3rdparty/liba52/downmix.c

/*
 * downmix.c
 * Copyright (C) 2000-2002 Michel Lespinasse <walken@zoy.org>
 * Copyright (C) 1999-2000 Aaron Holtzman <aholtzma@ess.engr.uvic.ca>
 *
 * This file is part of a52dec, a free ATSC A-52 stream decoder.
 * See http://liba52.sourceforge.net/ for updates.
 *
 * a52dec is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * a52dec 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 General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 */
#pragma warning(disable:4244)
#include "config.h"

#include <string.h>
#include "inttypes.h"

#include "a52.h"
#include "a52_internal.h"

#define CONVERT(acmod,output) (((output) << 3) + (acmod))

int a52_downmix_init (int input, int flags, sample_t * level,
                      sample_t clev, sample_t slev)
{
    static uint8_t table[11][8] = {
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_STEREO,
         A52_STEREO,    A52_STEREO,     A52_STEREO,     A52_STEREO},
        {A52_MONO,      A52_MONO,       A52_MONO,       A52_MONO,
         A52_MONO,      A52_MONO,       A52_MONO,       A52_MONO},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_STEREO,
         A52_STEREO,    A52_STEREO,     A52_STEREO,     A52_STEREO},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_3F,
         A52_STEREO,    A52_3F,         A52_STEREO,     A52_3F},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_STEREO,
         A52_2F1R,      A52_2F1R,       A52_2F1R,       A52_2F1R},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_STEREO,
         A52_2F1R,      A52_3F1R,       A52_2F1R,       A52_3F1R},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_3F,
         A52_2F2R,      A52_2F2R,       A52_2F2R,       A52_2F2R},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_3F,
         A52_2F2R,      A52_3F2R,       A52_2F2R,       A52_3F2R},
        {A52_CHANNEL1,  A52_MONO,       A52_MONO,       A52_MONO,
         A52_MONO,      A52_MONO,       A52_MONO,       A52_MONO},
        {A52_CHANNEL2,  A52_MONO,       A52_MONO,       A52_MONO,
         A52_MONO,      A52_MONO,       A52_MONO,       A52_MONO},
        {A52_CHANNEL,   A52_DOLBY,      A52_STEREO,     A52_DOLBY,
         A52_DOLBY,     A52_DOLBY,      A52_DOLBY,      A52_DOLBY}
    };
    int output;

    output = flags & A52_CHANNEL_MASK;
    if (output > A52_DOLBY)
        return -1;

    output = table[output][input & 7];

    if ((output == A52_STEREO) &&
        ((input == A52_DOLBY) || ((input == A52_3F) && (clev == LEVEL_3DB))))
        output = A52_DOLBY;

    if (flags & A52_ADJUST_LEVEL)
        switch (CONVERT (input & 7, output)) {

        case CONVERT (A52_3F, A52_MONO):
            *level *= LEVEL_3DB / (1 + clev);
            break;

        case CONVERT (A52_STEREO, A52_MONO):
        case CONVERT (A52_2F2R, A52_2F1R):
        case CONVERT (A52_3F2R, A52_3F1R):
        level_3db:
            *level *= LEVEL_3DB;
            break;

        case CONVERT (A52_3F2R, A52_2F1R):
            if (clev < LEVEL_PLUS3DB - 1)
                goto level_3db;
            /* break thru */
        case CONVERT (A52_3F, A52_STEREO):
        case CONVERT (A52_3F1R, A52_2F1R):
        case CONVERT (A52_3F1R, A52_2F2R):
        case CONVERT (A52_3F2R, A52_2F2R):
            *level /= 1 + clev;
            break;

        case CONVERT (A52_2F1R, A52_MONO):
            *level *= LEVEL_PLUS3DB / (2 + slev);
            break;

        case CONVERT (A52_2F1R, A52_STEREO):
        case CONVERT (A52_3F1R, A52_3F):
            *level /= 1 + slev * LEVEL_3DB;
            break;

        case CONVERT (A52_3F1R, A52_MONO):
            *level *= LEVEL_3DB / (1 + clev + 0.5 * slev);
            break;

        case CONVERT (A52_3F1R, A52_STEREO):
            *level /= 1 + clev + slev * LEVEL_3DB;
            break;

        case CONVERT (A52_2F2R, A52_MONO):
            *level *= LEVEL_3DB / (1 + slev);
            break;

        case CONVERT (A52_2F2R, A52_STEREO):
        case CONVERT (A52_3F2R, A52_3F):
            *level /= 1 + slev;
            break;

        case CONVERT (A52_3F2R, A52_MONO):
            *level *= LEVEL_3DB / (1 + clev + slev);
            break;

        case CONVERT (A52_3F2R, A52_STEREO):
            *level /= 1 + clev + slev;
            break;

        case CONVERT (A52_MONO, A52_DOLBY):
            *level *= LEVEL_PLUS3DB;
            break;

        case CONVERT (A52_3F, A52_DOLBY):
        case CONVERT (A52_2F1R, A52_DOLBY):
            *level *= 1 / (1 + LEVEL_3DB);
            break;

        case CONVERT (A52_3F1R, A52_DOLBY):
        case CONVERT (A52_2F2R, A52_DOLBY):
            *level *= 1 / (1 + 2 * LEVEL_3DB);
            break;

        case CONVERT (A52_3F2R, A52_DOLBY):
            *level *= 1 / (1 + 3 * LEVEL_3DB);
            break;
        }

    return output;
}

int a52_downmix_coeff (sample_t * coeff, int acmod, int output, sample_t level,
                       sample_t clev, sample_t slev)
{
    switch (CONVERT (acmod, output & A52_CHANNEL_MASK)) {

    case CONVERT (A52_CHANNEL, A52_CHANNEL):
    case CONVERT (A52_MONO, A52_MONO):
    case CONVERT (A52_STEREO, A52_STEREO):
    case CONVERT (A52_3F, A52_3F):
    case CONVERT (A52_2F1R, A52_2F1R):
    case CONVERT (A52_3F1R, A52_3F1R):
    case CONVERT (A52_2F2R, A52_2F2R):
    case CONVERT (A52_3F2R, A52_3F2R):
    case CONVERT (A52_STEREO, A52_DOLBY):
        coeff[0] = coeff[1] = coeff[2] = coeff[3] = coeff[4] = level;
        return 0;

    case CONVERT (A52_CHANNEL, A52_MONO):
        coeff[0] = coeff[1] = level * LEVEL_6DB;
        return 3;

    case CONVERT (A52_STEREO, A52_MONO):
        coeff[0] = coeff[1] = level * LEVEL_3DB;
        return 3;

    case CONVERT (A52_3F, A52_MONO):
        coeff[0] = coeff[2] = level * LEVEL_3DB;
        coeff[1] = level * clev * LEVEL_PLUS3DB;
        return 7;

    case CONVERT (A52_2F1R, A52_MONO):
        coeff[0] = coeff[1] = level * LEVEL_3DB;
        coeff[2] = level * slev * LEVEL_3DB;
        return 7;

    case CONVERT (A52_2F2R, A52_MONO):
        coeff[0] = coeff[1] = level * LEVEL_3DB;
        coeff[2] = coeff[3] = level * slev * LEVEL_3DB;
        return 15;

    case CONVERT (A52_3F1R, A52_MONO):
        coeff[0] = coeff[2] = level * LEVEL_3DB;
        coeff[1] = level * clev * LEVEL_PLUS3DB;
        coeff[3] = level * slev * LEVEL_3DB;
        return 15;

    case CONVERT (A52_3F2R, A52_MONO):
        coeff[0] = coeff[2] = level * LEVEL_3DB;
        coeff[1] = level * clev * LEVEL_PLUS3DB;
        coeff[3] = coeff[4] = level * slev * LEVEL_3DB;
        return 31;

    case CONVERT (A52_MONO, A52_DOLBY):
        coeff[0] = level * LEVEL_3DB;
        return 0;

    case CONVERT (A52_3F, A52_DOLBY):
        clev = LEVEL_3DB;
    case CONVERT (A52_3F, A52_STEREO):
    case CONVERT (A52_3F1R, A52_2F1R):
    case CONVERT (A52_3F2R, A52_2F2R):
        coeff[0] = coeff[2] = coeff[3] = coeff[4] = level;
        coeff[1] = level * clev;
        return 7;

    case CONVERT (A52_2F1R, A52_DOLBY):
        slev = 1;
    case CONVERT (A52_2F1R, A52_STEREO):
        coeff[0] = coeff[1] = level;
        coeff[2] = level * slev * LEVEL_3DB;
        return 7;

    case CONVERT (A52_3F1R, A52_DOLBY):
        clev = LEVEL_3DB;
        slev = 1;
    case CONVERT (A52_3F1R, A52_STEREO):
        coeff[0] = coeff[2] = level;
        coeff[1] = level * clev;
        coeff[3] = level * slev * LEVEL_3DB;
        return 15;

    case CONVERT (A52_2F2R, A52_DOLBY):
        slev = LEVEL_3DB;
    case CONVERT (A52_2F2R, A52_STEREO):
        coeff[0] = coeff[1] = level;
        coeff[2] = coeff[3] = level * slev;
        return 15;

    case CONVERT (A52_3F2R, A52_DOLBY):
        clev = LEVEL_3DB;
    case CONVERT (A52_3F2R, A52_2F1R):
        slev = LEVEL_3DB;
    case CONVERT (A52_3F2R, A52_STEREO):
        coeff[0] = coeff[2] = level;
        coeff[1] = level * clev;
        coeff[3] = coeff[4] = level * slev;
        return 31;

    case CONVERT (A52_3F1R, A52_3F):
        coeff[0] = coeff[1] = coeff[2] = level;
        coeff[3] = level * slev * LEVEL_3DB;
        return 13;

    case CONVERT (A52_3F2R, A52_3F):
        coeff[0] = coeff[1] = coeff[2] = level;
        coeff[3] = coeff[4] = level * slev;
        return 29;

    case CONVERT (A52_2F2R, A52_2F1R):
        coeff[0] = coeff[1] = level;
        coeff[2] = coeff[3] = level * LEVEL_3DB;
        return 12;

    case CONVERT (A52_3F2R, A52_3F1R):
        coeff[0] = coeff[1] = coeff[2] = level;
        coeff[3] = coeff[4] = level * LEVEL_3DB;
        return 24;

    case CONVERT (A52_2F1R, A52_2F2R):
        coeff[0] = coeff[1] = level;
        coeff[2] = level * LEVEL_3DB;
        return 0;

    case CONVERT (A52_3F1R, A52_2F2R):
        coeff[0] = coeff[2] = level;
        coeff[1] = level * clev;
        coeff[3] = level * LEVEL_3DB;
        return 7;

    case CONVERT (A52_3F1R, A52_3F2R):
        coeff[0] = coeff[1] = coeff[2] = level;
        coeff[3] = level * LEVEL_3DB;
        return 0;

    case CONVERT (A52_CHANNEL, A52_CHANNEL1):
        coeff[0] = level;
        coeff[1] = 0;
        return 0;

    case CONVERT (A52_CHANNEL, A52_CHANNEL2):
        coeff[0] = 0;
        coeff[1] = level;
        return 0;
    }

    return -1;  /* NOTREACHED */
}

static void mix2to1 (sample_t * dest, sample_t * src, sample_t bias)
{
    int i;

    for (i = 0; i < 256; i++)
        dest[i] += src[i] + bias;
}

static void mix3to1 (sample_t * samples, sample_t bias)
{
    int i;

    for (i = 0; i < 256; i++)
        samples[i] += samples[i + 256] + samples[i + 512] + bias;
}

static void mix4to1 (sample_t * samples, sample_t bias)
{
    int i;

    for (i = 0; i < 256; i++)
        samples[i] += (samples[i + 256] + samples[i + 512] +
                       samples[i + 768] + bias);
}

static void mix5to1 (sample_t * samples, sample_t bias)
{
    int i;

    for (i = 0; i < 256; i++)
        samples[i] += (samples[i + 256] + samples[i + 512] +
                       samples[i + 768] + samples[i + 1024] + bias);
}

static void mix3to2 (sample_t * samples, sample_t bias)
{
    int i;
    sample_t common;

    for (i = 0; i < 256; i++) {
        common = samples[i + 256] + bias;
        samples[i] += common;
        samples[i + 256] = samples[i + 512] + common;
    }
}

static void mix21to2 (sample_t * left, sample_t * right, sample_t bias)
{
    int i;
    sample_t common;

    for (i = 0; i < 256; i++) {
        common = right[i + 256] + bias;
        left[i] += common;
        right[i] += common;
    }
}

static void mix21toS (sample_t * samples, sample_t bias)
{
    int i;
    sample_t surround;

    for (i = 0; i < 256; i++) {
        surround = samples[i + 512];
        samples[i] += bias - surround;
        samples[i + 256] += bias + surround;
    }
}

static void mix31to2 (sample_t * samples, sample_t bias)
{
    int i;
    sample_t common;

    for (i = 0; i < 256; i++) {
        common = samples[i + 256] + samples[i + 768] + bias;
        samples[i] += common;
        samples[i + 256] = samples[i + 512] + common;
    }
}

static void mix31toS (sample_t * samples, sample_t bias)
{
    int i;
    sample_t common, surround;

    for (i = 0; i < 256; i++) {
        common = samples[i + 256] + bias;
        surround = samples[i + 768];
        samples[i] += common - surround;
        samples[i + 256] = samples[i + 512] + common + surround;
    }
}

static void mix22toS (sample_t * samples, sample_t bias)
{
    int i;
    sample_t surround;

    for (i = 0; i < 256; i++) {
        surround = samples[i + 512] + samples[i + 768];
        samples[i] += bias - surround;
        samples[i + 256] += bias + surround;
    }
}

static void mix32to2 (sample_t * samples, sample_t bias)
{
    int i;
    sample_t common;

    for (i = 0; i < 256; i++) {
        common = samples[i + 256] + bias;
        samples[i] += common + samples[i + 768];
        samples[i + 256] = common + samples[i + 512] + samples[i + 1024];
    }
}

static void mix32toS (sample_t * samples, sample_t bias)
{
    int i;
    sample_t common, surround;

    for (i = 0; i < 256; i++) {
        common = samples[i + 256] + bias;
        surround = samples[i + 768] + samples[i + 1024];
        samples[i] += common - surround;
        samples[i + 256] = samples[i + 512] + common + surround;
    }
}

static void move2to1 (sample_t * src, sample_t * dest, sample_t bias)
{
    int i;

    for (i = 0; i < 256; i++)
        dest[i] = src[i] + src[i + 256] + bias;
}

static void zero (sample_t * samples)
{
    int i;

    for (i = 0; i < 256; i++)
        samples[i] = 0;
}

void a52_downmix (sample_t * samples, int acmod, int output, sample_t bias,
                  sample_t clev, sample_t slev)
{
    switch (CONVERT (acmod, output & A52_CHANNEL_MASK)) {

    case CONVERT (A52_CHANNEL, A52_CHANNEL2):
        memcpy (samples, samples + 256, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_CHANNEL, A52_MONO):
    case CONVERT (A52_STEREO, A52_MONO):
    mix_2to1:
        mix2to1 (samples, samples + 256, bias);
        break;

    case CONVERT (A52_2F1R, A52_MONO):
        if (slev == 0)
            goto mix_2to1;
    case CONVERT (A52_3F, A52_MONO):
    mix_3to1:
        mix3to1 (samples, bias);
        break;

    case CONVERT (A52_3F1R, A52_MONO):
        if (slev == 0)
            goto mix_3to1;
    case CONVERT (A52_2F2R, A52_MONO):
        if (slev == 0)
            goto mix_2to1;
        mix4to1 (samples, bias);
        break;

    case CONVERT (A52_3F2R, A52_MONO):
        if (slev == 0)
            goto mix_3to1;
        mix5to1 (samples, bias);
        break;

    case CONVERT (A52_MONO, A52_DOLBY):
        memcpy (samples + 256, samples, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_3F, A52_STEREO):
    case CONVERT (A52_3F, A52_DOLBY):
    mix_3to2:
        mix3to2 (samples, bias);
        break;

    case CONVERT (A52_2F1R, A52_STEREO):
        if (slev == 0)
            break;
        mix21to2 (samples, samples + 256, bias);
        break;

    case CONVERT (A52_2F1R, A52_DOLBY):
        mix21toS (samples, bias);
        break;

    case CONVERT (A52_3F1R, A52_STEREO):
        if (slev == 0)
            goto mix_3to2;
        mix31to2 (samples, bias);
        break;

    case CONVERT (A52_3F1R, A52_DOLBY):
        mix31toS (samples, bias);
        break;

    case CONVERT (A52_2F2R, A52_STEREO):
        if (slev == 0)
            break;
        mix2to1 (samples, samples + 512, bias);
        mix2to1 (samples + 256, samples + 768, bias);
        break;

    case CONVERT (A52_2F2R, A52_DOLBY):
        mix22toS (samples, bias);
        break;

    case CONVERT (A52_3F2R, A52_STEREO):
        if (slev == 0)
            goto mix_3to2;
        mix32to2 (samples, bias);
        break;

    case CONVERT (A52_3F2R, A52_DOLBY):
        mix32toS (samples, bias);
        break;

    case CONVERT (A52_3F1R, A52_3F):
        if (slev == 0)
            break;
        mix21to2 (samples, samples + 512, bias);
        break;

    case CONVERT (A52_3F2R, A52_3F):
        if (slev == 0)
            break;
        mix2to1 (samples, samples + 768, bias);
        mix2to1 (samples + 512, samples + 1024, bias);
        break;

    case CONVERT (A52_3F1R, A52_2F1R):
        mix3to2 (samples, bias);
        memcpy (samples + 512, samples + 768, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_2F2R, A52_2F1R):
        mix2to1 (samples + 512, samples + 768, bias);
        break;

    case CONVERT (A52_3F2R, A52_2F1R):
        mix3to2 (samples, bias);
        move2to1 (samples + 768, samples + 512, bias);
        break;

    case CONVERT (A52_3F2R, A52_3F1R):
        mix2to1 (samples + 768, samples + 1024, bias);
        break;

    case CONVERT (A52_2F1R, A52_2F2R):
        memcpy (samples + 768, samples + 512, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_3F1R, A52_2F2R):
        mix3to2 (samples, bias);
        memcpy (samples + 512, samples + 768, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_3F2R, A52_2F2R):
        mix3to2 (samples, bias);
        memcpy (samples + 512, samples + 768, 256 * sizeof (sample_t));
        memcpy (samples + 768, samples + 1024, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_3F1R, A52_3F2R):
        memcpy (samples + 1027, samples + 768, 256 * sizeof (sample_t));
        break;
    }
}

void a52_upmix (sample_t * samples, int acmod, int output)
{
    switch (CONVERT (acmod, output & A52_CHANNEL_MASK)) {

    case CONVERT (A52_CHANNEL, A52_CHANNEL2):
        memcpy (samples + 256, samples, 256 * sizeof (sample_t));
        break;

    case CONVERT (A52_3F2R, A52_MONO):
        zero (samples + 1024);
    case CONVERT (A52_3F1R, A52_MONO):
    case CONVERT (A52_2F2R, A52_MONO):
        zero (samples + 768);
    case CONVERT (A52_3F, A52_MONO):
    case CONVERT (A52_2F1R, A52_MONO):
        zero (samples + 512);
    case CONVERT (A52_CHANNEL, A52_MONO):
    case CONVERT (A52_STEREO, A52_MONO):
        zero (samples + 256);
        break;

    case CONVERT (A52_3F2R, A52_STEREO):
    case CONVERT (A52_3F2R, A52_DOLBY):
        zero (samples + 1024);
    case CONVERT (A52_3F1R, A52_STEREO):
    case CONVERT (A52_3F1R, A52_DOLBY):
        zero (samples + 768);
    case CONVERT (A52_3F, A52_STEREO):
    case CONVERT (A52_3F, A52_DOLBY):
    mix_3to2:
        memcpy (samples + 512, samples + 256, 256 * sizeof (sample_t));
        zero (samples + 256);
        break;

    case CONVERT (A52_2F2R, A52_STEREO):
    case CONVERT (A52_2F2R, A52_DOLBY):
        zero (samples + 768);
    case CONVERT (A52_2F1R, A52_STEREO):
    case CONVERT (A52_2F1R, A52_DOLBY):
        zero (samples + 512);
        break;

    case CONVERT (A52_3F2R, A52_3F):
        zero (samples + 1024);
    case CONVERT (A52_3F1R, A52_3F):
    case CONVERT (A52_2F2R, A52_2F1R):
        zero (samples + 768);
        break;

    case CONVERT (A52_3F2R, A52_3F1R):
        zero (samples + 1024);
        break;

    case CONVERT (A52_3F2R, A52_2F1R):
        zero (samples + 1024);
    case CONVERT (A52_3F1R, A52_2F1R):
    mix_31to21:
        memcpy (samples + 768, samples + 512, 256 * sizeof (sample_t));
        goto mix_3to2;

    case CONVERT (A52_3F2R, A52_2F2R):
        memcpy (samples + 1024, samples + 768, 256 * sizeof (sample_t));
        goto mix_31to21;
    }
}
1	/*
2	* downmix.c
3	* Copyright (C) 2000-2002 Michel Lespinasse <walken@zoy.org>
4	* Copyright (C) 1999-2000 Aaron Holtzman <aholtzma@ess.engr.uvic.ca>
5	*
6	* This file is part of a52dec, a free ATSC A-52 stream decoder.
7	* See http://liba52.sourceforge.net/ for updates.
8	*
9	* a52dec is free software; you can redistribute it and/or modify
10	* it under the terms of the GNU General Public License as published by
11	* the Free Software Foundation; either version 2 of the License, or
12	* (at your option) any later version.
13	*
14	* a52dec is distributed in the hope that it will be useful,
15	* but WITHOUT ANY WARRANTY; without even the implied warranty of
16	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17	* GNU General Public License for more details.
18	*
19	* You should have received a copy of the GNU General Public License
20	* along with this program; if not, write to the Free Software
21	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
22	*/
23	#pragma warning(disable:4244)
24	#include "config.h"
25
26	#include <string.h>
27	#include "inttypes.h"
28
29	#include "a52.h"
30	#include "a52_internal.h"
31
32	#define CONVERT(acmod,output) (((output) << 3) + (acmod))
33
34	int a52_downmix_init (int input, int flags, sample_t * level,
35	sample_t clev, sample_t slev)
36	{
37	static uint8_t table[11][8] = {
38	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_STEREO,
39	A52_STEREO, A52_STEREO, A52_STEREO, A52_STEREO},
40	{A52_MONO, A52_MONO, A52_MONO, A52_MONO,
41	A52_MONO, A52_MONO, A52_MONO, A52_MONO},
42	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_STEREO,
43	A52_STEREO, A52_STEREO, A52_STEREO, A52_STEREO},
44	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_3F,
45	A52_STEREO, A52_3F, A52_STEREO, A52_3F},
46	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_STEREO,
47	A52_2F1R, A52_2F1R, A52_2F1R, A52_2F1R},
48	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_STEREO,
49	A52_2F1R, A52_3F1R, A52_2F1R, A52_3F1R},
50	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_3F,
51	A52_2F2R, A52_2F2R, A52_2F2R, A52_2F2R},
52	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_3F,
53	A52_2F2R, A52_3F2R, A52_2F2R, A52_3F2R},
54	{A52_CHANNEL1, A52_MONO, A52_MONO, A52_MONO,
55	A52_MONO, A52_MONO, A52_MONO, A52_MONO},
56	{A52_CHANNEL2, A52_MONO, A52_MONO, A52_MONO,
57	A52_MONO, A52_MONO, A52_MONO, A52_MONO},
58	{A52_CHANNEL, A52_DOLBY, A52_STEREO, A52_DOLBY,
59	A52_DOLBY, A52_DOLBY, A52_DOLBY, A52_DOLBY}
60	};
61	int output;
62
63	output = flags & A52_CHANNEL_MASK;
64	if (output > A52_DOLBY)
65	return -1;
66
67	output = table[output][input & 7];
68
69	if ((output == A52_STEREO) &&
70	((input == A52_DOLBY) \|\| ((input == A52_3F) && (clev == LEVEL_3DB))))
71	output = A52_DOLBY;
72
73	if (flags & A52_ADJUST_LEVEL)
74	switch (CONVERT (input & 7, output)) {
75
76	case CONVERT (A52_3F, A52_MONO):
77	level = LEVEL_3DB / (1 + clev);
78	break;
79
80	case CONVERT (A52_STEREO, A52_MONO):
81	case CONVERT (A52_2F2R, A52_2F1R):
82	case CONVERT (A52_3F2R, A52_3F1R):
83	level_3db:
84	level = LEVEL_3DB;
85	break;
86
87	case CONVERT (A52_3F2R, A52_2F1R):
88	if (clev < LEVEL_PLUS3DB - 1)
89	goto level_3db;
90	/* break thru */
91	case CONVERT (A52_3F, A52_STEREO):
92	case CONVERT (A52_3F1R, A52_2F1R):
93	case CONVERT (A52_3F1R, A52_2F2R):
94	case CONVERT (A52_3F2R, A52_2F2R):
95	*level /= 1 + clev;
96	break;
97
98	case CONVERT (A52_2F1R, A52_MONO):
99	level = LEVEL_PLUS3DB / (2 + slev);
100	break;
101
102	case CONVERT (A52_2F1R, A52_STEREO):
103	case CONVERT (A52_3F1R, A52_3F):
104	level /= 1 + slev LEVEL_3DB;
105	break;
106
107	case CONVERT (A52_3F1R, A52_MONO):
108	level = LEVEL_3DB / (1 + clev + 0.5 * slev);
109	break;
110
111	case CONVERT (A52_3F1R, A52_STEREO):
112	level /= 1 + clev + slev LEVEL_3DB;
113	break;
114
115	case CONVERT (A52_2F2R, A52_MONO):
116	level = LEVEL_3DB / (1 + slev);
117	break;
118
119	case CONVERT (A52_2F2R, A52_STEREO):
120	case CONVERT (A52_3F2R, A52_3F):
121	*level /= 1 + slev;
122	break;
123
124	case CONVERT (A52_3F2R, A52_MONO):
125	level = LEVEL_3DB / (1 + clev + slev);
126	break;
127
128	case CONVERT (A52_3F2R, A52_STEREO):
129	*level /= 1 + clev + slev;
130	break;
131
132	case CONVERT (A52_MONO, A52_DOLBY):
133	level = LEVEL_PLUS3DB;
134	break;
135
136	case CONVERT (A52_3F, A52_DOLBY):
137	case CONVERT (A52_2F1R, A52_DOLBY):
138	level = 1 / (1 + LEVEL_3DB);
139	break;
140
141	case CONVERT (A52_3F1R, A52_DOLBY):
142	case CONVERT (A52_2F2R, A52_DOLBY):
143	level = 1 / (1 + 2 * LEVEL_3DB);
144	break;
145
146	case CONVERT (A52_3F2R, A52_DOLBY):
147	level = 1 / (1 + 3 * LEVEL_3DB);
148	break;
149	}
150
151	return output;
152	}
153
154	int a52_downmix_coeff (sample_t * coeff, int acmod, int output, sample_t level,
155	sample_t clev, sample_t slev)
156	{
157	switch (CONVERT (acmod, output & A52_CHANNEL_MASK)) {
158
159	case CONVERT (A52_CHANNEL, A52_CHANNEL):
160	case CONVERT (A52_MONO, A52_MONO):
161	case CONVERT (A52_STEREO, A52_STEREO):
162	case CONVERT (A52_3F, A52_3F):
163	case CONVERT (A52_2F1R, A52_2F1R):
164	case CONVERT (A52_3F1R, A52_3F1R):
165	case CONVERT (A52_2F2R, A52_2F2R):
166	case CONVERT (A52_3F2R, A52_3F2R):
167	case CONVERT (A52_STEREO, A52_DOLBY):
168	coeff[0] = coeff[1] = coeff[2] = coeff[3] = coeff[4] = level;
169	return 0;
170
171	case CONVERT (A52_CHANNEL, A52_MONO):
172	coeff[0] = coeff[1] = level * LEVEL_6DB;
173	return 3;
174
175	case CONVERT (A52_STEREO, A52_MONO):
176	coeff[0] = coeff[1] = level * LEVEL_3DB;
177	return 3;
178
179	case CONVERT (A52_3F, A52_MONO):
180	coeff[0] = coeff[2] = level * LEVEL_3DB;
181	coeff[1] = level * clev * LEVEL_PLUS3DB;
182	return 7;
183
184	case CONVERT (A52_2F1R, A52_MONO):
185	coeff[0] = coeff[1] = level * LEVEL_3DB;
186	coeff[2] = level * slev * LEVEL_3DB;
187	return 7;
188
189	case CONVERT (A52_2F2R, A52_MONO):
190	coeff[0] = coeff[1] = level * LEVEL_3DB;
191	coeff[2] = coeff[3] = level * slev * LEVEL_3DB;
192	return 15;
193
194	case CONVERT (A52_3F1R, A52_MONO):
195	coeff[0] = coeff[2] = level * LEVEL_3DB;
196	coeff[1] = level * clev * LEVEL_PLUS3DB;
197	coeff[3] = level * slev * LEVEL_3DB;
198	return 15;
199
200	case CONVERT (A52_3F2R, A52_MONO):
201	coeff[0] = coeff[2] = level * LEVEL_3DB;
202	coeff[1] = level * clev * LEVEL_PLUS3DB;
203	coeff[3] = coeff[4] = level * slev * LEVEL_3DB;
204	return 31;
205
206	case CONVERT (A52_MONO, A52_DOLBY):
207	coeff[0] = level * LEVEL_3DB;
208	return 0;
209
210	case CONVERT (A52_3F, A52_DOLBY):
211	clev = LEVEL_3DB;
212	case CONVERT (A52_3F, A52_STEREO):
213	case CONVERT (A52_3F1R, A52_2F1R):
214	case CONVERT (A52_3F2R, A52_2F2R):
215	coeff[0] = coeff[2] = coeff[3] = coeff[4] = level;
216	coeff[1] = level * clev;
217	return 7;
218
219	case CONVERT (A52_2F1R, A52_DOLBY):
220	slev = 1;
221	case CONVERT (A52_2F1R, A52_STEREO):
222	coeff[0] = coeff[1] = level;
223	coeff[2] = level * slev * LEVEL_3DB;
224	return 7;
225
226	case CONVERT (A52_3F1R, A52_DOLBY):
227	clev = LEVEL_3DB;
228	slev = 1;
229	case CONVERT (A52_3F1R, A52_STEREO):
230	coeff[0] = coeff[2] = level;
231	coeff[1] = level * clev;
232	coeff[3] = level * slev * LEVEL_3DB;
233	return 15;
234
235	case CONVERT (A52_2F2R, A52_DOLBY):
236	slev = LEVEL_3DB;
237	case CONVERT (A52_2F2R, A52_STEREO):
238	coeff[0] = coeff[1] = level;
239	coeff[2] = coeff[3] = level * slev;
240	return 15;
241
242	case CONVERT (A52_3F2R, A52_DOLBY):
243	clev = LEVEL_3DB;
244	case CONVERT (A52_3F2R, A52_2F1R):
245	slev = LEVEL_3DB;
246	case CONVERT (A52_3F2R, A52_STEREO):
247	coeff[0] = coeff[2] = level;
248	coeff[1] = level * clev;
249	coeff[3] = coeff[4] = level * slev;
250	return 31;
251
252	case CONVERT (A52_3F1R, A52_3F):
253	coeff[0] = coeff[1] = coeff[2] = level;
254	coeff[3] = level * slev * LEVEL_3DB;
255	return 13;
256
257	case CONVERT (A52_3F2R, A52_3F):
258	coeff[0] = coeff[1] = coeff[2] = level;
259	coeff[3] = coeff[4] = level * slev;
260	return 29;
261
262	case CONVERT (A52_2F2R, A52_2F1R):
263	coeff[0] = coeff[1] = level;
264	coeff[2] = coeff[3] = level * LEVEL_3DB;
265	return 12;
266
267	case CONVERT (A52_3F2R, A52_3F1R):
268	coeff[0] = coeff[1] = coeff[2] = level;
269	coeff[3] = coeff[4] = level * LEVEL_3DB;
270	return 24;
271
272	case CONVERT (A52_2F1R, A52_2F2R):
273	coeff[0] = coeff[1] = level;
274	coeff[2] = level * LEVEL_3DB;
275	return 0;
276
277	case CONVERT (A52_3F1R, A52_2F2R):
278	coeff[0] = coeff[2] = level;
279	coeff[1] = level * clev;
280	coeff[3] = level * LEVEL_3DB;
281	return 7;
282
283	case CONVERT (A52_3F1R, A52_3F2R):
284	coeff[0] = coeff[1] = coeff[2] = level;
285	coeff[3] = level * LEVEL_3DB;
286	return 0;
287
288	case CONVERT (A52_CHANNEL, A52_CHANNEL1):
289	coeff[0] = level;
290	coeff[1] = 0;
291	return 0;
292
293	case CONVERT (A52_CHANNEL, A52_CHANNEL2):
294	coeff[0] = 0;
295	coeff[1] = level;
296	return 0;
297	}
298
299	return -1; /* NOTREACHED */
300	}
301
302	static void mix2to1 (sample_t * dest, sample_t * src, sample_t bias)
303	{
304	int i;
305
306	for (i = 0; i < 256; i++)
307	dest[i] += src[i] + bias;
308	}
309
310	static void mix3to1 (sample_t * samples, sample_t bias)
311	{
312	int i;
313
314	for (i = 0; i < 256; i++)
315	samples[i] += samples[i + 256] + samples[i + 512] + bias;
316	}
317
318	static void mix4to1 (sample_t * samples, sample_t bias)
319	{
320	int i;
321
322	for (i = 0; i < 256; i++)
323	samples[i] += (samples[i + 256] + samples[i + 512] +
324	samples[i + 768] + bias);
325	}
326
327	static void mix5to1 (sample_t * samples, sample_t bias)
328	{
329	int i;
330
331	for (i = 0; i < 256; i++)
332	samples[i] += (samples[i + 256] + samples[i + 512] +
333	samples[i + 768] + samples[i + 1024] + bias);
334	}
335
336	static void mix3to2 (sample_t * samples, sample_t bias)
337	{
338	int i;
339	sample_t common;
340
341	for (i = 0; i < 256; i++) {
342	common = samples[i + 256] + bias;
343	samples[i] += common;
344	samples[i + 256] = samples[i + 512] + common;
345	}
346	}
347
348	static void mix21to2 (sample_t * left, sample_t * right, sample_t bias)
349	{
350	int i;
351	sample_t common;
352
353	for (i = 0; i < 256; i++) {
354	common = right[i + 256] + bias;
355	left[i] += common;
356	right[i] += common;
357	}
358	}
359
360	static void mix21toS (sample_t * samples, sample_t bias)
361	{
362	int i;
363	sample_t surround;
364
365	for (i = 0; i < 256; i++) {
366	surround = samples[i + 512];
367	samples[i] += bias - surround;
368	samples[i + 256] += bias + surround;
369	}
370	}
371
372	static void mix31to2 (sample_t * samples, sample_t bias)
373	{
374	int i;
375	sample_t common;
376
377	for (i = 0; i < 256; i++) {
378	common = samples[i + 256] + samples[i + 768] + bias;
379	samples[i] += common;
380	samples[i + 256] = samples[i + 512] + common;
381	}
382	}
383
384	static void mix31toS (sample_t * samples, sample_t bias)
385	{
386	int i;
387	sample_t common, surround;
388
389	for (i = 0; i < 256; i++) {
390	common = samples[i + 256] + bias;
391	surround = samples[i + 768];
392	samples[i] += common - surround;
393	samples[i + 256] = samples[i + 512] + common + surround;
394	}
395	}
396
397	static void mix22toS (sample_t * samples, sample_t bias)
398	{
399	int i;
400	sample_t surround;
401
402	for (i = 0; i < 256; i++) {
403	surround = samples[i + 512] + samples[i + 768];
404	samples[i] += bias - surround;
405	samples[i + 256] += bias + surround;
406	}
407	}
408
409	static void mix32to2 (sample_t * samples, sample_t bias)
410	{
411	int i;
412	sample_t common;
413
414	for (i = 0; i < 256; i++) {
415	common = samples[i + 256] + bias;
416	samples[i] += common + samples[i + 768];
417	samples[i + 256] = common + samples[i + 512] + samples[i + 1024];
418	}
419	}
420
421	static void mix32toS (sample_t * samples, sample_t bias)
422	{
423	int i;
424	sample_t common, surround;
425
426	for (i = 0; i < 256; i++) {
427	common = samples[i + 256] + bias;
428	surround = samples[i + 768] + samples[i + 1024];
429	samples[i] += common - surround;
430	samples[i + 256] = samples[i + 512] + common + surround;
431	}
432	}
433
434	static void move2to1 (sample_t * src, sample_t * dest, sample_t bias)
435	{
436	int i;
437
438	for (i = 0; i < 256; i++)
439	dest[i] = src[i] + src[i + 256] + bias;
440	}
441
442	static void zero (sample_t * samples)
443	{
444	int i;
445
446	for (i = 0; i < 256; i++)
447	samples[i] = 0;
448	}
449
450	void a52_downmix (sample_t * samples, int acmod, int output, sample_t bias,
451	sample_t clev, sample_t slev)
452	{
453	switch (CONVERT (acmod, output & A52_CHANNEL_MASK)) {
454
455	case CONVERT (A52_CHANNEL, A52_CHANNEL2):
456	memcpy (samples, samples + 256, 256 * sizeof (sample_t));
457	break;
458
459	case CONVERT (A52_CHANNEL, A52_MONO):
460	case CONVERT (A52_STEREO, A52_MONO):
461	mix_2to1:
462	mix2to1 (samples, samples + 256, bias);
463	break;
464
465	case CONVERT (A52_2F1R, A52_MONO):
466	if (slev == 0)
467	goto mix_2to1;
468	case CONVERT (A52_3F, A52_MONO):
469	mix_3to1:
470	mix3to1 (samples, bias);
471	break;
472
473	case CONVERT (A52_3F1R, A52_MONO):
474	if (slev == 0)
475	goto mix_3to1;
476	case CONVERT (A52_2F2R, A52_MONO):
477	if (slev == 0)
478	goto mix_2to1;
479	mix4to1 (samples, bias);
480	break;
481
482	case CONVERT (A52_3F2R, A52_MONO):
483	if (slev == 0)
484	goto mix_3to1;
485	mix5to1 (samples, bias);
486	break;
487
488	case CONVERT (A52_MONO, A52_DOLBY):
489	memcpy (samples + 256, samples, 256 * sizeof (sample_t));
490	break;
491
492	case CONVERT (A52_3F, A52_STEREO):
493	case CONVERT (A52_3F, A52_DOLBY):
494	mix_3to2:
495	mix3to2 (samples, bias);
496	break;
497
498	case CONVERT (A52_2F1R, A52_STEREO):
499	if (slev == 0)
500	break;
501	mix21to2 (samples, samples + 256, bias);
502	break;
503
504	case CONVERT (A52_2F1R, A52_DOLBY):
505	mix21toS (samples, bias);
506	break;
507
508	case CONVERT (A52_3F1R, A52_STEREO):
509	if (slev == 0)
510	goto mix_3to2;
511	mix31to2 (samples, bias);
512	break;
513
514	case CONVERT (A52_3F1R, A52_DOLBY):
515	mix31toS (samples, bias);
516	break;
517
518	case CONVERT (A52_2F2R, A52_STEREO):
519	if (slev == 0)
520	break;
521	mix2to1 (samples, samples + 512, bias);
522	mix2to1 (samples + 256, samples + 768, bias);
523	break;
524
525	case CONVERT (A52_2F2R, A52_DOLBY):
526	mix22toS (samples, bias);
527	break;
528
529	case CONVERT (A52_3F2R, A52_STEREO):
530	if (slev == 0)
531	goto mix_3to2;
532	mix32to2 (samples, bias);
533	break;
534
535	case CONVERT (A52_3F2R, A52_DOLBY):
536	mix32toS (samples, bias);
537	break;
538
539	case CONVERT (A52_3F1R, A52_3F):
540	if (slev == 0)
541	break;
542	mix21to2 (samples, samples + 512, bias);
543	break;
544
545	case CONVERT (A52_3F2R, A52_3F):
546	if (slev == 0)
547	break;
548	mix2to1 (samples, samples + 768, bias);
549	mix2to1 (samples + 512, samples + 1024, bias);
550	break;
551
552	case CONVERT (A52_3F1R, A52_2F1R):
553	mix3to2 (samples, bias);
554	memcpy (samples + 512, samples + 768, 256 * sizeof (sample_t));
555	break;
556
557	case CONVERT (A52_2F2R, A52_2F1R):
558	mix2to1 (samples + 512, samples + 768, bias);
559	break;
560
561	case CONVERT (A52_3F2R, A52_2F1R):
562	mix3to2 (samples, bias);
563	move2to1 (samples + 768, samples + 512, bias);
564	break;
565
566	case CONVERT (A52_3F2R, A52_3F1R):
567	mix2to1 (samples + 768, samples + 1024, bias);
568	break;
569
570	case CONVERT (A52_2F1R, A52_2F2R):
571	memcpy (samples + 768, samples + 512, 256 * sizeof (sample_t));
572	break;
573
574	case CONVERT (A52_3F1R, A52_2F2R):
575	mix3to2 (samples, bias);
576	memcpy (samples + 512, samples + 768, 256 * sizeof (sample_t));
577	break;
578
579	case CONVERT (A52_3F2R, A52_2F2R):
580	mix3to2 (samples, bias);
581	memcpy (samples + 512, samples + 768, 256 * sizeof (sample_t));
582	memcpy (samples + 768, samples + 1024, 256 * sizeof (sample_t));
583	break;
584
585	case CONVERT (A52_3F1R, A52_3F2R):
586	memcpy (samples + 1027, samples + 768, 256 * sizeof (sample_t));
587	break;
588	}
589	}
590
591	void a52_upmix (sample_t * samples, int acmod, int output)
592	{
593	switch (CONVERT (acmod, output & A52_CHANNEL_MASK)) {
594
595	case CONVERT (A52_CHANNEL, A52_CHANNEL2):
596	memcpy (samples + 256, samples, 256 * sizeof (sample_t));
597	break;
598
599	case CONVERT (A52_3F2R, A52_MONO):
600	zero (samples + 1024);
601	case CONVERT (A52_3F1R, A52_MONO):
602	case CONVERT (A52_2F2R, A52_MONO):
603	zero (samples + 768);
604	case CONVERT (A52_3F, A52_MONO):
605	case CONVERT (A52_2F1R, A52_MONO):
606	zero (samples + 512);
607	case CONVERT (A52_CHANNEL, A52_MONO):
608	case CONVERT (A52_STEREO, A52_MONO):
609	zero (samples + 256);
610	break;
611
612	case CONVERT (A52_3F2R, A52_STEREO):
613	case CONVERT (A52_3F2R, A52_DOLBY):
614	zero (samples + 1024);
615	case CONVERT (A52_3F1R, A52_STEREO):
616	case CONVERT (A52_3F1R, A52_DOLBY):
617	zero (samples + 768);
618	case CONVERT (A52_3F, A52_STEREO):
619	case CONVERT (A52_3F, A52_DOLBY):
620	mix_3to2:
621	memcpy (samples + 512, samples + 256, 256 * sizeof (sample_t));
622	zero (samples + 256);
623	break;
624
625	case CONVERT (A52_2F2R, A52_STEREO):
626	case CONVERT (A52_2F2R, A52_DOLBY):
627	zero (samples + 768);
628	case CONVERT (A52_2F1R, A52_STEREO):
629	case CONVERT (A52_2F1R, A52_DOLBY):
630	zero (samples + 512);
631	break;
632
633	case CONVERT (A52_3F2R, A52_3F):
634	zero (samples + 1024);
635	case CONVERT (A52_3F1R, A52_3F):
636	case CONVERT (A52_2F2R, A52_2F1R):
637	zero (samples + 768);
638	break;
639
640	case CONVERT (A52_3F2R, A52_3F1R):
641	zero (samples + 1024);
642	break;
643
644	case CONVERT (A52_3F2R, A52_2F1R):
645	zero (samples + 1024);
646	case CONVERT (A52_3F1R, A52_2F1R):
647	mix_31to21:
648	memcpy (samples + 768, samples + 512, 256 * sizeof (sample_t));
649	goto mix_3to2;
650
651	case CONVERT (A52_3F2R, A52_2F2R):
652	memcpy (samples + 1024, samples + 768, 256 * sizeof (sample_t));
653	goto mix_31to21;
654	}
655	}