mpv/liba52/downmix.c

656 lines
16 KiB
C

/*
* downmix.c
* Copyright (C) 2000-2001 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
*/
#include "config.h"
#include <string.h>
#include <inttypes.h>
#include "a52.h"
#include "a52_internal.h"
#define CONVERT(acmod,output) (((output) << 3) + (acmod))
int 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 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 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 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;
}
}