(gbc);
s->dba_syntax = get_bits1(gbc);
s->skip_syntax = get_bits1(gbc);
parse_spx_atten_data = get_bits1(gbc);
/* coupling strategy occurrence and coupling use per block */
num_cpl_blocks = 0;
if (s->channel_mode > 1) {
for (blk = 0; blk < s->num_blocks; blk++) {
s->cpl_strategy_exists[blk] = (!blk || get_bits1(gbc));
if (s->cpl_strategy_exists[blk]) {
s->cpl_in_use[blk] = get_bits1(gbc);
} else {
s->cpl_in_use[blk] = s->cpl_in_use[blk-1];
}
num_cpl_blocks += s->cpl_in_use[blk];
}
} else {
memset(s->cpl_in_use, 0, sizeof(s->cpl_in_use));
}
/* exponent strategy data */
if (ac3_exponent_strategy) {
/* AC-3-style exponent strategy syntax */
for (blk = 0; blk < s->num_blocks; blk++) {
for (ch = !s->cpl_in_use[blk]; ch <= s->fbw_channels; ch++) {
s->exp_strategy[blk][ch] = get_bits(gbc, 2);
}
}
} else {
/* LUT-based exponent strategy syntax */
for (ch = !((s->channel_mode > 1) && num_cpl_blocks); ch <= s->fbw_channels; ch++) {
int frmchexpstr = get_bits(gbc, 5);
for (blk = 0; blk < 6; blk++) {
s->exp_strategy[blk][ch] = ff_eac3_frm_expstr[frmchexpstr][blk];
}
}
}
/* LFE exponent strategy */
if (s->lfe_on) {
for (blk = 0; blk < s->num_blocks; blk++) {
s->exp_strategy[blk][s->lfe_ch] = get_bits1(gbc);
}
}
/* original exponent strategies if this stream was converted from AC-3 */
if (s->frame_type == EAC3_FRAME_TYPE_INDEPENDENT &&
(s->num_blocks == 6 || get_bits1(gbc))) {
skip_bits(gbc, 5 * s->fbw_channels); // skip converter channel exponent strategy
}
/* determine which channels use AHT */
if (parse_aht_info) {
/* For AHT to be used, all non-zero blocks must reuse exponents from
the first block. Furthermore, for AHT to be used in the coupling
channel, all blocks must use coupling and use the same coupling
strategy. */
s->channel_uses_aht[CPL_CH]=0;
for (ch = (num_cpl_blocks != 6); ch <= s->channels; ch++) {
int use_aht = 1;
for (blk = 1; blk < 6; blk++) {
if ((s->exp_strategy[blk][ch] != EXP_REUSE) ||
(!ch && s->cpl_strategy_exists[blk])) {
use_aht = 0;
break;
}
}
s->channel_uses_aht[ch] = use_aht && get_bits1(gbc);
}
} else {
memset(s->channel_uses_aht, 0, sizeof(s->channel_uses_aht));
}
/* per-frame SNR offset */
if (!s->snr_offset_strategy) {
int csnroffst = (get_bits(gbc, 6) - 15) << 4;
int snroffst = (csnroffst + get_bits(gbc, 4)) << 2;
for (ch = 0; ch <= s->channels; ch++)
s->snr_offset[ch] = snroffst;
}
/* transient pre-noise processing data */
if (parse_transient_proc_info) {
for (ch = 1; ch <= s->fbw_channels; ch++) {
if (get_bits1(gbc)) { // channel in transient processing
skip_bits(gbc, 10); // skip transient processing location
skip_bits(gbc, 8); // skip transient processing length
}
}
}
/* spectral extension attenuation data */
for (ch = 1; ch <= s->fbw_channels; ch++) {
if (parse_spx_atten_data && get_bits1(gbc)) {
s->spx_atten_code[ch] = get_bits(gbc, 5);
} else {
s->spx_atten_code[ch] = -1;
}
}
/* block start information */
if (s->num_blocks > 1 && get_bits1(gbc)) {
/* reference: Section E2.3.2.27
nblkstrtbits = (numblks - 1) * (4 + ceiling(log2(words_per_frame)))
The spec does not say what this data is or what it's used for.
It is likely the offset of each block within the frame. */
int block_start_bits = (s->num_blocks-1) * (4 + av_log2(s->frame_size-2));
skip_bits_long(gbc, block_start_bits);
avpriv_request_sample(s->avctx, "Block start info");
}
/* syntax state initialization */
for (ch = 1; ch <= s->fbw_channels; ch++) {
s->first_spx_coords[ch] = 1;
s->first_cpl_coords[ch] = 1;
}
s->first_cpl_leak = 1;
return 0;
}