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FFmpeg/libavcodec/mpegaudioenc.c

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  1. /*

  2.  * The simplest mpeg audio layer 2 encoder

  3.  * Copyright (c) 2000, 2001 Fabrice Bellard

  4.  *

  5.  * This file is part of FFmpeg.

  6.  *

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

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

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

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

  11.  *

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

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

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

  15.  * Lesser General Public License for more details.

  16.  *

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

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

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

  20.  */

  21. 

  22. /**

  23.  * @file

  24.  * The simplest mpeg audio layer 2 encoder.

  25.  */

  26. 

  27. #include "libavutil/channel_layout.h"

  28. 

  29. #include "avcodec.h"

  30. #include "internal.h"

  31. #include "put_bits.h"

  32. 

  33. #define FRAC_BITS   15   /* fractional bits for sb_samples and dct */

  34. #define WFRAC_BITS  14   /* fractional bits for window */

  35. 

  36. #include "mpegaudio.h"

  37. #include "mpegaudiodsp.h"

  38. 

  39. /* currently, cannot change these constants (need to modify

  40.    quantization stage) */

  41. #define MUL(a,b) (((int64_t)(a) * (int64_t)(b)) >> FRAC_BITS)

  42. 

  43. #define SAMPLES_BUF_SIZE 4096

  44. 

  45. typedef struct MpegAudioContext {

  46.     PutBitContext pb;

  47.     int nb_channels;

  48.     int lsf;           /* 1 if mpeg2 low bitrate selected */

  49.     int bitrate_index; /* bit rate */

  50.     int freq_index;

  51.     int frame_size; /* frame size, in bits, without padding */

  52.     /* padding computation */

  53.     int frame_frac, frame_frac_incr, do_padding;

  54.     short samples_buf[MPA_MAX_CHANNELS][SAMPLES_BUF_SIZE]; /* buffer for filter */

  55.     int samples_offset[MPA_MAX_CHANNELS];       /* offset in samples_buf */

  56.     int sb_samples[MPA_MAX_CHANNELS][3][12][SBLIMIT];

  57.     unsigned char scale_factors[MPA_MAX_CHANNELS][SBLIMIT][3]; /* scale factors */

  58.     /* code to group 3 scale factors */

  59.     unsigned char scale_code[MPA_MAX_CHANNELS][SBLIMIT];

  60.     int sblimit; /* number of used subbands */

  61.     const unsigned char *alloc_table;

  62. } MpegAudioContext;

  63. 

  64. /* define it to use floats in quantization (I don't like floats !) */

  65. #define USE_FLOATS

  66. 

  67. #include "mpegaudiodata.h"

  68. #include "mpegaudiotab.h"

  69. 

  70. static av_cold int MPA_encode_init(AVCodecContext *avctx)

  71. {

  72.     MpegAudioContext *s = avctx->priv_data;

  73.     int freq = avctx->sample_rate;

  74.     int bitrate = avctx->bit_rate;

  75.     int channels = avctx->channels;

  76.     int i, v, table;

  77.     float a;

  78. 

  79.     if (channels <= 0 || channels > 2){

  80.         av_log(avctx, AV_LOG_ERROR, "encoding %d channel(s) is not allowed in mp2\n", channels);

  81.         return AVERROR(EINVAL);

  82.     }

  83.     bitrate = bitrate / 1000;

  84.     s->nb_channels = channels;

  85.     avctx->frame_size = MPA_FRAME_SIZE;

  86.     avctx->delay      = 512 - 32 + 1;

  87. 

  88.     /* encoding freq */

  89.     s->lsf = 0;

  90.     for(i=0;i<3;i++) {

  91.         if (avpriv_mpa_freq_tab[i] == freq)

  92.             break;

  93.         if ((avpriv_mpa_freq_tab[i] / 2) == freq) {

  94.             s->lsf = 1;

  95.             break;

  96.         }

  97.     }

  98.     if (i == 3){

  99.         av_log(avctx, AV_LOG_ERROR, "Sampling rate %d is not allowed in mp2\n", freq);

  100.         return AVERROR(EINVAL);

  101.     }

  102.     s->freq_index = i;

  103. 

  104.     /* encoding bitrate & frequency */

  105.     for(i=0;i<15;i++) {

  106.         if (avpriv_mpa_bitrate_tab[s->lsf][1][i] == bitrate)

  107.             break;

  108.     }

  109.     if (i == 15){

  110.         av_log(avctx, AV_LOG_ERROR, "bitrate %d is not allowed in mp2\n", bitrate);

  111.         return AVERROR(EINVAL);

  112.     }

  113.     s->bitrate_index = i;

  114. 

  115.     /* compute total header size & pad bit */

  116. 

  117.     a = (float)(bitrate * 1000 * MPA_FRAME_SIZE) / (freq * 8.0);

  118.     s->frame_size = ((int)a) * 8;

  119. 

  120.     /* frame fractional size to compute padding */

  121.     s->frame_frac = 0;

  122.     s->frame_frac_incr = (int)((a - floor(a)) * 65536.0);

  123. 

  124.     /* select the right allocation table */

  125.     table = ff_mpa_l2_select_table(bitrate, s->nb_channels, freq, s->lsf);

  126. 

  127.     /* number of used subbands */

  128.     s->sblimit = ff_mpa_sblimit_table[table];

  129.     s->alloc_table = ff_mpa_alloc_tables[table];

  130. 

  131.     av_dlog(avctx, "%d kb/s, %d Hz, frame_size=%d bits, table=%d, padincr=%x\n",

  132.             bitrate, freq, s->frame_size, table, s->frame_frac_incr);

  133. 

  134.     for(i=0;i<s->nb_channels;i++)

  135.         s->samples_offset[i] = 0;

  136. 

  137.     for(i=0;i<257;i++) {

  138.         int v;

  139.         v = ff_mpa_enwindow[i];

  140. #if WFRAC_BITS != 16

  141.         v = (v + (1 << (16 - WFRAC_BITS - 1))) >> (16 - WFRAC_BITS);

  142. #endif

  143.         filter_bank[i] = v;

  144.         if ((i & 63) != 0)

  145.             v = -v;

  146.         if (i != 0)

  147.             filter_bank[512 - i] = v;

  148.     }

  149. 

  150.     for(i=0;i<64;i++) {

  151.         v = (int)(exp2((3 - i) / 3.0) * (1 << 20));

  152.         if (v <= 0)

  153.             v = 1;

  154.         scale_factor_table[i] = v;

  155. #ifdef USE_FLOATS

  156.         scale_factor_inv_table[i] = exp2(-(3 - i) / 3.0) / (float)(1 << 20);

  157. #else

  158. #define P 15

  159.         scale_factor_shift[i] = 21 - P - (i / 3);

  160.         scale_factor_mult[i] = (1 << P) * exp2((i % 3) / 3.0);

  161. #endif

  162.     }

  163.     for(i=0;i<128;i++) {

  164.         v = i - 64;

  165.         if (v <= -3)

  166.             v = 0;

  167.         else if (v < 0)

  168.             v = 1;

  169.         else if (v == 0)

  170.             v = 2;

  171.         else if (v < 3)

  172.             v = 3;

  173.         else

  174.             v = 4;

  175.         scale_diff_table[i] = v;

  176.     }

  177. 

  178.     for(i=0;i<17;i++) {

  179.         v = ff_mpa_quant_bits[i];

  180.         if (v < 0)

  181.             v = -v;

  182.         else

  183.             v = v * 3;

  184.         total_quant_bits[i] = 12 * v;

  185.     }

  186. 

  187. #if FF_API_OLD_ENCODE_AUDIO

  188.     avctx->coded_frame= avcodec_alloc_frame();

  189.     if (!avctx->coded_frame)

  190.         return AVERROR(ENOMEM);

  191. #endif

  192. 

  193.     return 0;

  194. }

  195. 

  196. /* 32 point floating point IDCT without 1/sqrt(2) coef zero scaling */

  197. static void idct32(int *out, int *tab)

  198. {

  199.     int i, j;

  200.     int *t, *t1, xr;

  201.     const int *xp = costab32;

  202. 

  203.     for(j=31;j>=3;j-=2) tab[j] += tab[j - 2];

  204. 

  205.     t = tab + 30;

  206.     t1 = tab + 2;

  207.     do {

  208.         t[0] += t[-4];

  209.         t[1] += t[1 - 4];

  210.         t -= 4;

  211.     } while (t != t1);

  212. 

  213.     t = tab + 28;

  214.     t1 = tab + 4;

  215.     do {

  216.         t[0] += t[-8];

  217.         t[1] += t[1-8];

  218.         t[2] += t[2-8];

  219.         t[3] += t[3-8];

  220.         t -= 8;

  221.     } while (t != t1);

  222. 

  223.     t = tab;

  224.     t1 = tab + 32;

  225.     do {

  226.         t[ 3] = -t[ 3];

  227.         t[ 6] = -t[ 6];

  228. 

  229.         t[11] = -t[11];

  230.         t[12] = -t[12];

  231.         t[13] = -t[13];

  232.         t[15] = -t[15];

  233.         t += 16;

  234.     } while (t != t1);

  235. 

  236. 

  237.     t = tab;

  238.     t1 = tab + 8;

  239.     do {

  240.         int x1, x2, x3, x4;

  241. 

  242.         x3 = MUL(t[16], FIX(SQRT2*0.5));

  243.         x4 = t[0] - x3;

  244.         x3 = t[0] + x3;

  245. 

  246.         x2 = MUL(-(t[24] + t[8]), FIX(SQRT2*0.5));

  247.         x1 = MUL((t[8] - x2), xp[0]);

  248.         x2 = MUL((t[8] + x2), xp[1]);

  249. 

  250.         t[ 0] = x3 + x1;

  251.         t[ 8] = x4 - x2;

  252.         t[16] = x4 + x2;

  253.         t[24] = x3 - x1;

  254.         t++;

  255.     } while (t != t1);

  256. 

  257.     xp += 2;

  258.     t = tab;

  259.     t1 = tab + 4;

  260.     do {

  261.         xr = MUL(t[28],xp[0]);

  262.         t[28] = (t[0] - xr);

  263.         t[0] = (t[0] + xr);

  264. 

  265.         xr = MUL(t[4],xp[1]);

  266.         t[ 4] = (t[24] - xr);

  267.         t[24] = (t[24] + xr);

  268. 

  269.         xr = MUL(t[20],xp[2]);

  270.         t[20] = (t[8] - xr);

  271.         t[ 8] = (t[8] + xr);

  272. 

  273.         xr = MUL(t[12],xp[3]);

  274.         t[12] = (t[16] - xr);

  275.         t[16] = (t[16] + xr);

  276.         t++;

  277.     } while (t != t1);

  278.     xp += 4;

  279. 

  280.     for (i = 0; i < 4; i++) {

  281.         xr = MUL(tab[30-i*4],xp[0]);

  282.         tab[30-i*4] = (tab[i*4] - xr);

  283.         tab[   i*4] = (tab[i*4] + xr);

  284. 

  285.         xr = MUL(tab[ 2+i*4],xp[1]);

  286.         tab[ 2+i*4] = (tab[28-i*4] - xr);

  287.         tab[28-i*4] = (tab[28-i*4] + xr);

  288. 

  289.         xr = MUL(tab[31-i*4],xp[0]);

  290.         tab[31-i*4] = (tab[1+i*4] - xr);

  291.         tab[ 1+i*4] = (tab[1+i*4] + xr);

  292. 

  293.         xr = MUL(tab[ 3+i*4],xp[1]);

  294.         tab[ 3+i*4] = (tab[29-i*4] - xr);

  295.         tab[29-i*4] = (tab[29-i*4] + xr);

  296. 

  297.         xp += 2;

  298.     }

  299. 

  300.     t = tab + 30;

  301.     t1 = tab + 1;

  302.     do {

  303.         xr = MUL(t1[0], *xp);

  304.         t1[0] = (t[0] - xr);

  305.         t[0] = (t[0] + xr);

  306.         t -= 2;

  307.         t1 += 2;

  308.         xp++;

  309.     } while (t >= tab);

  310. 

  311.     for(i=0;i<32;i++) {

  312.         out[i] = tab[bitinv32[i]];

  313.     }

  314. }

  315. 

  316. #define WSHIFT (WFRAC_BITS + 15 - FRAC_BITS)

  317. 

  318. static void filter(MpegAudioContext *s, int ch, const short *samples, int incr)

  319. {

  320.     short *p, *q;

  321.     int sum, offset, i, j;

  322.     int tmp[64];

  323.     int tmp1[32];

  324.     int *out;

  325. 

  326.     offset = s->samples_offset[ch];

  327.     out = &s->sb_samples[ch][0][0][0];

  328.     for(j=0;j<36;j++) {

  329.         /* 32 samples at once */

  330.         for(i=0;i<32;i++) {

  331.             s->samples_buf[ch][offset + (31 - i)] = samples[0];

  332.             samples += incr;

  333.         }

  334. 

  335.         /* filter */

  336.         p = s->samples_buf[ch] + offset;

  337.         q = filter_bank;

  338.         /* maxsum = 23169 */

  339.         for(i=0;i<64;i++) {

  340.             sum = p[0*64] * q[0*64];

  341.             sum += p[1*64] * q[1*64];

  342.             sum += p[2*64] * q[2*64];

  343.             sum += p[3*64] * q[3*64];

  344.             sum += p[4*64] * q[4*64];

  345.             sum += p[5*64] * q[5*64];

  346.             sum += p[6*64] * q[6*64];

  347.             sum += p[7*64] * q[7*64];

  348.             tmp[i] = sum;

  349.             p++;

  350.             q++;

  351.         }

  352.         tmp1[0] = tmp[16] >> WSHIFT;

  353.         for( i=1; i<=16; i++ ) tmp1[i] = (tmp[i+16]+tmp[16-i]) >> WSHIFT;

  354.         for( i=17; i<=31; i++ ) tmp1[i] = (tmp[i+16]-tmp[80-i]) >> WSHIFT;

  355. 

  356.         idct32(out, tmp1);

  357. 

  358.         /* advance of 32 samples */

  359.         offset -= 32;

  360.         out += 32;

  361.         /* handle the wrap around */

  362.         if (offset < 0) {

  363.             memmove(s->samples_buf[ch] + SAMPLES_BUF_SIZE - (512 - 32),

  364.                     s->samples_buf[ch], (512 - 32) * 2);

  365.             offset = SAMPLES_BUF_SIZE - 512;

  366.         }

  367.     }

  368.     s->samples_offset[ch] = offset;

  369. }

  370. 

  371. static void compute_scale_factors(unsigned char scale_code[SBLIMIT],

  372.                                   unsigned char scale_factors[SBLIMIT][3],

  373.                                   int sb_samples[3][12][SBLIMIT],

  374.                                   int sblimit)

  375. {

  376.     int *p, vmax, v, n, i, j, k, code;

  377.     int index, d1, d2;

  378.     unsigned char *sf = &scale_factors[0][0];

  379. 

  380.     for(j=0;j<sblimit;j++) {

  381.         for(i=0;i<3;i++) {

  382.             /* find the max absolute value */

  383.             p = &sb_samples[i][0][j];

  384.             vmax = abs(*p);

  385.             for(k=1;k<12;k++) {

  386.                 p += SBLIMIT;

  387.                 v = abs(*p);

  388.                 if (v > vmax)

  389.                     vmax = v;

  390.             }

  391.             /* compute the scale factor index using log 2 computations */

  392.             if (vmax > 1) {

  393.                 n = av_log2(vmax);

  394.                 /* n is the position of the MSB of vmax. now

  395.                    use at most 2 compares to find the index */

  396.                 index = (21 - n) * 3 - 3;

  397.                 if (index >= 0) {

  398.                     while (vmax <= scale_factor_table[index+1])

  399.                         index++;

  400.                 } else {

  401.                     index = 0; /* very unlikely case of overflow */

  402.                 }

  403.             } else {

  404.                 index = 62; /* value 63 is not allowed */

  405.             }

  406. 

  407.             av_dlog(NULL, "%2d:%d in=%x %x %d\n",

  408.                     j, i, vmax, scale_factor_table[index], index);

  409.             /* store the scale factor */

  410.             av_assert2(index >=0 && index <= 63);

  411.             sf[i] = index;

  412.         }

  413. 

  414.         /* compute the transmission factor : look if the scale factors

  415.            are close enough to each other */

  416.         d1 = scale_diff_table[sf[0] - sf[1] + 64];

  417.         d2 = scale_diff_table[sf[1] - sf[2] + 64];

  418. 

  419.         /* handle the 25 cases */

  420.         switch(d1 * 5 + d2) {

  421.         case 0*5+0:

  422.         case 0*5+4:

  423.         case 3*5+4:

  424.         case 4*5+0:

  425.         case 4*5+4:

  426.             code = 0;

  427.             break;

  428.         case 0*5+1:

  429.         case 0*5+2:

  430.         case 4*5+1:

  431.         case 4*5+2:

  432.             code = 3;

  433.             sf[2] = sf[1];

  434.             break;

  435.         case 0*5+3:

  436.         case 4*5+3:

  437.             code = 3;

  438.             sf[1] = sf[2];

  439.             break;

  440.         case 1*5+0:

  441.         case 1*5+4:

  442.         case 2*5+4:

  443.             code = 1;

  444.             sf[1] = sf[0];

  445.             break;

  446.         case 1*5+1:

  447.         case 1*5+2:

  448.         case 2*5+0:

  449.         case 2*5+1:

  450.         case 2*5+2:

  451.             code = 2;

  452.             sf[1] = sf[2] = sf[0];

  453.             break;

  454.         case 2*5+3:

  455.         case 3*5+3:

  456.             code = 2;

  457.             sf[0] = sf[1] = sf[2];

  458.             break;

  459.         case 3*5+0:

  460.         case 3*5+1:

  461.         case 3*5+2:

  462.             code = 2;

  463.             sf[0] = sf[2] = sf[1];

  464.             break;

  465.         case 1*5+3:

  466.             code = 2;

  467.             if (sf[0] > sf[2])

  468.               sf[0] = sf[2];

  469.             sf[1] = sf[2] = sf[0];

  470.             break;

  471.         default:

  472.             av_assert2(0); //cannot happen

  473.             code = 0;           /* kill warning */

  474.         }

  475. 

  476.         av_dlog(NULL, "%d: %2d %2d %2d %d %d -> %d\n", j,

  477.                 sf[0], sf[1], sf[2], d1, d2, code);

  478.         scale_code[j] = code;

  479.         sf += 3;

  480.     }

  481. }

  482. 

  483. /* The most important function : psycho acoustic module. In this

  484.    encoder there is basically none, so this is the worst you can do,

  485.    but also this is the simpler. */

  486. static void psycho_acoustic_model(MpegAudioContext *s, short smr[SBLIMIT])

  487. {

  488.     int i;

  489. 

  490.     for(i=0;i<s->sblimit;i++) {

  491.         smr[i] = (int)(fixed_smr[i] * 10);

  492.     }

  493. }

  494. 

  495. 

  496. #define SB_NOTALLOCATED  0

  497. #define SB_ALLOCATED     1

  498. #define SB_NOMORE        2

  499. 

  500. /* Try to maximize the smr while using a number of bits inferior to

  501.    the frame size. I tried to make the code simpler, faster and

  502.    smaller than other encoders :-) */

  503. static void compute_bit_allocation(MpegAudioContext *s,

  504.                                    short smr1[MPA_MAX_CHANNELS][SBLIMIT],

  505.                                    unsigned char bit_alloc[MPA_MAX_CHANNELS][SBLIMIT],

  506.                                    int *padding)

  507. {

  508.     int i, ch, b, max_smr, max_ch, max_sb, current_frame_size, max_frame_size;

  509.     int incr;

  510.     short smr[MPA_MAX_CHANNELS][SBLIMIT];

  511.     unsigned char subband_status[MPA_MAX_CHANNELS][SBLIMIT];

  512.     const unsigned char *alloc;

  513. 

  514.     memcpy(smr, smr1, s->nb_channels * sizeof(short) * SBLIMIT);

  515.     memset(subband_status, SB_NOTALLOCATED, s->nb_channels * SBLIMIT);

  516.     memset(bit_alloc, 0, s->nb_channels * SBLIMIT);

  517. 

  518.     /* compute frame size and padding */

  519.     max_frame_size = s->frame_size;

  520.     s->frame_frac += s->frame_frac_incr;

  521.     if (s->frame_frac >= 65536) {

  522.         s->frame_frac -= 65536;

  523.         s->do_padding = 1;

  524.         max_frame_size += 8;

  525.     } else {

  526.         s->do_padding = 0;

  527.     }

  528. 

  529.     /* compute the header + bit alloc size */

  530.     current_frame_size = 32;

  531.     alloc = s->alloc_table;

  532.     for(i=0;i<s->sblimit;i++) {

  533.         incr = alloc[0];

  534.         current_frame_size += incr * s->nb_channels;

  535.         alloc += 1 << incr;

  536.     }

  537.     for(;;) {

  538.         /* look for the subband with the largest signal to mask ratio */

  539.         max_sb = -1;

  540.         max_ch = -1;

  541.         max_smr = INT_MIN;

  542.         for(ch=0;ch<s->nb_channels;ch++) {

  543.             for(i=0;i<s->sblimit;i++) {

  544.                 if (smr[ch][i] > max_smr && subband_status[ch][i] != SB_NOMORE) {

  545.                     max_smr = smr[ch][i];

  546.                     max_sb = i;

  547.                     max_ch = ch;

  548.                 }

  549.             }

  550.         }

  551.         if (max_sb < 0)

  552.             break;

  553.         av_dlog(NULL, "current=%d max=%d max_sb=%d max_ch=%d alloc=%d\n",

  554.                 current_frame_size, max_frame_size, max_sb, max_ch,

  555.                 bit_alloc[max_ch][max_sb]);

  556. 

  557.         /* find alloc table entry (XXX: not optimal, should use

  558.            pointer table) */

  559.         alloc = s->alloc_table;

  560.         for(i=0;i<max_sb;i++) {

  561.             alloc += 1 << alloc[0];

  562.         }

  563. 

  564.         if (subband_status[max_ch][max_sb] == SB_NOTALLOCATED) {

  565.             /* nothing was coded for this band: add the necessary bits */

  566.             incr = 2 + nb_scale_factors[s->scale_code[max_ch][max_sb]] * 6;

  567.             incr += total_quant_bits[alloc[1]];

  568.         } else {

  569.             /* increments bit allocation */

  570.             b = bit_alloc[max_ch][max_sb];

  571.             incr = total_quant_bits[alloc[b + 1]] -

  572.                 total_quant_bits[alloc[b]];

  573.         }

  574. 

  575.         if (current_frame_size + incr <= max_frame_size) {

  576.             /* can increase size */

  577.             b = ++bit_alloc[max_ch][max_sb];

  578.             current_frame_size += incr;

  579.             /* decrease smr by the resolution we added */

  580.             smr[max_ch][max_sb] = smr1[max_ch][max_sb] - quant_snr[alloc[b]];

  581.             /* max allocation size reached ? */

  582.             if (b == ((1 << alloc[0]) - 1))

  583.                 subband_status[max_ch][max_sb] = SB_NOMORE;

  584.             else

  585.                 subband_status[max_ch][max_sb] = SB_ALLOCATED;

  586.         } else {

  587.             /* cannot increase the size of this subband */

  588.             subband_status[max_ch][max_sb] = SB_NOMORE;

  589.         }

  590.     }

  591.     *padding = max_frame_size - current_frame_size;

  592.     av_assert0(*padding >= 0);

  593. }

  594. 

  595. /*

  596.  * Output the mpeg audio layer 2 frame. Note how the code is small

  597.  * compared to other encoders :-)

  598.  */

  599. static void encode_frame(MpegAudioContext *s,

  600.                          unsigned char bit_alloc[MPA_MAX_CHANNELS][SBLIMIT],

  601.                          int padding)

  602. {

  603.     int i, j, k, l, bit_alloc_bits, b, ch;

  604.     unsigned char *sf;

  605.     int q[3];

  606.     PutBitContext *p = &s->pb;

  607. 

  608.     /* header */

  609. 

  610.     put_bits(p, 12, 0xfff);

  611.     put_bits(p, 1, 1 - s->lsf); /* 1 = mpeg1 ID, 0 = mpeg2 lsf ID */

  612.     put_bits(p, 2, 4-2);  /* layer 2 */

  613.     put_bits(p, 1, 1); /* no error protection */

  614.     put_bits(p, 4, s->bitrate_index);

  615.     put_bits(p, 2, s->freq_index);

  616.     put_bits(p, 1, s->do_padding); /* use padding */

  617.     put_bits(p, 1, 0);             /* private_bit */

  618.     put_bits(p, 2, s->nb_channels == 2 ? MPA_STEREO : MPA_MONO);

  619.     put_bits(p, 2, 0); /* mode_ext */

  620.     put_bits(p, 1, 0); /* no copyright */

  621.     put_bits(p, 1, 1); /* original */

  622.     put_bits(p, 2, 0); /* no emphasis */

  623. 

  624.     /* bit allocation */

  625.     j = 0;

  626.     for(i=0;i<s->sblimit;i++) {

  627.         bit_alloc_bits = s->alloc_table[j];

  628.         for(ch=0;ch<s->nb_channels;ch++) {

  629.             put_bits(p, bit_alloc_bits, bit_alloc[ch][i]);

  630.         }

  631.         j += 1 << bit_alloc_bits;

  632.     }

  633. 

  634.     /* scale codes */

  635.     for(i=0;i<s->sblimit;i++) {

  636.         for(ch=0;ch<s->nb_channels;ch++) {

  637.             if (bit_alloc[ch][i])

  638.                 put_bits(p, 2, s->scale_code[ch][i]);

  639.         }

  640.     }

  641. 

  642.     /* scale factors */

  643.     for(i=0;i<s->sblimit;i++) {

  644.         for(ch=0;ch<s->nb_channels;ch++) {

  645.             if (bit_alloc[ch][i]) {

  646.                 sf = &s->scale_factors[ch][i][0];

  647.                 switch(s->scale_code[ch][i]) {

  648.                 case 0:

  649.                     put_bits(p, 6, sf[0]);

  650.                     put_bits(p, 6, sf[1]);

  651.                     put_bits(p, 6, sf[2]);

  652.                     break;

  653.                 case 3:

  654.                 case 1:

  655.                     put_bits(p, 6, sf[0]);

  656.                     put_bits(p, 6, sf[2]);

  657.                     break;

  658.                 case 2:

  659.                     put_bits(p, 6, sf[0]);

  660.                     break;

  661.                 }

  662.             }

  663.         }

  664.     }

  665. 

  666.     /* quantization & write sub band samples */

  667. 

  668.     for(k=0;k<3;k++) {

  669.         for(l=0;l<12;l+=3) {

  670.             j = 0;

  671.             for(i=0;i<s->sblimit;i++) {

  672.                 bit_alloc_bits = s->alloc_table[j];

  673.                 for(ch=0;ch<s->nb_channels;ch++) {

  674.                     b = bit_alloc[ch][i];

  675.                     if (b) {

  676.                         int qindex, steps, m, sample, bits;

  677.                         /* we encode 3 sub band samples of the same sub band at a time */

  678.                         qindex = s->alloc_table[j+b];

  679.                         steps = ff_mpa_quant_steps[qindex];

  680.                         for(m=0;m<3;m++) {

  681.                             sample = s->sb_samples[ch][k][l + m][i];

  682.                             /* divide by scale factor */

  683. #ifdef USE_FLOATS

  684.                             {

  685.                                 float a;

  686.                                 a = (float)sample * scale_factor_inv_table[s->scale_factors[ch][i][k]];

  687.                                 q[m] = (int)((a + 1.0) * steps * 0.5);

  688.                             }

  689. #else

  690.                             {

  691.                                 int q1, e, shift, mult;

  692.                                 e = s->scale_factors[ch][i][k];

  693.                                 shift = scale_factor_shift[e];

  694.                                 mult = scale_factor_mult[e];

  695. 

  696.                                 /* normalize to P bits */

  697.                                 if (shift < 0)

  698.                                     q1 = sample << (-shift);

  699.                                 else

  700.                                     q1 = sample >> shift;

  701.                                 q1 = (q1 * mult) >> P;

  702.                                 q[m] = ((q1 + (1 << P)) * steps) >> (P + 1);

  703.                             }

  704. #endif

  705.                             if (q[m] >= steps)

  706.                                 q[m] = steps - 1;

  707.                             av_assert2(q[m] >= 0 && q[m] < steps);

  708.                         }

  709.                         bits = ff_mpa_quant_bits[qindex];

  710.                         if (bits < 0) {

  711.                             /* group the 3 values to save bits */

  712.                             put_bits(p, -bits,

  713.                                      q[0] + steps * (q[1] + steps * q[2]));

  714.                         } else {

  715.                             put_bits(p, bits, q[0]);

  716.                             put_bits(p, bits, q[1]);

  717.                             put_bits(p, bits, q[2]);

  718.                         }

  719.                     }

  720.                 }

  721.                 /* next subband in alloc table */

  722.                 j += 1 << bit_alloc_bits;

  723.             }

  724.         }

  725.     }

  726. 

  727.     /* padding */

  728.     for(i=0;i<padding;i++)

  729.         put_bits(p, 1, 0);

  730. 

  731.     /* flush */

  732.     flush_put_bits(p);

  733. }

  734. 

  735. static int MPA_encode_frame(AVCodecContext *avctx, AVPacket *avpkt,

  736.                             const AVFrame *frame, int *got_packet_ptr)

  737. {

  738.     MpegAudioContext *s = avctx->priv_data;

  739.     const int16_t *samples = (const int16_t *)frame->data[0];

  740.     short smr[MPA_MAX_CHANNELS][SBLIMIT];

  741.     unsigned char bit_alloc[MPA_MAX_CHANNELS][SBLIMIT];

  742.     int padding, i, ret;

  743. 

  744.     for(i=0;i<s->nb_channels;i++) {

  745.         filter(s, i, samples + i, s->nb_channels);

  746.     }

  747. 

  748.     for(i=0;i<s->nb_channels;i++) {

  749.         compute_scale_factors(s->scale_code[i], s->scale_factors[i],

  750.                               s->sb_samples[i], s->sblimit);

  751.     }

  752.     for(i=0;i<s->nb_channels;i++) {

  753.         psycho_acoustic_model(s, smr[i]);

  754.     }

  755.     compute_bit_allocation(s, smr, bit_alloc, &padding);

  756. 

  757.     if ((ret = ff_alloc_packet2(avctx, avpkt, MPA_MAX_CODED_FRAME_SIZE)))

  758.         return ret;

  759. 

  760.     init_put_bits(&s->pb, avpkt->data, avpkt->size);

  761. 

  762.     encode_frame(s, bit_alloc, padding);

  763. 

  764.     if (frame->pts != AV_NOPTS_VALUE)

  765.         avpkt->pts = frame->pts - ff_samples_to_time_base(avctx, avctx->delay);

  766. 

  767.     avpkt->size = put_bits_count(&s->pb) / 8;

  768.     *got_packet_ptr = 1;

  769.     return 0;

  770. }

  771. 

  772. static av_cold int MPA_encode_close(AVCodecContext *avctx)

  773. {

  774. #if FF_API_OLD_ENCODE_AUDIO

  775.     av_freep(&avctx->coded_frame);

  776. #endif

  777.     return 0;

  778. }

  779. 

  780. static const AVCodecDefault mp2_defaults[] = {

  781.     { "b",    "128k" },

  782.     { NULL },

  783. };

  784. 

  785. AVCodec ff_mp2_encoder = {

  786.     .name                  = "mp2",

  787.     .type                  = AVMEDIA_TYPE_AUDIO,

  788.     .id                    = AV_CODEC_ID_MP2,

  789.     .priv_data_size        = sizeof(MpegAudioContext),

  790.     .init                  = MPA_encode_init,

  791.     .encode2               = MPA_encode_frame,

  792.     .close                 = MPA_encode_close,

  793.     .sample_fmts           = (const enum AVSampleFormat[]){ AV_SAMPLE_FMT_S16,

  794.                                                             AV_SAMPLE_FMT_NONE },

  795.     .supported_samplerates = (const int[]){

  796.         44100, 48000,  32000, 22050, 24000, 16000, 0

  797.     },

  798.     .channel_layouts       = (const uint64_t[]){ AV_CH_LAYOUT_MONO,

  799.                                                  AV_CH_LAYOUT_STEREO,

  800.                                                  0 },

  801.     .long_name             = NULL_IF_CONFIG_SMALL("MP2 (MPEG audio layer 2)"),

  802.     .defaults              = mp2_defaults,

  803. };