/* the Music Player Daemon (MPD)
* Copyright (C) 2003-2007 by Warren Dukes (warren.dukes@gmail.com)
* This project's homepage is: http://www.musicpd.org
*
* This program 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.
*
* This program 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 "pcm_utils.h"
#include "pcm_channels.h"
#include "log.h"
#include "utils.h"
#include "conf.h"
#include "audio_format.h"
#include <assert.h>
#include <string.h>
#include <math.h>
static inline int
pcm_dither(void)
{
return (rand() & 511) - (rand() & 511);
}
/**
* Check if the value is within the range of the provided bit size,
* and caps it if necessary.
*/
static int32_t
pcm_range(int32_t sample, unsigned bits)
{
if (mpd_unlikely(sample < (-1 << (bits - 1))))
return -1 << (bits - 1);
if (mpd_unlikely(sample >= (1 << (bits - 1))))
return (1 << (bits - 1)) - 1;
return sample;
}
static void
pcm_volume_change_8(int8_t *buffer, unsigned num_samples, int volume)
{
while (num_samples > 0) {
int32_t sample = *buffer;
sample = (sample * volume + pcm_dither() + PCM_VOLUME_1 / 2)
/ PCM_VOLUME_1;
*buffer++ = pcm_range(sample, 8);
--num_samples;
}
}
static void
pcm_volume_change_16(int16_t *buffer, unsigned num_samples, int volume)
{
while (num_samples > 0) {
int32_t sample = *buffer;
sample = (sample * volume + pcm_dither() + PCM_VOLUME_1 / 2)
/ PCM_VOLUME_1;
*buffer++ = pcm_range(sample, 16);
--num_samples;
}
}
static void
pcm_volume_change_24(int32_t *buffer, unsigned num_samples, int volume)
{
while (num_samples > 0) {
int64_t sample = *buffer;
sample = (sample * volume + pcm_dither() + PCM_VOLUME_1 / 2)
/ PCM_VOLUME_1;
*buffer++ = pcm_range(sample, 24);
--num_samples;
}
}
void pcm_volume(char *buffer, int bufferSize,
const struct audio_format *format,
int volume)
{
if (volume >= PCM_VOLUME_1)
return;
if (volume <= 0) {
memset(buffer, 0, bufferSize);
return;
}
switch (format->bits) {
case 8:
pcm_volume_change_8((int8_t *)buffer, bufferSize, volume);
break;
case 16:
pcm_volume_change_16((int16_t *)buffer, bufferSize / 2,
volume);
break;
case 24:
pcm_volume_change_24((int32_t*)buffer, bufferSize / 4,
volume);
break;
default:
FATAL("%u bits not supported by pcm_volume!\n",
format->bits);
}
}
static void
pcm_add_8(int8_t *buffer1, const int8_t *buffer2,
unsigned num_samples, int volume1, int volume2)
{
while (num_samples > 0) {
int32_t sample1 = *buffer1;
int32_t sample2 = *buffer2++;
sample1 = ((sample1 * volume1 + sample2 * volume2) +
pcm_dither() + PCM_VOLUME_1 / 2) / PCM_VOLUME_1;
*buffer1++ = pcm_range(sample1, 8);
--num_samples;
}
}
static void
pcm_add_16(int16_t *buffer1, const int16_t *buffer2,
unsigned num_samples, int volume1, int volume2)
{
while (num_samples > 0) {
int32_t sample1 = *buffer1;
int32_t sample2 = *buffer2++;
sample1 = ((sample1 * volume1 + sample2 * volume2) +
pcm_dither() + PCM_VOLUME_1 / 2) / PCM_VOLUME_1;
*buffer1++ = pcm_range(sample1, 16);
--num_samples;
}
}
static void
pcm_add_24(int32_t *buffer1, const int32_t *buffer2,
unsigned num_samples, unsigned volume1, unsigned volume2)
{
while (num_samples > 0) {
int64_t sample1 = *buffer1;
int64_t sample2 = *buffer2++;
sample1 = ((sample1 * volume1 + sample2 * volume2) +
pcm_dither() + PCM_VOLUME_1 / 2) / PCM_VOLUME_1;
*buffer1++ = pcm_range(sample1, 24);
--num_samples;
}
}
static void pcm_add(char *buffer1, const char *buffer2, size_t size,
int vol1, int vol2,
const struct audio_format *format)
{
switch (format->bits) {
case 8:
pcm_add_8((int8_t *)buffer1, (const int8_t *)buffer2,
size, vol1, vol2);
break;
case 16:
pcm_add_16((int16_t *)buffer1, (const int16_t *)buffer2,
size / 2, vol1, vol2);
break;
case 24:
pcm_add_24((int32_t*)buffer1,
(const int32_t*)buffer2,
size / 4, vol1, vol2);
break;
default:
FATAL("%u bits not supported by pcm_add!\n", format->bits);
}
}
void pcm_mix(char *buffer1, const char *buffer2, size_t size,
const struct audio_format *format, float portion1)
{
int vol1;
float s = sin(M_PI_2 * portion1);
s *= s;
vol1 = s * PCM_VOLUME_1 + 0.5;
vol1 = vol1 > PCM_VOLUME_1 ? PCM_VOLUME_1 : (vol1 < 0 ? 0 : vol1);
pcm_add(buffer1, buffer2, size, vol1, PCM_VOLUME_1 - vol1, format);
}
void pcm_convert_init(struct pcm_convert_state *state)
{
memset(state, 0, sizeof(*state));
pcm_resample_init(&state->resample);
pcm_dither_24_init(&state->dither);
}
static void
pcm_convert_8_to_16(int16_t *out, const int8_t *in,
unsigned num_samples)
{
while (num_samples > 0) {
*out++ = *in++ << 8;
--num_samples;
}
}
static void
pcm_convert_24_to_16(struct pcm_dither_24 *dither,
int16_t *out, const int32_t *in,
unsigned num_samples)
{
pcm_dither_24_to_16(dither, out, in, num_samples);
}
static const int16_t *
pcm_convert_to_16(struct pcm_convert_state *convert,
uint8_t bits, const void *src,
size_t src_size, size_t *dest_size_r)
{
static int16_t *buf;
static size_t len;
unsigned num_samples;
switch (bits) {
case 8:
num_samples = src_size;
*dest_size_r = src_size << 1;
if (*dest_size_r > len) {
len = *dest_size_r;
buf = xrealloc(buf, len);
}
pcm_convert_8_to_16((int16_t *)buf,
(const int8_t *)src,
num_samples);
return buf;
case 16:
*dest_size_r = src_size;
return src;
case 24:
num_samples = src_size / 4;
*dest_size_r = num_samples * 2;
if (*dest_size_r > len) {
len = *dest_size_r;
buf = xrealloc(buf, len);
}
pcm_convert_24_to_16(&convert->dither,
(int16_t *)buf,
(const int32_t *)src,
num_samples);
return buf;
}
ERROR("only 8 or 16 bits are supported for conversion!\n");
return NULL;
}
static void
pcm_convert_8_to_24(int32_t *out, const int8_t *in,
unsigned num_samples)
{
while (num_samples > 0) {
*out++ = *in++ << 16;
--num_samples;
}
}
static void
pcm_convert_16_to_24(int32_t *out, const int16_t *in,
unsigned num_samples)
{
while (num_samples > 0) {
*out++ = *in++ << 8;
--num_samples;
}
}
static const int32_t *
pcm_convert_to_24(uint8_t bits, const void *src,
size_t src_size, size_t *dest_size_r)
{
static int32_t *buf;
static size_t len;
unsigned num_samples;
switch (bits) {
case 8:
num_samples = src_size;
*dest_size_r = src_size * 4;
if (*dest_size_r > len) {
len = *dest_size_r;
buf = xrealloc(buf, len);
}
pcm_convert_8_to_24(buf, (const int8_t *)src,
num_samples);
return buf;
case 16:
num_samples = src_size / 2;
*dest_size_r = num_samples * 4;
if (*dest_size_r > len) {
len = *dest_size_r;
buf = xrealloc(buf, len);
}
pcm_convert_16_to_24(buf, (const int16_t *)src,
num_samples);
return buf;
case 24:
*dest_size_r = src_size;
return src;
}
ERROR("only 8 or 24 bits are supported for conversion!\n");
return NULL;
}
static size_t
pcm_convert_16(const struct audio_format *src_format,
const void *src_buffer, size_t src_size,
const struct audio_format *dest_format,
int16_t *dest_buffer,
struct pcm_convert_state *state)
{
const int16_t *buf;
size_t len;
size_t dest_size = pcm_convert_size(src_format, src_size, dest_format);
assert(dest_format->bits == 16);
buf = pcm_convert_to_16(state, src_format->bits,
src_buffer, src_size, &len);
if (!buf)
exit(EXIT_FAILURE);
if (src_format->channels != dest_format->channels) {
buf = pcm_convert_channels_16(dest_format->channels,
src_format->channels,
buf, len, &len);
if (!buf)
exit(EXIT_FAILURE);
}
if (src_format->sample_rate == dest_format->sample_rate) {
assert(dest_size >= len);
memcpy(dest_buffer, buf, len);
} else {
len = pcm_resample_16(dest_format->channels,
src_format->sample_rate, buf, len,
dest_format->sample_rate,
dest_buffer, dest_size,
&state->resample);
if (len == 0)
exit(EXIT_FAILURE);
}
return len;
}
static size_t
pcm_convert_24(const struct audio_format *src_format,
const void *src_buffer, size_t src_size,
const struct audio_format *dest_format,
int32_t *dest_buffer,
struct pcm_convert_state *state)
{
const int32_t *buf;
size_t len;
size_t dest_size = pcm_convert_size(src_format, src_size, dest_format);
assert(dest_format->bits == 24);
buf = pcm_convert_to_24(src_format->bits,
src_buffer, src_size, &len);
if (!buf)
exit(EXIT_FAILURE);
if (src_format->channels != dest_format->channels) {
buf = pcm_convert_channels_24(dest_format->channels,
src_format->channels,
buf, len, &len);
if (!buf)
exit(EXIT_FAILURE);
}
if (src_format->sample_rate == dest_format->sample_rate) {
assert(dest_size >= len);
memcpy(dest_buffer, buf, len);
} else {
len = pcm_resample_24(dest_format->channels,
src_format->sample_rate, buf, len,
dest_format->sample_rate,
(int32_t*)dest_buffer, dest_size,
&state->resample);
if (len == 0)
exit(EXIT_FAILURE);
}
return len;
}
/* outFormat bits must be 16 and channels must be 1 or 2! */
size_t pcm_convert(const struct audio_format *inFormat,
const char *src, size_t src_size,
const struct audio_format *outFormat,
char *outBuffer,
struct pcm_convert_state *convState)
{
switch (outFormat->bits) {
case 16:
return pcm_convert_16(inFormat, src, src_size,
outFormat, (int16_t*)outBuffer,
convState);
case 24:
return pcm_convert_24(inFormat, src, src_size,
outFormat, (int32_t*)outBuffer,
convState);
default:
FATAL("cannot convert to %u bit\n", outFormat->bits);
}
}
size_t pcm_convert_size(const struct audio_format *inFormat, size_t src_size,
const struct audio_format *outFormat)
{
const double ratio = (double)outFormat->sample_rate /
(double)inFormat->sample_rate;
size_t dest_size = src_size;
/* no partial frames allowed */
assert((src_size % audio_format_frame_size(inFormat)) == 0);
dest_size /= audio_format_frame_size(inFormat);
dest_size = floor(0.5 + (double)dest_size * ratio);
dest_size *= audio_format_frame_size(outFormat);
return dest_size;
}