winamp/Src/external_dependencies/openmpt-trunk/include/lame/libmp3lame/encoder.c

/*
 *      LAME MP3 encoding engine
 *
 *      Copyright (c) 1999 Mark Taylor
 *      Copyright (c) 2000-2002 Takehiro Tominaga
 *      Copyright (c) 2000-2011 Robert Hegemann
 *      Copyright (c) 2001 Gabriel Bouvigne
 *      Copyright (c) 2001 John Dahlstrom
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Library 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
 * Library General Public License for more details.
 *
 * You should have received a copy of the GNU Library General Public
 * License along with this library; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 */

/* $Id: encoder.c,v 1.114 2017/08/26 10:54:57 robert Exp $ */

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif


#include "lame.h"
#include "machine.h"
#include "encoder.h"
#include "util.h"
#include "lame_global_flags.h"
#include "newmdct.h"
#include "psymodel.h"
#include "lame-analysis.h"
#include "bitstream.h"
#include "VbrTag.h"
#include "quantize.h"
#include "quantize_pvt.h"


/*
 * auto-adjust of ATH, useful for low volume
 * Gabriel Bouvigne 3 feb 2001
 *
 * modifies some values in
 *   gfp->internal_flags->ATH
 *   (gfc->ATH)
 */
static void
adjust_ATH(lame_internal_flags const *const gfc)
{
    SessionConfig_t const *const cfg = &gfc->cfg;
    FLOAT   gr2_max, max_pow;

    if (gfc->ATH->use_adjust == 0) {
        gfc->ATH->adjust_factor = 1.0; /* no adjustment */
        return;
    }

    /* jd - 2001 mar 12, 27, jun 30 */
    /* loudness based on equal loudness curve; */
    /* use granule with maximum combined loudness */
    max_pow = gfc->ov_psy.loudness_sq[0][0];
    gr2_max = gfc->ov_psy.loudness_sq[1][0];
    if (cfg->channels_out == 2) {
        max_pow += gfc->ov_psy.loudness_sq[0][1];
        gr2_max += gfc->ov_psy.loudness_sq[1][1];
    }
    else {
        max_pow += max_pow;
        gr2_max += gr2_max;
    }
    if (cfg->mode_gr == 2) {
        max_pow = Max(max_pow, gr2_max);
    }
    max_pow *= 0.5;     /* max_pow approaches 1.0 for full band noise */

    /* jd - 2001 mar 31, jun 30 */
    /* user tuning of ATH adjustment region */
    max_pow *= gfc->ATH->aa_sensitivity_p;

    /*  adjust ATH depending on range of maximum value
     */

    /* jd - 2001 feb27, mar12,20, jun30, jul22 */
    /* continuous curves based on approximation */
    /* to GB's original values. */
    /* For an increase in approximate loudness, */
    /* set ATH adjust to adjust_limit immediately */
    /* after a delay of one frame. */
    /* For a loudness decrease, reduce ATH adjust */
    /* towards adjust_limit gradually. */
    /* max_pow is a loudness squared or a power. */
    if (max_pow > 0.03125) { /* ((1 - 0.000625)/ 31.98) from curve below */
        if (gfc->ATH->adjust_factor >= 1.0) {
            gfc->ATH->adjust_factor = 1.0;
        }
        else {
            /* preceding frame has lower ATH adjust; */
            /* ascend only to the preceding adjust_limit */
            /* in case there is leading low volume */
            if (gfc->ATH->adjust_factor < gfc->ATH->adjust_limit) {
                gfc->ATH->adjust_factor = gfc->ATH->adjust_limit;
            }
        }
        gfc->ATH->adjust_limit = 1.0;
    }
    else {              /* adjustment curve */
        /* about 32 dB maximum adjust (0.000625) */
        FLOAT const adj_lim_new = 31.98 * max_pow + 0.000625;
        if (gfc->ATH->adjust_factor >= adj_lim_new) { /* descend gradually */
            gfc->ATH->adjust_factor *= adj_lim_new * 0.075 + 0.925;
            if (gfc->ATH->adjust_factor < adj_lim_new) { /* stop descent */
                gfc->ATH->adjust_factor = adj_lim_new;
            }
        }
        else {          /* ascend */
            if (gfc->ATH->adjust_limit >= adj_lim_new) {
                gfc->ATH->adjust_factor = adj_lim_new;
            }
            else {      /* preceding frame has lower ATH adjust; */
                /* ascend only to the preceding adjust_limit */
                if (gfc->ATH->adjust_factor < gfc->ATH->adjust_limit) {
                    gfc->ATH->adjust_factor = gfc->ATH->adjust_limit;
                }
            }
        }
        gfc->ATH->adjust_limit = adj_lim_new;
    }
}

/***********************************************************************
 *
 *  some simple statistics
 *
 *  bitrate index 0: free bitrate -> not allowed in VBR mode
 *  : bitrates, kbps depending on MPEG version
 *  bitrate index 15: forbidden
 *
 *  mode_ext:
 *  0:  LR
 *  1:  LR-i
 *  2:  MS
 *  3:  MS-i
 *
 ***********************************************************************/

static void
updateStats(lame_internal_flags * const gfc)
{
    SessionConfig_t const *const cfg = &gfc->cfg;
    EncResult_t *eov = &gfc->ov_enc;
    int     gr, ch;
    assert(0 <= eov->bitrate_index && eov->bitrate_index < 16);
    assert(0 <= eov->mode_ext && eov->mode_ext < 4);

    /* count bitrate indices */
    eov->bitrate_channelmode_hist[eov->bitrate_index][4]++;
    eov->bitrate_channelmode_hist[15][4]++;

    /* count 'em for every mode extension in case of 2 channel encoding */
    if (cfg->channels_out == 2) {
        eov->bitrate_channelmode_hist[eov->bitrate_index][eov->mode_ext]++;
        eov->bitrate_channelmode_hist[15][eov->mode_ext]++;
    }
    for (gr = 0; gr < cfg->mode_gr; ++gr) {
        for (ch = 0; ch < cfg->channels_out; ++ch) {
            int     bt = gfc->l3_side.tt[gr][ch].block_type;
            if (gfc->l3_side.tt[gr][ch].mixed_block_flag)
                bt = 4;
            eov->bitrate_blocktype_hist[eov->bitrate_index][bt]++;
            eov->bitrate_blocktype_hist[eov->bitrate_index][5]++;
            eov->bitrate_blocktype_hist[15][bt]++;
            eov->bitrate_blocktype_hist[15][5]++;
        }
    }
}


static void
lame_encode_frame_init(lame_internal_flags * gfc, const sample_t *const inbuf[2])
{
    SessionConfig_t const *const cfg = &gfc->cfg;

    int     ch, gr;

    if (gfc->lame_encode_frame_init == 0) {
        sample_t primebuff0[286 + 1152 + 576];
        sample_t primebuff1[286 + 1152 + 576];
        int const framesize = 576 * cfg->mode_gr;
        /* prime the MDCT/polyphase filterbank with a short block */
        int     i, j;
        gfc->lame_encode_frame_init = 1;
        memset(primebuff0, 0, sizeof(primebuff0));
        memset(primebuff1, 0, sizeof(primebuff1));
        for (i = 0, j = 0; i < 286 + 576 * (1 + cfg->mode_gr); ++i) {
            if (i < framesize) {
                primebuff0[i] = 0;
                if (cfg->channels_out == 2)
                    primebuff1[i] = 0;
            }
            else {
                primebuff0[i] = inbuf[0][j];
                if (cfg->channels_out == 2)
                    primebuff1[i] = inbuf[1][j];
                ++j;
            }
        }
        /* polyphase filtering / mdct */
        for (gr = 0; gr < cfg->mode_gr; gr++) {
            for (ch = 0; ch < cfg->channels_out; ch++) {
                gfc->l3_side.tt[gr][ch].block_type = SHORT_TYPE;
            }
        }
        mdct_sub48(gfc, primebuff0, primebuff1);

        /* check FFT will not use a negative starting offset */
#if 576 < FFTOFFSET
# error FFTOFFSET greater than 576: FFT uses a negative offset
#endif
        /* check if we have enough data for FFT */
        assert(gfc->sv_enc.mf_size >= (BLKSIZE + framesize - FFTOFFSET));
        /* check if we have enough data for polyphase filterbank */
        assert(gfc->sv_enc.mf_size >= (512 + framesize - 32));
    }

}


/************************************************************************
*
* encodeframe()           Layer 3
*
* encode a single frame
*
************************************************************************
lame_encode_frame()


                       gr 0            gr 1
inbuf:           |--------------|--------------|--------------|


Polyphase (18 windows, each shifted 32)
gr 0:
window1          <----512---->
window18                 <----512---->

gr 1:
window1                         <----512---->
window18                                <----512---->


MDCT output:  |--------------|--------------|--------------|

FFT's                    <---------1024---------->
                                         <---------1024-------->


    inbuf = buffer of PCM data size=MP3 framesize
    encoder acts on inbuf[ch][0], but output is delayed by MDCTDELAY
    so the MDCT coefficints are from inbuf[ch][-MDCTDELAY]

    psy-model FFT has a 1 granule delay, so we feed it data for the 
    next granule.
    FFT is centered over granule:  224+576+224
    So FFT starts at:   576-224-MDCTDELAY

    MPEG2:  FFT ends at:  BLKSIZE+576-224-MDCTDELAY      (1328)
    MPEG1:  FFT ends at:  BLKSIZE+2*576-224-MDCTDELAY    (1904)

    MPEG2:  polyphase first window:  [0..511]
                      18th window:   [544..1055]          (1056)
    MPEG1:            36th window:   [1120..1631]         (1632)
            data needed:  512+framesize-32

    A close look newmdct.c shows that the polyphase filterbank
    only uses data from [0..510] for each window.  Perhaps because the window
    used by the filterbank is zero for the last point, so Takehiro's
    code doesn't bother to compute with it.

    FFT starts at 576-224-MDCTDELAY (304)  = 576-FFTOFFSET

*/

typedef FLOAT chgrdata[2][2];


int
lame_encode_mp3_frame(       /* Output */
                         lame_internal_flags * gfc, /* Context */
                         sample_t const *inbuf_l, /* Input */
                         sample_t const *inbuf_r, /* Input */
                         unsigned char *mp3buf, /* Output */
                         int mp3buf_size)
{                       /* Output */
    SessionConfig_t const *const cfg = &gfc->cfg;
    int     mp3count;
    III_psy_ratio masking_LR[2][2]; /*LR masking & energy */
    III_psy_ratio masking_MS[2][2]; /*MS masking & energy */
    const III_psy_ratio (*masking)[2]; /*pointer to selected maskings */
    const sample_t *inbuf[2];

    FLOAT   tot_ener[2][4];
    FLOAT   ms_ener_ratio[2] = { .5, .5 };
    FLOAT   pe[2][2] = { {0., 0.}, {0., 0.} }, pe_MS[2][2] = { {
    0., 0.}, {
    0., 0.}};
    FLOAT (*pe_use)[2];

    int     ch, gr;

    inbuf[0] = inbuf_l;
    inbuf[1] = inbuf_r;

    if (gfc->lame_encode_frame_init == 0) {
        /*first run? */
        lame_encode_frame_init(gfc, inbuf);

    }


    /********************** padding *****************************/
    /* padding method as described in 
     * "MPEG-Layer3 / Bitstream Syntax and Decoding"
     * by Martin Sieler, Ralph Sperschneider
     *
     * note: there is no padding for the very first frame
     *
     * Robert Hegemann 2000-06-22
     */
    gfc->ov_enc.padding = FALSE;
    if ((gfc->sv_enc.slot_lag -= gfc->sv_enc.frac_SpF) < 0) {
        gfc->sv_enc.slot_lag += cfg->samplerate_out;
        gfc->ov_enc.padding = TRUE;
    }


    /****************************************
    *   Stage 1: psychoacoustic model       *
    ****************************************/

    {
        /* psychoacoustic model
         * psy model has a 1 granule (576) delay that we must compensate for
         * (mt 6/99).
         */
        int     ret;
        const sample_t *bufp[2] = {0, 0}; /* address of beginning of left & right granule */
        int     blocktype[2];

        for (gr = 0; gr < cfg->mode_gr; gr++) {

            for (ch = 0; ch < cfg->channels_out; ch++) {
                bufp[ch] = &inbuf[ch][576 + gr * 576 - FFTOFFSET];
            }
            ret = L3psycho_anal_vbr(gfc, bufp, gr,
                                    masking_LR, masking_MS,
                                    pe[gr], pe_MS[gr], tot_ener[gr], blocktype);
            if (ret != 0)
                return -4;

            if (cfg->mode == JOINT_STEREO) {
                ms_ener_ratio[gr] = tot_ener[gr][2] + tot_ener[gr][3];
                if (ms_ener_ratio[gr] > 0)
                    ms_ener_ratio[gr] = tot_ener[gr][3] / ms_ener_ratio[gr];
            }

            /* block type flags */
            for (ch = 0; ch < cfg->channels_out; ch++) {
                gr_info *const cod_info = &gfc->l3_side.tt[gr][ch];
                cod_info->block_type = blocktype[ch];
                cod_info->mixed_block_flag = 0;
            }
        }
    }


    /* auto-adjust of ATH, useful for low volume */
    adjust_ATH(gfc);


    /****************************************
    *   Stage 2: MDCT                       *
    ****************************************/

    /* polyphase filtering / mdct */
    mdct_sub48(gfc, inbuf[0], inbuf[1]);


    /****************************************
    *   Stage 3: MS/LR decision             *
    ****************************************/

    /* Here will be selected MS or LR coding of the 2 stereo channels */
    gfc->ov_enc.mode_ext = MPG_MD_LR_LR;

    if (cfg->force_ms) {
        gfc->ov_enc.mode_ext = MPG_MD_MS_LR;
    }
    else if (cfg->mode == JOINT_STEREO) {
        /* ms_ratio = is scaled, for historical reasons, to look like
           a ratio of side_channel / total.
           0 = signal is 100% mono
           .5 = L & R uncorrelated
         */

        /* [0] and [1] are the results for the two granules in MPEG-1,
         * in MPEG-2 it's only a faked averaging of the same value
         * _prev is the value of the last granule of the previous frame
         * _next is the value of the first granule of the next frame
         */

        FLOAT   sum_pe_MS = 0;
        FLOAT   sum_pe_LR = 0;
        for (gr = 0; gr < cfg->mode_gr; gr++) {
            for (ch = 0; ch < cfg->channels_out; ch++) {
                sum_pe_MS += pe_MS[gr][ch];
                sum_pe_LR += pe[gr][ch];
            }
        }

        /* based on PE: M/S coding would not use much more bits than L/R */
        if (sum_pe_MS <= 1.00 * sum_pe_LR) {

            gr_info const *const gi0 = &gfc->l3_side.tt[0][0];
            gr_info const *const gi1 = &gfc->l3_side.tt[cfg->mode_gr - 1][0];

            if (gi0[0].block_type == gi0[1].block_type && gi1[0].block_type == gi1[1].block_type) {

                gfc->ov_enc.mode_ext = MPG_MD_MS_LR;
            }
        }
    }

    /* bit and noise allocation */
    if (gfc->ov_enc.mode_ext == MPG_MD_MS_LR) {
        masking = (const III_psy_ratio (*)[2])masking_MS; /* use MS masking */
        pe_use = pe_MS;
    }
    else {
        masking = (const III_psy_ratio (*)[2])masking_LR; /* use LR masking */
        pe_use = pe;
    }


    /* copy data for MP3 frame analyzer */
    if (cfg->analysis && gfc->pinfo != NULL) {
        for (gr = 0; gr < cfg->mode_gr; gr++) {
            for (ch = 0; ch < cfg->channels_out; ch++) {
                gfc->pinfo->ms_ratio[gr] = 0;
                gfc->pinfo->ms_ener_ratio[gr] = ms_ener_ratio[gr];
                gfc->pinfo->blocktype[gr][ch] = gfc->l3_side.tt[gr][ch].block_type;
                gfc->pinfo->pe[gr][ch] = pe_use[gr][ch];
                memcpy(gfc->pinfo->xr[gr][ch], &gfc->l3_side.tt[gr][ch].xr[0], sizeof(FLOAT) * 576);
                /* in psymodel, LR and MS data was stored in pinfo.  
                   switch to MS data: */
                if (gfc->ov_enc.mode_ext == MPG_MD_MS_LR) {
                    gfc->pinfo->ers[gr][ch] = gfc->pinfo->ers[gr][ch + 2];
                    memcpy(gfc->pinfo->energy[gr][ch], gfc->pinfo->energy[gr][ch + 2],
                           sizeof(gfc->pinfo->energy[gr][ch]));
                }
            }
        }
    }


    /****************************************
    *   Stage 4: quantization loop          *
    ****************************************/

    if (cfg->vbr == vbr_off || cfg->vbr == vbr_abr) {
        static FLOAT const fircoef[9] = {
            -0.0207887 * 5, -0.0378413 * 5, -0.0432472 * 5, -0.031183 * 5,
            7.79609e-18 * 5, 0.0467745 * 5, 0.10091 * 5, 0.151365 * 5,
            0.187098 * 5
        };

        int     i;
        FLOAT   f;

        for (i = 0; i < 18; i++)
            gfc->sv_enc.pefirbuf[i] = gfc->sv_enc.pefirbuf[i + 1];

        f = 0.0;
        for (gr = 0; gr < cfg->mode_gr; gr++)
            for (ch = 0; ch < cfg->channels_out; ch++)
                f += pe_use[gr][ch];
        gfc->sv_enc.pefirbuf[18] = f;

        f = gfc->sv_enc.pefirbuf[9];
        for (i = 0; i < 9; i++)
            f += (gfc->sv_enc.pefirbuf[i] + gfc->sv_enc.pefirbuf[18 - i]) * fircoef[i];

        f = (670 * 5 * cfg->mode_gr * cfg->channels_out) / f;
        for (gr = 0; gr < cfg->mode_gr; gr++) {
            for (ch = 0; ch < cfg->channels_out; ch++) {
                pe_use[gr][ch] *= f;
            }
        }
    }
    switch (cfg->vbr)
    {
    default:
    case vbr_off:
        CBR_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);
        break;
    case vbr_abr:
        ABR_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);
        break;
    case vbr_rh:
        VBR_old_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);
        break;
    case vbr_mt:
    case vbr_mtrh:
        VBR_new_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);
        break;
    }


    /****************************************
    *   Stage 5: bitstream formatting       *
    ****************************************/


    /*  write the frame to the bitstream  */
    (void) format_bitstream(gfc);

    /* copy mp3 bit buffer into array */
    mp3count = copy_buffer(gfc, mp3buf, mp3buf_size, 1);


    if (cfg->write_lame_tag) {
        AddVbrFrame(gfc);
    }

    if (cfg->analysis && gfc->pinfo != NULL) {
        int     framesize = 576 * cfg->mode_gr;
        for (ch = 0; ch < cfg->channels_out; ch++) {
            int     j;
            for (j = 0; j < FFTOFFSET; j++)
                gfc->pinfo->pcmdata[ch][j] = gfc->pinfo->pcmdata[ch][j + framesize];
            for (j = FFTOFFSET; j < 1600; j++) {
                gfc->pinfo->pcmdata[ch][j] = inbuf[ch][j - FFTOFFSET];
            }
        }
        gfc->sv_qnt.masking_lower = 1.0;

        set_frame_pinfo(gfc, masking);
    }

    ++gfc->ov_enc.frame_number;

    updateStats(gfc);

    return mp3count;
}
Initial community commit 2024-09-24 12:54:57 +00:00			`/*`
			`* LAME MP3 encoding engine`
			`*`
			`* Copyright (c) 1999 Mark Taylor`
			`* Copyright (c) 2000-2002 Takehiro Tominaga`
			`* Copyright (c) 2000-2011 Robert Hegemann`
			`* Copyright (c) 2001 Gabriel Bouvigne`
			`* Copyright (c) 2001 John Dahlstrom`
			`*`
			`* This library is free software; you can redistribute it and/or`
			`* modify it under the terms of the GNU Library 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`
			`* Library General Public License for more details.`
			`*`
			`* You should have received a copy of the GNU Library General Public`
			`* License along with this library; if not, write to the`
			`* Free Software Foundation, Inc., 59 Temple Place - Suite 330,`
			`* Boston, MA 02111-1307, USA.`
			`*/`

			`/* $Id: encoder.c,v 1.114 2017/08/26 10:54:57 robert Exp $ */`

			`#ifdef HAVE_CONFIG_H`
			`#include <config.h>`
			`#endif`


			`#include "lame.h"`
			`#include "machine.h"`
			`#include "encoder.h"`
			`#include "util.h"`
			`#include "lame_global_flags.h"`
			`#include "newmdct.h"`
			`#include "psymodel.h"`
			`#include "lame-analysis.h"`
			`#include "bitstream.h"`
			`#include "VbrTag.h"`
			`#include "quantize.h"`
			`#include "quantize_pvt.h"`



			`/*`
			`* auto-adjust of ATH, useful for low volume`
			`* Gabriel Bouvigne 3 feb 2001`
			`*`
			`* modifies some values in`
			`* gfp->internal_flags->ATH`
			`* (gfc->ATH)`
			`*/`
			`static void`
			`adjust_ATH(lame_internal_flags const *const gfc)`
			`{`
			`SessionConfig_t const *const cfg = &gfc->cfg;`
			`FLOAT gr2_max, max_pow;`

			`if (gfc->ATH->use_adjust == 0) {`
			`gfc->ATH->adjust_factor = 1.0; /* no adjustment */`
			`return;`
			`}`

			`/* jd - 2001 mar 12, 27, jun 30 */`
			`/* loudness based on equal loudness curve; */`
			`/* use granule with maximum combined loudness */`
			`max_pow = gfc->ov_psy.loudness_sq[0][0];`
			`gr2_max = gfc->ov_psy.loudness_sq[1][0];`
			`if (cfg->channels_out == 2) {`
			`max_pow += gfc->ov_psy.loudness_sq[0][1];`
			`gr2_max += gfc->ov_psy.loudness_sq[1][1];`
			`}`
			`else {`
			`max_pow += max_pow;`
			`gr2_max += gr2_max;`
			`}`
			`if (cfg->mode_gr == 2) {`
			`max_pow = Max(max_pow, gr2_max);`
			`}`
			`max_pow = 0.5; / max_pow approaches 1.0 for full band noise */`

			`/* jd - 2001 mar 31, jun 30 */`
			`/* user tuning of ATH adjustment region */`
			`max_pow *= gfc->ATH->aa_sensitivity_p;`

			`/* adjust ATH depending on range of maximum value`
			`*/`

			`/* jd - 2001 feb27, mar12,20, jun30, jul22 */`
			`/* continuous curves based on approximation */`
			`/* to GB's original values. */`
			`/* For an increase in approximate loudness, */`
			`/* set ATH adjust to adjust_limit immediately */`
			`/* after a delay of one frame. */`
			`/* For a loudness decrease, reduce ATH adjust */`
			`/* towards adjust_limit gradually. */`
			`/* max_pow is a loudness squared or a power. */`
			`if (max_pow > 0.03125) { /* ((1 - 0.000625)/ 31.98) from curve below */`
			`if (gfc->ATH->adjust_factor >= 1.0) {`
			`gfc->ATH->adjust_factor = 1.0;`
			`}`
			`else {`
			`/* preceding frame has lower ATH adjust; */`
			`/* ascend only to the preceding adjust_limit */`
			`/* in case there is leading low volume */`
			`if (gfc->ATH->adjust_factor < gfc->ATH->adjust_limit) {`
			`gfc->ATH->adjust_factor = gfc->ATH->adjust_limit;`
			`}`
			`}`
			`gfc->ATH->adjust_limit = 1.0;`
			`}`
			`else { /* adjustment curve */`
			`/* about 32 dB maximum adjust (0.000625) */`
			`FLOAT const adj_lim_new = 31.98 * max_pow + 0.000625;`
			`if (gfc->ATH->adjust_factor >= adj_lim_new) { /* descend gradually */`
			`gfc->ATH->adjust_factor = adj_lim_new 0.075 + 0.925;`
			`if (gfc->ATH->adjust_factor < adj_lim_new) { /* stop descent */`
			`gfc->ATH->adjust_factor = adj_lim_new;`
			`}`
			`}`
			`else { /* ascend */`
			`if (gfc->ATH->adjust_limit >= adj_lim_new) {`
			`gfc->ATH->adjust_factor = adj_lim_new;`
			`}`
			`else { /* preceding frame has lower ATH adjust; */`
			`/* ascend only to the preceding adjust_limit */`
			`if (gfc->ATH->adjust_factor < gfc->ATH->adjust_limit) {`
			`gfc->ATH->adjust_factor = gfc->ATH->adjust_limit;`
			`}`
			`}`
			`}`
			`gfc->ATH->adjust_limit = adj_lim_new;`
			`}`
			`}`

			`/***********************************************************************`
			`*`
			`* some simple statistics`
			`*`
			`* bitrate index 0: free bitrate -> not allowed in VBR mode`
			`* : bitrates, kbps depending on MPEG version`
			`* bitrate index 15: forbidden`
			`*`
			`* mode_ext:`
			`* 0: LR`
			`* 1: LR-i`
			`* 2: MS`
			`* 3: MS-i`
			`*`
			`***********************************************************************/`

			`static void`
			`updateStats(lame_internal_flags * const gfc)`
			`{`
			`SessionConfig_t const *const cfg = &gfc->cfg;`
			`EncResult_t *eov = &gfc->ov_enc;`
			`int gr, ch;`
			`assert(0 <= eov->bitrate_index && eov->bitrate_index < 16);`
			`assert(0 <= eov->mode_ext && eov->mode_ext < 4);`

			`/* count bitrate indices */`
			`eov->bitrate_channelmode_hist[eov->bitrate_index][4]++;`
			`eov->bitrate_channelmode_hist[15][4]++;`

			`/* count 'em for every mode extension in case of 2 channel encoding */`
			`if (cfg->channels_out == 2) {`
			`eov->bitrate_channelmode_hist[eov->bitrate_index][eov->mode_ext]++;`
			`eov->bitrate_channelmode_hist[15][eov->mode_ext]++;`
			`}`
			`for (gr = 0; gr < cfg->mode_gr; ++gr) {`
			`for (ch = 0; ch < cfg->channels_out; ++ch) {`
			`int bt = gfc->l3_side.tt[gr][ch].block_type;`
			`if (gfc->l3_side.tt[gr][ch].mixed_block_flag)`
			`bt = 4;`
			`eov->bitrate_blocktype_hist[eov->bitrate_index][bt]++;`
			`eov->bitrate_blocktype_hist[eov->bitrate_index][5]++;`
			`eov->bitrate_blocktype_hist[15][bt]++;`
			`eov->bitrate_blocktype_hist[15][5]++;`
			`}`
			`}`
			`}`




			`static void`
			`lame_encode_frame_init(lame_internal_flags * gfc, const sample_t *const inbuf[2])`
			`{`
			`SessionConfig_t const *const cfg = &gfc->cfg;`

			`int ch, gr;`

			`if (gfc->lame_encode_frame_init == 0) {`
			`sample_t primebuff0[286 + 1152 + 576];`
			`sample_t primebuff1[286 + 1152 + 576];`
			`int const framesize = 576 * cfg->mode_gr;`
			`/* prime the MDCT/polyphase filterbank with a short block */`
			`int i, j;`
			`gfc->lame_encode_frame_init = 1;`
			`memset(primebuff0, 0, sizeof(primebuff0));`
			`memset(primebuff1, 0, sizeof(primebuff1));`
			`for (i = 0, j = 0; i < 286 + 576 * (1 + cfg->mode_gr); ++i) {`
			`if (i < framesize) {`
			`primebuff0[i] = 0;`
			`if (cfg->channels_out == 2)`
			`primebuff1[i] = 0;`
			`}`
			`else {`
			`primebuff0[i] = inbuf[0][j];`
			`if (cfg->channels_out == 2)`
			`primebuff1[i] = inbuf[1][j];`
			`++j;`
			`}`
			`}`
			`/* polyphase filtering / mdct */`
			`for (gr = 0; gr < cfg->mode_gr; gr++) {`
			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`gfc->l3_side.tt[gr][ch].block_type = SHORT_TYPE;`
			`}`
			`}`
			`mdct_sub48(gfc, primebuff0, primebuff1);`

			`/* check FFT will not use a negative starting offset */`
			`#if 576 < FFTOFFSET`
			`# error FFTOFFSET greater than 576: FFT uses a negative offset`
			`#endif`
			`/* check if we have enough data for FFT */`
			`assert(gfc->sv_enc.mf_size >= (BLKSIZE + framesize - FFTOFFSET));`
			`/* check if we have enough data for polyphase filterbank */`
			`assert(gfc->sv_enc.mf_size >= (512 + framesize - 32));`
			`}`

			`}`







			`/************************************************************************`
			`*`
			`* encodeframe() Layer 3`
			`*`
			`* encode a single frame`
			`*`
			`************************************************************************`
			`lame_encode_frame()`


			`gr 0 gr 1`
			`inbuf: \|--------------\|--------------\|--------------\|`


			`Polyphase (18 windows, each shifted 32)`
			`gr 0:`
			`window1 <----512---->`
			`window18 <----512---->`

			`gr 1:`
			`window1 <----512---->`
			`window18 <----512---->`



			`MDCT output: \|--------------\|--------------\|--------------\|`

			`FFT's <---------1024---------->`
			`<---------1024-------->`



			`inbuf = buffer of PCM data size=MP3 framesize`
			`encoder acts on inbuf[ch][0], but output is delayed by MDCTDELAY`
			`so the MDCT coefficints are from inbuf[ch][-MDCTDELAY]`

			`psy-model FFT has a 1 granule delay, so we feed it data for the`
			`next granule.`
			`FFT is centered over granule: 224+576+224`
			`So FFT starts at: 576-224-MDCTDELAY`

			`MPEG2: FFT ends at: BLKSIZE+576-224-MDCTDELAY (1328)`
			`MPEG1: FFT ends at: BLKSIZE+2*576-224-MDCTDELAY (1904)`

			`MPEG2: polyphase first window: [0..511]`
			`18th window: [544..1055] (1056)`
			`MPEG1: 36th window: [1120..1631] (1632)`
			`data needed: 512+framesize-32`

			`A close look newmdct.c shows that the polyphase filterbank`
			`only uses data from [0..510] for each window. Perhaps because the window`
			`used by the filterbank is zero for the last point, so Takehiro's`
			`code doesn't bother to compute with it.`

			`FFT starts at 576-224-MDCTDELAY (304) = 576-FFTOFFSET`

			`*/`

			`typedef FLOAT chgrdata[2][2];`


			`int`
			`lame_encode_mp3_frame( /* Output */`
			`lame_internal_flags * gfc, /* Context */`
			`sample_t const inbuf_l, / Input */`
			`sample_t const inbuf_r, / Input */`
			`unsigned char mp3buf, / Output */`
			`int mp3buf_size)`
			`{ /* Output */`
			`SessionConfig_t const *const cfg = &gfc->cfg;`
			`int mp3count;`
			`III_psy_ratio masking_LR[2][2]; /LR masking & energy /`
			`III_psy_ratio masking_MS[2][2]; /MS masking & energy /`
			`const III_psy_ratio (masking)[2]; /pointer to selected maskings */`
			`const sample_t *inbuf[2];`

			`FLOAT tot_ener[2][4];`
			`FLOAT ms_ener_ratio[2] = { .5, .5 };`
			`FLOAT pe[2][2] = { {0., 0.}, {0., 0.} }, pe_MS[2][2] = { {`
			`0., 0.}, {`
			`0., 0.}};`
			`FLOAT (*pe_use)[2];`

			`int ch, gr;`

			`inbuf[0] = inbuf_l;`
			`inbuf[1] = inbuf_r;`

			`if (gfc->lame_encode_frame_init == 0) {`
			`/first run? /`
			`lame_encode_frame_init(gfc, inbuf);`

			`}`


			`/******************** padding ***************************/`
			`/* padding method as described in`
			`* "MPEG-Layer3 / Bitstream Syntax and Decoding"`
			`* by Martin Sieler, Ralph Sperschneider`
			`*`
			`* note: there is no padding for the very first frame`
			`*`
			`* Robert Hegemann 2000-06-22`
			`*/`
			`gfc->ov_enc.padding = FALSE;`
			`if ((gfc->sv_enc.slot_lag -= gfc->sv_enc.frac_SpF) < 0) {`
			`gfc->sv_enc.slot_lag += cfg->samplerate_out;`
			`gfc->ov_enc.padding = TRUE;`
			`}`



			`/****************************************`
			`* Stage 1: psychoacoustic model *`
			`****************************************/`

			`{`
			`/* psychoacoustic model`
			`* psy model has a 1 granule (576) delay that we must compensate for`
			`* (mt 6/99).`
			`*/`
			`int ret;`
			`const sample_t bufp[2] = {0, 0}; / address of beginning of left & right granule */`
			`int blocktype[2];`

			`for (gr = 0; gr < cfg->mode_gr; gr++) {`

			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`bufp[ch] = &inbuf[ch][576 + gr * 576 - FFTOFFSET];`
			`}`
			`ret = L3psycho_anal_vbr(gfc, bufp, gr,`
			`masking_LR, masking_MS,`
			`pe[gr], pe_MS[gr], tot_ener[gr], blocktype);`
			`if (ret != 0)`
			`return -4;`

			`if (cfg->mode == JOINT_STEREO) {`
			`ms_ener_ratio[gr] = tot_ener[gr][2] + tot_ener[gr][3];`
			`if (ms_ener_ratio[gr] > 0)`
			`ms_ener_ratio[gr] = tot_ener[gr][3] / ms_ener_ratio[gr];`
			`}`

			`/* block type flags */`
			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`gr_info *const cod_info = &gfc->l3_side.tt[gr][ch];`
			`cod_info->block_type = blocktype[ch];`
			`cod_info->mixed_block_flag = 0;`
			`}`
			`}`
			`}`


			`/* auto-adjust of ATH, useful for low volume */`
			`adjust_ATH(gfc);`


			`/****************************************`
			`* Stage 2: MDCT *`
			`****************************************/`

			`/* polyphase filtering / mdct */`
			`mdct_sub48(gfc, inbuf[0], inbuf[1]);`


			`/****************************************`
			`* Stage 3: MS/LR decision *`
			`****************************************/`

			`/* Here will be selected MS or LR coding of the 2 stereo channels */`
			`gfc->ov_enc.mode_ext = MPG_MD_LR_LR;`

			`if (cfg->force_ms) {`
			`gfc->ov_enc.mode_ext = MPG_MD_MS_LR;`
			`}`
			`else if (cfg->mode == JOINT_STEREO) {`
			`/* ms_ratio = is scaled, for historical reasons, to look like`
			`a ratio of side_channel / total.`
			`0 = signal is 100% mono`
			`.5 = L & R uncorrelated`
			`*/`

			`/* [0] and [1] are the results for the two granules in MPEG-1,`
			`* in MPEG-2 it's only a faked averaging of the same value`
			`* _prev is the value of the last granule of the previous frame`
			`* _next is the value of the first granule of the next frame`
			`*/`

			`FLOAT sum_pe_MS = 0;`
			`FLOAT sum_pe_LR = 0;`
			`for (gr = 0; gr < cfg->mode_gr; gr++) {`
			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`sum_pe_MS += pe_MS[gr][ch];`
			`sum_pe_LR += pe[gr][ch];`
			`}`
			`}`

			`/* based on PE: M/S coding would not use much more bits than L/R */`
			`if (sum_pe_MS <= 1.00 * sum_pe_LR) {`

			`gr_info const *const gi0 = &gfc->l3_side.tt[0][0];`
			`gr_info const *const gi1 = &gfc->l3_side.tt[cfg->mode_gr - 1][0];`

			`if (gi0[0].block_type == gi0[1].block_type && gi1[0].block_type == gi1[1].block_type) {`

			`gfc->ov_enc.mode_ext = MPG_MD_MS_LR;`
			`}`
			`}`
			`}`

			`/* bit and noise allocation */`
			`if (gfc->ov_enc.mode_ext == MPG_MD_MS_LR) {`
			`masking = (const III_psy_ratio ()[2])masking_MS; / use MS masking */`
			`pe_use = pe_MS;`
			`}`
			`else {`
			`masking = (const III_psy_ratio ()[2])masking_LR; / use LR masking */`
			`pe_use = pe;`
			`}`


			`/* copy data for MP3 frame analyzer */`
			`if (cfg->analysis && gfc->pinfo != NULL) {`
			`for (gr = 0; gr < cfg->mode_gr; gr++) {`
			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`gfc->pinfo->ms_ratio[gr] = 0;`
			`gfc->pinfo->ms_ener_ratio[gr] = ms_ener_ratio[gr];`
			`gfc->pinfo->blocktype[gr][ch] = gfc->l3_side.tt[gr][ch].block_type;`
			`gfc->pinfo->pe[gr][ch] = pe_use[gr][ch];`
			`memcpy(gfc->pinfo->xr[gr][ch], &gfc->l3_side.tt[gr][ch].xr[0], sizeof(FLOAT) * 576);`
			`/* in psymodel, LR and MS data was stored in pinfo.`
			`switch to MS data: */`
			`if (gfc->ov_enc.mode_ext == MPG_MD_MS_LR) {`
			`gfc->pinfo->ers[gr][ch] = gfc->pinfo->ers[gr][ch + 2];`
			`memcpy(gfc->pinfo->energy[gr][ch], gfc->pinfo->energy[gr][ch + 2],`
			`sizeof(gfc->pinfo->energy[gr][ch]));`
			`}`
			`}`
			`}`
			`}`


			`/****************************************`
			`* Stage 4: quantization loop *`
			`****************************************/`

			`if (cfg->vbr == vbr_off \|\| cfg->vbr == vbr_abr) {`
			`static FLOAT const fircoef[9] = {`
			`-0.0207887 * 5, -0.0378413 * 5, -0.0432472 * 5, -0.031183 * 5,`
			`7.79609e-18 * 5, 0.0467745 * 5, 0.10091 * 5, 0.151365 * 5,`
			`0.187098 * 5`
			`};`

			`int i;`
			`FLOAT f;`

			`for (i = 0; i < 18; i++)`
			`gfc->sv_enc.pefirbuf[i] = gfc->sv_enc.pefirbuf[i + 1];`

			`f = 0.0;`
			`for (gr = 0; gr < cfg->mode_gr; gr++)`
			`for (ch = 0; ch < cfg->channels_out; ch++)`
			`f += pe_use[gr][ch];`
			`gfc->sv_enc.pefirbuf[18] = f;`

			`f = gfc->sv_enc.pefirbuf[9];`
			`for (i = 0; i < 9; i++)`
			`f += (gfc->sv_enc.pefirbuf[i] + gfc->sv_enc.pefirbuf[18 - i]) * fircoef[i];`

			`f = (670 * 5 * cfg->mode_gr * cfg->channels_out) / f;`
			`for (gr = 0; gr < cfg->mode_gr; gr++) {`
			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`pe_use[gr][ch] *= f;`
			`}`
			`}`
			`}`
			`switch (cfg->vbr)`
			`{`
			`default:`
			`case vbr_off:`
			`CBR_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);`
			`break;`
			`case vbr_abr:`
			`ABR_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);`
			`break;`
			`case vbr_rh:`
			`VBR_old_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);`
			`break;`
			`case vbr_mt:`
			`case vbr_mtrh:`
			`VBR_new_iteration_loop(gfc, (const FLOAT (*)[2])pe_use, ms_ener_ratio, masking);`
			`break;`
			`}`


			`/****************************************`
			`* Stage 5: bitstream formatting *`
			`****************************************/`


			`/* write the frame to the bitstream */`
			`(void) format_bitstream(gfc);`

			`/* copy mp3 bit buffer into array */`
			`mp3count = copy_buffer(gfc, mp3buf, mp3buf_size, 1);`


			`if (cfg->write_lame_tag) {`
			`AddVbrFrame(gfc);`
			`}`

			`if (cfg->analysis && gfc->pinfo != NULL) {`
			`int framesize = 576 * cfg->mode_gr;`
			`for (ch = 0; ch < cfg->channels_out; ch++) {`
			`int j;`
			`for (j = 0; j < FFTOFFSET; j++)`
			`gfc->pinfo->pcmdata[ch][j] = gfc->pinfo->pcmdata[ch][j + framesize];`
			`for (j = FFTOFFSET; j < 1600; j++) {`
			`gfc->pinfo->pcmdata[ch][j] = inbuf[ch][j - FFTOFFSET];`
			`}`
			`}`
			`gfc->sv_qnt.masking_lower = 1.0;`

			`set_frame_pinfo(gfc, masking);`
			`}`

			`++gfc->ov_enc.frame_number;`

			`updateStats(gfc);`

			`return mp3count;`
			`}`