falkTX
/
FFmpeg
mirror of https://github.com/falkTX/FFmpeg.git
1
0
Fork 0
Code Issues 0 Releases 338 Wiki Activity
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
22948 Commits
32 Branches
821MB
Tree: 8ef4e65e94
Branches Tags
${ item.name }
Create branch ${ searchTerm }
from '8ef4e65e94'
${ noResults }
FFmpeg/libavcodec/atrac1.c

382 lines
13KB
Raw Blame History 

  1. /*

  2.  * Atrac 1 compatible decoder

  3.  * Copyright (c) 2009 Maxim Poliakovski

  4.  * Copyright (c) 2009 Benjamin Larsson

  5.  *

  6.  * This file is part of FFmpeg.

  7.  *

  8.  * FFmpeg is free software; you can redistribute it and/or

  9.  * modify it under the terms of the GNU Lesser General Public

  10.  * License as published by the Free Software Foundation; either

  11.  * version 2.1 of the License, or (at your option) any later version.

  12.  *

  13.  * FFmpeg is distributed in the hope that it will be useful,

  14.  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  15.  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

  16.  * Lesser General Public License for more details.

  17.  *

  18.  * You should have received a copy of the GNU Lesser General Public

  19.  * License along with FFmpeg; if not, write to the Free Software

  20.  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

  21.  */

  22. 

  23. /**

  24.  * @file libavcodec/atrac1.c

  25.  * Atrac 1 compatible decoder.

  26.  * This decoder handles raw ATRAC1 data and probably SDDS data.

  27.  */

  28. 

  29. /* Many thanks to Tim Craig for all the help! */

  30. 

  31. #include <math.h>

  32. #include <stddef.h>

  33. #include <stdio.h>

  34. 

  35. #include "avcodec.h"

  36. #include "get_bits.h"

  37. #include "dsputil.h"

  38. 

  39. #include "atrac.h"

  40. #include "atrac1data.h"

  41. 

  42. #define AT1_MAX_BFU      52                 ///< max number of block floating units in a sound unit

  43. #define AT1_SU_SIZE      212                ///< number of bytes in a sound unit

  44. #define AT1_SU_SAMPLES   512                ///< number of samples in a sound unit

  45. #define AT1_FRAME_SIZE   AT1_SU_SIZE * 2

  46. #define AT1_SU_MAX_BITS  AT1_SU_SIZE * 8

  47. #define AT1_MAX_CHANNELS 2

  48. 

  49. #define AT1_QMF_BANDS    3

  50. #define IDX_LOW_BAND     0

  51. #define IDX_MID_BAND     1

  52. #define IDX_HIGH_BAND    2

  53. 

  54. /**

  55.  * Sound unit struct, one unit is used per channel

  56.  */

  57. typedef struct {

  58.     int                 log2_block_count[AT1_QMF_BANDS];    ///< log2 number of blocks in a band

  59.     int                 num_bfus;                           ///< number of Block Floating Units

  60.     float*              spectrum[2];

  61.     DECLARE_ALIGNED_16(float, spec1)[AT1_SU_SAMPLES];     ///< mdct buffer

  62.     DECLARE_ALIGNED_16(float, spec2)[AT1_SU_SAMPLES];     ///< mdct buffer

  63.     DECLARE_ALIGNED_16(float, fst_qmf_delay)[46];         ///< delay line for the 1st stacked QMF filter

  64.     DECLARE_ALIGNED_16(float, snd_qmf_delay)[46];         ///< delay line for the 2nd stacked QMF filter

  65.     DECLARE_ALIGNED_16(float, last_qmf_delay)[256+23];    ///< delay line for the last stacked QMF filter

  66. } AT1SUCtx;

  67. 

  68. /**

  69.  * The atrac1 context, holds all needed parameters for decoding

  70.  */

  71. typedef struct {

  72.     AT1SUCtx            SUs[AT1_MAX_CHANNELS];              ///< channel sound unit

  73.     DECLARE_ALIGNED_16(float, spec)[AT1_SU_SAMPLES];      ///< the mdct spectrum buffer

  74. 

  75.     DECLARE_ALIGNED_16(float,  low)[256];

  76.     DECLARE_ALIGNED_16(float,  mid)[256];

  77.     DECLARE_ALIGNED_16(float, high)[512];

  78.     float*              bands[3];

  79.     DECLARE_ALIGNED_16(float, out_samples)[AT1_MAX_CHANNELS][AT1_SU_SAMPLES];

  80.     FFTContext          mdct_ctx[3];

  81.     int                 channels;

  82.     DSPContext          dsp;

  83. } AT1Ctx;

  84. 

  85. /** size of the transform in samples in the long mode for each QMF band */

  86. static const uint16_t samples_per_band[3] = {128, 128, 256};

  87. static const uint8_t   mdct_long_nbits[3] = {7, 7, 8};

  88. 

  89. 

  90. static void at1_imdct(AT1Ctx *q, float *spec, float *out, int nbits,

  91.                       int rev_spec)

  92. {

  93.     FFTContext* mdct_context = &q->mdct_ctx[nbits - 5 - (nbits > 6)];

  94.     int transf_size = 1 << nbits;

  95. 

  96.     if (rev_spec) {

  97.         int i;

  98.         for (i = 0; i < transf_size / 2; i++)

  99.             FFSWAP(float, spec[i], spec[transf_size - 1 - i]);

  100.     }

  101.     ff_imdct_half(mdct_context, out, spec);

  102. }

  103. 

  104. 

  105. static int at1_imdct_block(AT1SUCtx* su, AT1Ctx *q)

  106. {

  107.     int          band_num, band_samples, log2_block_count, nbits, num_blocks, block_size;

  108.     unsigned int start_pos, ref_pos = 0, pos = 0;

  109. 

  110.     for (band_num = 0; band_num < AT1_QMF_BANDS; band_num++) {

  111.         float *prev_buf;

  112.         int j;

  113. 

  114.         band_samples = samples_per_band[band_num];

  115.         log2_block_count = su->log2_block_count[band_num];

  116. 

  117.         /* number of mdct blocks in the current QMF band: 1 - for long mode */

  118.         /* 4 for short mode(low/middle bands) and 8 for short mode(high band)*/

  119.         num_blocks = 1 << log2_block_count;

  120. 

  121.         if (num_blocks == 1) {

  122.             /* mdct block size in samples: 128 (long mode, low & mid bands), */

  123.             /* 256 (long mode, high band) and 32 (short mode, all bands) */

  124.             block_size = band_samples >> log2_block_count;

  125. 

  126.             /* calc transform size in bits according to the block_size_mode */

  127.             nbits = mdct_long_nbits[band_num] - log2_block_count;

  128. 

  129.             if (nbits != 5 && nbits != 7 && nbits != 8)

  130.                 return -1;

  131.         } else {

  132.             block_size = 32;

  133.             nbits = 5;

  134.         }

  135. 

  136.         start_pos = 0;

  137.         prev_buf = &su->spectrum[1][ref_pos + band_samples - 16];

  138.         for (j=0; j < num_blocks; j++) {

  139.             at1_imdct(q, &q->spec[pos], &su->spectrum[0][ref_pos + start_pos], nbits, band_num);

  140. 

  141.             /* overlap and window */

  142.             q->dsp.vector_fmul_window(&q->bands[band_num][start_pos], prev_buf,

  143.                                       &su->spectrum[0][ref_pos + start_pos], ff_sine_32, 0, 16);

  144. 

  145.             prev_buf = &su->spectrum[0][ref_pos+start_pos + 16];

  146.             start_pos += block_size;

  147.             pos += block_size;

  148.         }

  149. 

  150.         if (num_blocks == 1)

  151.             memcpy(q->bands[band_num] + 32, &su->spectrum[0][ref_pos + 16], 240 * sizeof(float));

  152. 

  153.         ref_pos += band_samples;

  154.     }

  155. 

  156.     /* Swap buffers so the mdct overlap works */

  157.     FFSWAP(float*, su->spectrum[0], su->spectrum[1]);

  158. 

  159.     return 0;

  160. }

  161. 

  162. /**

  163.  * Parse the block size mode byte

  164.  */

  165. 

  166. static int at1_parse_bsm(GetBitContext* gb, int log2_block_cnt[AT1_QMF_BANDS])

  167. {

  168.     int log2_block_count_tmp, i;

  169. 

  170.     for (i = 0; i < 2; i++) {

  171.         /* low and mid band */

  172.         log2_block_count_tmp = get_bits(gb, 2);

  173.         if (log2_block_count_tmp & 1)

  174.             return -1;

  175.         log2_block_cnt[i] = 2 - log2_block_count_tmp;

  176.     }

  177. 

  178.     /* high band */

  179.     log2_block_count_tmp = get_bits(gb, 2);

  180.     if (log2_block_count_tmp != 0 && log2_block_count_tmp != 3)

  181.         return -1;

  182.     log2_block_cnt[IDX_HIGH_BAND] = 3 - log2_block_count_tmp;

  183. 

  184.     skip_bits(gb, 2);

  185.     return 0;

  186. }

  187. 

  188. 

  189. static int at1_unpack_dequant(GetBitContext* gb, AT1SUCtx* su,

  190.                               float spec[AT1_SU_SAMPLES])

  191. {

  192.     int bits_used, band_num, bfu_num, i;

  193.     uint8_t idwls[AT1_MAX_BFU];                 ///< the word length indexes for each BFU

  194.     uint8_t idsfs[AT1_MAX_BFU];                 ///< the scalefactor indexes for each BFU

  195. 

  196.     /* parse the info byte (2nd byte) telling how much BFUs were coded */

  197.     su->num_bfus = bfu_amount_tab1[get_bits(gb, 3)];

  198. 

  199.     /* calc number of consumed bits:

  200.         num_BFUs * (idwl(4bits) + idsf(6bits)) + log2_block_count(8bits) + info_byte(8bits)

  201.         + info_byte_copy(8bits) + log2_block_count_copy(8bits) */

  202.     bits_used = su->num_bfus * 10 + 32 +

  203.                 bfu_amount_tab2[get_bits(gb, 2)] +

  204.                 (bfu_amount_tab3[get_bits(gb, 3)] << 1);

  205. 

  206.     /* get word length index (idwl) for each BFU */

  207.     for (i = 0; i < su->num_bfus; i++)

  208.         idwls[i] = get_bits(gb, 4);

  209. 

  210.     /* get scalefactor index (idsf) for each BFU */

  211.     for (i = 0; i < su->num_bfus; i++)

  212.         idsfs[i] = get_bits(gb, 6);

  213. 

  214.     /* zero idwl/idsf for empty BFUs */

  215.     for (i = su->num_bfus; i < AT1_MAX_BFU; i++)

  216.         idwls[i] = idsfs[i] = 0;

  217. 

  218.     /* read in the spectral data and reconstruct MDCT spectrum of this channel */

  219.     for (band_num = 0; band_num < AT1_QMF_BANDS; band_num++) {

  220.         for (bfu_num = bfu_bands_t[band_num]; bfu_num < bfu_bands_t[band_num+1]; bfu_num++) {

  221.             int pos;

  222. 

  223.             int num_specs = specs_per_bfu[bfu_num];

  224.             int word_len  = !!idwls[bfu_num] + idwls[bfu_num];

  225.             float scale_factor = sf_table[idsfs[bfu_num]];

  226.             bits_used += word_len * num_specs; /* add number of bits consumed by current BFU */

  227. 

  228.             /* check for bitstream overflow */

  229.             if (bits_used > AT1_SU_MAX_BITS)

  230.                 return -1;

  231. 

  232.             /* get the position of the 1st spec according to the block size mode */

  233.             pos = su->log2_block_count[band_num] ? bfu_start_short[bfu_num] : bfu_start_long[bfu_num];

  234. 

  235.             if (word_len) {

  236.                 float   max_quant = 1.0 / (float)((1 << (word_len - 1)) - 1);

  237. 

  238.                 for (i = 0; i < num_specs; i++) {

  239.                     /* read in a quantized spec and convert it to

  240.                      * signed int and then inverse quantization

  241.                      */

  242.                     spec[pos+i] = get_sbits(gb, word_len) * scale_factor * max_quant;

  243.                 }

  244.             } else { /* word_len = 0 -> empty BFU, zero all specs in the emty BFU */

  245.                 memset(&spec[pos], 0, num_specs * sizeof(float));

  246.             }

  247.         }

  248.     }

  249. 

  250.     return 0;

  251. }

  252. 

  253. 

  254. void at1_subband_synthesis(AT1Ctx *q, AT1SUCtx* su, float *pOut)

  255. {

  256.     float temp[256];

  257.     float iqmf_temp[512 + 46];

  258. 

  259.     /* combine low and middle bands */

  260.     atrac_iqmf(q->bands[0], q->bands[1], 128, temp, su->fst_qmf_delay, iqmf_temp);

  261. 

  262.     /* delay the signal of the high band by 23 samples */

  263.     memcpy( su->last_qmf_delay,    &su->last_qmf_delay[256], sizeof(float) *  23);

  264.     memcpy(&su->last_qmf_delay[23], q->bands[2],             sizeof(float) * 256);

  265. 

  266.     /* combine (low + middle) and high bands */

  267.     atrac_iqmf(temp, su->last_qmf_delay, 256, pOut, su->snd_qmf_delay, iqmf_temp);

  268. }

  269. 

  270. 

  271. static int atrac1_decode_frame(AVCodecContext *avctx, void *data,

  272.                                int *data_size, AVPacket *avpkt)

  273. {

  274.     const uint8_t *buf = avpkt->data;

  275.     int buf_size       = avpkt->size;

  276.     AT1Ctx *q          = avctx->priv_data;

  277.     int ch, ret, i;

  278.     GetBitContext gb;

  279.     float* samples = data;

  280. 

  281. 

  282.     if (buf_size < 212 * q->channels) {

  283.         av_log(q,AV_LOG_ERROR,"Not enought data to decode!\n");

  284.         return -1;

  285.     }

  286. 

  287.     for (ch = 0; ch < q->channels; ch++) {

  288.         AT1SUCtx* su = &q->SUs[ch];

  289. 

  290.         init_get_bits(&gb, &buf[212 * ch], 212 * 8);

  291. 

  292.         /* parse block_size_mode, 1st byte */

  293.         ret = at1_parse_bsm(&gb, su->log2_block_count);

  294.         if (ret < 0)

  295.             return ret;

  296. 

  297.         ret = at1_unpack_dequant(&gb, su, q->spec);

  298.         if (ret < 0)

  299.             return ret;

  300. 

  301.         ret = at1_imdct_block(su, q);

  302.         if (ret < 0)

  303.             return ret;

  304.         at1_subband_synthesis(q, su, q->out_samples[ch]);

  305.     }

  306. 

  307.     /* round, convert to 16bit and interleave */

  308.     if (q->channels == 1) {

  309.         /* mono */

  310.         q->dsp.vector_clipf(samples, q->out_samples[0], -32700.0 / (1 << 15),

  311.                             32700.0 / (1 << 15), AT1_SU_SAMPLES);

  312.     } else {

  313.         /* stereo */

  314.         for (i = 0; i < AT1_SU_SAMPLES; i++) {

  315.             samples[i * 2]     = av_clipf(q->out_samples[0][i],

  316.                                           -32700.0 / (1 << 15),

  317.                                            32700.0 / (1 << 15));

  318.             samples[i * 2 + 1] = av_clipf(q->out_samples[1][i],

  319.                                           -32700.0 / (1 << 15),

  320.                                            32700.0 / (1 << 15));

  321.         }

  322.     }

  323. 

  324.     *data_size = q->channels * AT1_SU_SAMPLES * sizeof(*samples);

  325.     return avctx->block_align;

  326. }

  327. 

  328. 

  329. static av_cold int atrac1_decode_init(AVCodecContext *avctx)

  330. {

  331.     AT1Ctx *q = avctx->priv_data;

  332. 

  333.     avctx->sample_fmt = SAMPLE_FMT_FLT;

  334. 

  335.     q->channels = avctx->channels;

  336. 

  337.     /* Init the mdct transforms */

  338.     ff_mdct_init(&q->mdct_ctx[0], 6, 1, -1.0/ (1 << 15));

  339.     ff_mdct_init(&q->mdct_ctx[1], 8, 1, -1.0/ (1 << 15));

  340.     ff_mdct_init(&q->mdct_ctx[2], 9, 1, -1.0/ (1 << 15));

  341. 

  342.     ff_init_ff_sine_windows(5);

  343. 

  344.     atrac_generate_tables();

  345. 

  346.     dsputil_init(&q->dsp, avctx);

  347. 

  348.     q->bands[0] = q->low;

  349.     q->bands[1] = q->mid;

  350.     q->bands[2] = q->high;

  351. 

  352.     /* Prepare the mdct overlap buffers */

  353.     q->SUs[0].spectrum[0] = q->SUs[0].spec1;

  354.     q->SUs[0].spectrum[1] = q->SUs[0].spec2;

  355.     q->SUs[1].spectrum[0] = q->SUs[1].spec1;

  356.     q->SUs[1].spectrum[1] = q->SUs[1].spec2;

  357. 

  358.     return 0;

  359. }

  360. 

  361. 

  362. static av_cold int atrac1_decode_end(AVCodecContext * avctx) {

  363.     AT1Ctx *q = avctx->priv_data;

  364. 

  365.     ff_mdct_end(&q->mdct_ctx[0]);

  366.     ff_mdct_end(&q->mdct_ctx[1]);

  367.     ff_mdct_end(&q->mdct_ctx[2]);

  368.     return 0;

  369. }

  370. 

  371. 

  372. AVCodec atrac1_decoder = {

  373.     .name = "atrac1",

  374.     .type = CODEC_TYPE_AUDIO,

  375.     .id = CODEC_ID_ATRAC1,

  376.     .priv_data_size = sizeof(AT1Ctx),

  377.     .init = atrac1_decode_init,

  378.     .close = atrac1_decode_end,

  379.     .decode = atrac1_decode_frame,

  380.     .long_name = NULL_IF_CONFIG_SMALL("Atrac 1 (Adaptive TRansform Acoustic Coding)"),

  381. };