/* 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 "../inputPlugin.h"
#ifdef HAVE_MAD
#include <mad.h>
#ifdef HAVE_ID3TAG
#include <id3tag.h>
#endif
#include "../log.h"
#include "../utils.h"
#include "../conf.h"
#define FRAMES_CUSHION 2000
#define READ_BUFFER_SIZE 40960
enum mp3_action {
DECODE_SKIP = -3,
DECODE_BREAK = -2,
DECODE_CONT = -1,
DECODE_OK = 0
};
enum muteframe {
MUTEFRAME_NONE,
MUTEFRAME_SKIP,
MUTEFRAME_SEEK
};
/* the number of samples of silence the decoder inserts at start */
#define DECODERDELAY 529
#define DEFAULT_GAPLESS_MP3_PLAYBACK 1
static int gaplessPlaybackEnabled;
/* this is stolen from mpg321! */
struct audio_dither {
mad_fixed_t error[3];
mad_fixed_t random;
};
static unsigned long prng(unsigned long state)
{
return (state * 0x0019660dL + 0x3c6ef35fL) & 0xffffffffL;
}
static int16_t audio_linear_dither(unsigned int bits, mad_fixed_t sample,
struct audio_dither *dither)
{
unsigned int scalebits;
mad_fixed_t output, mask, rnd;
enum {
MIN = -MAD_F_ONE,
MAX = MAD_F_ONE - 1
};
sample += dither->error[0] - dither->error[1] + dither->error[2];
dither->error[2] = dither->error[1];
dither->error[1] = dither->error[0] / 2;
output = sample + (1L << (MAD_F_FRACBITS + 1 - bits - 1));
scalebits = MAD_F_FRACBITS + 1 - bits;
mask = (1L << scalebits) - 1;
rnd = prng(dither->random);
output += (rnd & mask) - (dither->random & mask);
dither->random = rnd;
if (output > MAX) {
output = MAX;
if (sample > MAX)
sample = MAX;
} else if (output < MIN) {
output = MIN;
if (sample < MIN)
sample = MIN;
}
output &= ~mask;
dither->error[0] = sample - output;
return (int16_t)(output >> scalebits);
}
static unsigned dither_buffer(int16_t *dest0, const struct mad_synth *synth,
struct audio_dither *dither,
unsigned int start, unsigned int end,
unsigned int num_channels)
{
int16_t *dest = dest0;
unsigned int i;
for (i = start; i < end; ++i) {
*dest++ = audio_linear_dither(16,
synth->pcm.samples[0][i],
dither);
if (num_channels == 2)
*dest++ = audio_linear_dither(16,
synth->pcm.samples[1][i],
dither);
}
return dest - dest0;
}
/* end of stolen stuff from mpg321 */
static int mp3_plugin_init(void)
{
gaplessPlaybackEnabled = getBoolConfigParam(CONF_GAPLESS_MP3_PLAYBACK,
1);
if (gaplessPlaybackEnabled == CONF_BOOL_UNSET)
gaplessPlaybackEnabled = DEFAULT_GAPLESS_MP3_PLAYBACK;
return 1;
}
/* decoder stuff is based on madlld */
#define MP3_DATA_OUTPUT_BUFFER_SIZE 2048
typedef struct _mp3DecodeData {
struct mad_stream stream;
struct mad_frame frame;
struct mad_synth synth;
mad_timer_t timer;
unsigned char readBuffer[READ_BUFFER_SIZE];
int16_t outputBuffer[MP3_DATA_OUTPUT_BUFFER_SIZE];
float totalTime;
float elapsedTime;
enum muteframe muteFrame;
long *frameOffset;
mad_timer_t *times;
unsigned long highestFrame;
unsigned long maxFrames;
unsigned long currentFrame;
unsigned int dropFramesAtStart;
unsigned int dropFramesAtEnd;
unsigned int dropSamplesAtStart;
unsigned int dropSamplesAtEnd;
int foundXing;
int foundFirstFrame;
int decodedFirstFrame;
unsigned long bitRate;
InputStream *inStream;
struct audio_dither dither;
enum mad_layer layer;
} mp3DecodeData;
static void initMp3DecodeData(mp3DecodeData * data, InputStream * inStream)
{
data->muteFrame = MUTEFRAME_NONE;
data->highestFrame = 0;
data->maxFrames = 0;
data->frameOffset = NULL;
data->times = NULL;
data->currentFrame = 0;
data->dropFramesAtStart = 0;
data->dropFramesAtEnd = 0;
data->dropSamplesAtStart = 0;
data->dropSamplesAtEnd = 0;
data->foundXing = 0;
data->foundFirstFrame = 0;
data->decodedFirstFrame = 0;
data->inStream = inStream;
data->layer = 0;
memset(&(data->dither), 0, sizeof(struct audio_dither));
mad_stream_init(&data->stream);
mad_stream_options(&data->stream, MAD_OPTION_IGNORECRC);
mad_frame_init(&data->frame);
mad_synth_init(&data->synth);
mad_timer_reset(&data->timer);
}
static int seekMp3InputBuffer(mp3DecodeData * data, long offset)
{
if (seekInputStream(data->inStream, offset, SEEK_SET) < 0) {
return -1;
}
mad_stream_buffer(&data->stream, data->readBuffer, 0);
(data->stream).error = 0;
return 0;
}
static int fillMp3InputBuffer(mp3DecodeData * data)
{
size_t readSize;
size_t remaining;
size_t readed;
unsigned char *readStart;
if ((data->stream).next_frame != NULL) {
remaining = (data->stream).bufend - (data->stream).next_frame;
memmove(data->readBuffer, (data->stream).next_frame, remaining);
readStart = (data->readBuffer) + remaining;
readSize = READ_BUFFER_SIZE - remaining;
} else {
readSize = READ_BUFFER_SIZE;
readStart = data->readBuffer, remaining = 0;
}
/* we've exhausted the read buffer, so give up!, these potential
* mp3 frames are way too big, and thus unlikely to be mp3 frames */
if (readSize == 0)
return -1;
readed = readFromInputStream(data->inStream, readStart, (size_t) 1,
readSize);
if (readed <= 0 && inputStreamAtEOF(data->inStream))
return -1;
/* sleep for a fraction of a second! */
else if (readed <= 0) {
readed = 0;
my_usleep(10000);
}
mad_stream_buffer(&data->stream, data->readBuffer, readed + remaining);
(data->stream).error = 0;
return 0;
}
#ifdef HAVE_ID3TAG
static ReplayGainInfo *parseId3ReplayGainInfo(struct id3_tag *tag)
{
int i;
char *key;
char *value;
struct id3_frame *frame;
int found = 0;
ReplayGainInfo *replayGainInfo;
replayGainInfo = newReplayGainInfo();
for (i = 0; (frame = id3_tag_findframe(tag, "TXXX", i)); i++) {
if (frame->nfields < 3)
continue;
key = (char *)
id3_ucs4_latin1duplicate(id3_field_getstring
(&frame->fields[1]));
value = (char *)
id3_ucs4_latin1duplicate(id3_field_getstring
(&frame->fields[2]));
if (strcasecmp(key, "replaygain_track_gain") == 0) {
replayGainInfo->trackGain = atof(value);
found = 1;
} else if (strcasecmp(key, "replaygain_album_gain") == 0) {
replayGainInfo->albumGain = atof(value);
found = 1;
} else if (strcasecmp(key, "replaygain_track_peak") == 0) {
replayGainInfo->trackPeak = atof(value);
found = 1;
} else if (strcasecmp(key, "replaygain_album_peak") == 0) {
replayGainInfo->albumPeak = atof(value);
found = 1;
}
free(key);
free(value);
}
if (found)
return replayGainInfo;
freeReplayGainInfo(replayGainInfo);
return NULL;
}
#endif
#ifdef HAVE_ID3TAG
static void mp3_parseId3Tag(mp3DecodeData * data, size_t tagsize,
struct mpd_tag ** mpdTag, ReplayGainInfo ** replayGainInfo)
{
struct id3_tag *id3Tag = NULL;
id3_length_t count;
id3_byte_t const *id3_data;
id3_byte_t *allocated = NULL;
struct mpd_tag *tmpMpdTag;
ReplayGainInfo *tmpReplayGainInfo;
count = data->stream.bufend - data->stream.this_frame;
if (tagsize <= count) {
id3_data = data->stream.this_frame;
mad_stream_skip(&(data->stream), tagsize);
} else {
allocated = xmalloc(tagsize);
if (!allocated)
goto fail;
memcpy(allocated, data->stream.this_frame, count);
mad_stream_skip(&(data->stream), count);
while (count < tagsize) {
size_t len;
len = readFromInputStream(data->inStream,
allocated + count, (size_t) 1,
tagsize - count);
if (len <= 0 && inputStreamAtEOF(data->inStream))
break;
else
count += len;
}
if (count != tagsize) {
DEBUG("mp3_decode: error parsing ID3 tag\n");
goto fail;
}
id3_data = allocated;
}
id3Tag = id3_tag_parse(id3_data, tagsize);
if (!id3Tag)
goto fail;
if (mpdTag) {
tmpMpdTag = tag_id3_import(id3Tag);
if (tmpMpdTag) {
if (*mpdTag)
tag_free(*mpdTag);
*mpdTag = tmpMpdTag;
}
}
if (replayGainInfo) {
tmpReplayGainInfo = parseId3ReplayGainInfo(id3Tag);
if (tmpReplayGainInfo) {
if (*replayGainInfo)
freeReplayGainInfo(*replayGainInfo);
*replayGainInfo = tmpReplayGainInfo;
}
}
id3_tag_delete(id3Tag);
fail:
if (allocated)
free(allocated);
}
#endif
static enum mp3_action
decodeNextFrameHeader(mp3DecodeData * data, struct mpd_tag ** tag,
ReplayGainInfo ** replayGainInfo)
{
enum mad_layer layer;
if ((data->stream).buffer == NULL
|| (data->stream).error == MAD_ERROR_BUFLEN) {
if (fillMp3InputBuffer(data) < 0) {
return DECODE_BREAK;
}
}
if (mad_header_decode(&data->frame.header, &data->stream)) {
#ifdef HAVE_ID3TAG
if ((data->stream).error == MAD_ERROR_LOSTSYNC &&
(data->stream).this_frame) {
signed long tagsize = id3_tag_query((data->stream).
this_frame,
(data->stream).
bufend -
(data->stream).
this_frame);
if (tagsize > 0) {
if (tag && !(*tag)) {
mp3_parseId3Tag(data, (size_t)tagsize,
tag, replayGainInfo);
} else {
mad_stream_skip(&(data->stream),
tagsize);
}
return DECODE_CONT;
}
}
#endif
if (MAD_RECOVERABLE((data->stream).error)) {
return DECODE_SKIP;
} else {
if ((data->stream).error == MAD_ERROR_BUFLEN)
return DECODE_CONT;
else {
ERROR("unrecoverable frame level error "
"(%s).\n",
mad_stream_errorstr(&data->stream));
return DECODE_BREAK;
}
}
}
layer = data->frame.header.layer;
if (!data->layer) {
if (layer != MAD_LAYER_II && layer != MAD_LAYER_III) {
/* Only layer 2 and 3 have been tested to work */
return DECODE_SKIP;
}
data->layer = layer;
} else if (layer != data->layer) {
/* Don't decode frames with a different layer than the first */
return DECODE_SKIP;
}
return DECODE_OK;
}
static enum mp3_action
decodeNextFrame(mp3DecodeData * data)
{
if ((data->stream).buffer == NULL
|| (data->stream).error == MAD_ERROR_BUFLEN) {
if (fillMp3InputBuffer(data) < 0) {
return DECODE_BREAK;
}
}
if (mad_frame_decode(&data->frame, &data->stream)) {
#ifdef HAVE_ID3TAG
if ((data->stream).error == MAD_ERROR_LOSTSYNC) {
signed long tagsize = id3_tag_query((data->stream).
this_frame,
(data->stream).
bufend -
(data->stream).
this_frame);
if (tagsize > 0) {
mad_stream_skip(&(data->stream), tagsize);
return DECODE_CONT;
}
}
#endif
if (MAD_RECOVERABLE((data->stream).error)) {
return DECODE_SKIP;
} else {
if ((data->stream).error == MAD_ERROR_BUFLEN)
return DECODE_CONT;
else {
ERROR("unrecoverable frame level error "
"(%s).\n",
mad_stream_errorstr(&data->stream));
return DECODE_BREAK;
}
}
}
return DECODE_OK;
}
/* xing stuff stolen from alsaplayer, and heavily modified by jat */
#define XI_MAGIC (('X' << 8) | 'i')
#define NG_MAGIC (('n' << 8) | 'g')
#define IN_MAGIC (('I' << 8) | 'n')
#define FO_MAGIC (('f' << 8) | 'o')
enum xing_magic {
XING_MAGIC_XING, /* VBR */
XING_MAGIC_INFO /* CBR */
};
struct xing {
long flags; /* valid fields (see below) */
unsigned long frames; /* total number of frames */
unsigned long bytes; /* total number of bytes */
unsigned char toc[100]; /* 100-point seek table */
long scale; /* VBR quality */
enum xing_magic magic; /* header magic */
};
enum {
XING_FRAMES = 0x00000001L,
XING_BYTES = 0x00000002L,
XING_TOC = 0x00000004L,
XING_SCALE = 0x00000008L
};
struct version {
unsigned major;
unsigned minor;
};
struct lame {
char encoder[10]; /* 9 byte encoder name/version ("LAME3.97b") */
struct version version; /* struct containing just the version */
float peak; /* replaygain peak */
float trackGain; /* replaygain track gain */
float albumGain; /* replaygain album gain */
int encoderDelay; /* # of added samples at start of mp3 */
int encoderPadding; /* # of added samples at end of mp3 */
int crc; /* CRC of the first 190 bytes of this frame */
};
static int parse_xing(struct xing *xing, struct mad_bitptr *ptr, int *oldbitlen)
{
unsigned long bits;
int bitlen;
int bitsleft;
int i;
bitlen = *oldbitlen;
if (bitlen < 16) goto fail;
bits = mad_bit_read(ptr, 16);
bitlen -= 16;
if (bits == XI_MAGIC) {
if (bitlen < 16) goto fail;
if (mad_bit_read(ptr, 16) != NG_MAGIC) goto fail;
bitlen -= 16;
xing->magic = XING_MAGIC_XING;
} else if (bits == IN_MAGIC) {
if (bitlen < 16) goto fail;
if (mad_bit_read(ptr, 16) != FO_MAGIC) goto fail;
bitlen -= 16;
xing->magic = XING_MAGIC_INFO;
}
else if (bits == NG_MAGIC) xing->magic = XING_MAGIC_XING;
else if (bits == FO_MAGIC) xing->magic = XING_MAGIC_INFO;
else goto fail;
if (bitlen < 32) goto fail;
xing->flags = mad_bit_read(ptr, 32);
bitlen -= 32;
if (xing->flags & XING_FRAMES) {
if (bitlen < 32) goto fail;
xing->frames = mad_bit_read(ptr, 32);
bitlen -= 32;
}
if (xing->flags & XING_BYTES) {
if (bitlen < 32) goto fail;
xing->bytes = mad_bit_read(ptr, 32);
bitlen -= 32;
}
if (xing->flags & XING_TOC) {
if (bitlen < 800) goto fail;
for (i = 0; i < 100; ++i) xing->toc[i] = mad_bit_read(ptr, 8);
bitlen -= 800;
}
if (xing->flags & XING_SCALE) {
if (bitlen < 32) goto fail;
xing->scale = mad_bit_read(ptr, 32);
bitlen -= 32;
}
/* Make sure we consume no less than 120 bytes (960 bits) in hopes that
* the LAME tag is found there, and not right after the Xing header */
bitsleft = 960 - ((*oldbitlen) - bitlen);
if (bitsleft < 0) goto fail;
else if (bitsleft > 0) {
mad_bit_read(ptr, bitsleft);
bitlen -= bitsleft;
}
*oldbitlen = bitlen;
return 1;
fail:
xing->flags = 0;
return 0;
}
static int parse_lame(struct lame *lame, struct mad_bitptr *ptr, int *bitlen)
{
int adj = 0;
int name;
int orig;
int sign;
int gain;
int i;
/* Unlike the xing header, the lame tag has a fixed length. Fail if
* not all 36 bytes (288 bits) are there. */
if (*bitlen < 288)
return 0;
for (i = 0; i < 9; i++)
lame->encoder[i] = (char)mad_bit_read(ptr, 8);
lame->encoder[9] = '\0';
*bitlen -= 72;
/* This is technically incorrect, since the encoder might not be lame.
* But there's no other way to determine if this is a lame tag, and we
* wouldn't want to go reading a tag that's not there. */
if (prefixcmp(lame->encoder, "LAME"))
return 0;
if (sscanf(lame->encoder+4, "%u.%u",
&lame->version.major, &lame->version.minor) != 2)
return 0;
DEBUG("detected LAME version %i.%i (\"%s\")\n",
lame->version.major, lame->version.minor, lame->encoder);
/* The reference volume was changed from the 83dB used in the
* ReplayGain spec to 89dB in lame 3.95.1. Bump the gain for older
* versions, since everyone else uses 89dB instead of 83dB.
* Unfortunately, lame didn't differentiate between 3.95 and 3.95.1, so
* it's impossible to make the proper adjustment for 3.95.
* Fortunately, 3.95 was only out for about a day before 3.95.1 was
* released. -- tmz */
if (lame->version.major < 3 ||
(lame->version.major == 3 && lame->version.minor < 95))
adj = 6;
mad_bit_read(ptr, 16);
lame->peak = mad_f_todouble(mad_bit_read(ptr, 32) << 5); /* peak */
DEBUG("LAME peak found: %f\n", lame->peak);
lame->trackGain = 0;
name = mad_bit_read(ptr, 3); /* gain name */
orig = mad_bit_read(ptr, 3); /* gain originator */
sign = mad_bit_read(ptr, 1); /* sign bit */
gain = mad_bit_read(ptr, 9); /* gain*10 */
if (gain && name == 1 && orig != 0) {
lame->trackGain = ((sign ? -gain : gain) / 10.0) + adj;
DEBUG("LAME track gain found: %f\n", lame->trackGain);
}
/* tmz reports that this isn't currently written by any version of lame
* (as of 3.97). Since we have no way of testing it, don't use it.
* Wouldn't want to go blowing someone's ears just because we read it
* wrong. :P -- jat */
lame->albumGain = 0;
#if 0
name = mad_bit_read(ptr, 3); /* gain name */
orig = mad_bit_read(ptr, 3); /* gain originator */
sign = mad_bit_read(ptr, 1); /* sign bit */
gain = mad_bit_read(ptr, 9); /* gain*10 */
if (gain && name == 2 && orig != 0) {
lame->albumGain = ((sign ? -gain : gain) / 10.0) + adj;
DEBUG("LAME album gain found: %f\n", lame->trackGain);
}
#else
mad_bit_read(ptr, 16);
#endif
mad_bit_read(ptr, 16);
lame->encoderDelay = mad_bit_read(ptr, 12);
lame->encoderPadding = mad_bit_read(ptr, 12);
DEBUG("encoder delay is %i, encoder padding is %i\n",
lame->encoderDelay, lame->encoderPadding);
mad_bit_read(ptr, 80);
lame->crc = mad_bit_read(ptr, 16);
*bitlen -= 216;
return 1;
}
static int decodeFirstFrame(mp3DecodeData * data,
struct mpd_tag ** tag, ReplayGainInfo ** replayGainInfo)
{
struct xing xing;
struct lame lame;
struct mad_bitptr ptr;
int bitlen;
int ret;
/* stfu gcc */
memset(&xing, 0, sizeof(struct xing));
xing.flags = 0;
while (1) {
while ((ret = decodeNextFrameHeader(data, tag, replayGainInfo)) == DECODE_CONT &&
!dc_intr());
if (ret == DECODE_BREAK || dc_intr()) return -1;
if (ret == DECODE_SKIP) continue;
while ((ret = decodeNextFrame(data)) == DECODE_CONT &&
!dc_intr());
if (ret == DECODE_BREAK || dc_intr()) return -1;
if (ret == DECODE_OK) break;
}
ptr = data->stream.anc_ptr;
bitlen = data->stream.anc_bitlen;
/*
* Attempt to calulcate the length of the song from filesize
*/
{
size_t offset = data->inStream->offset;
mad_timer_t duration = data->frame.header.duration;
float frameTime = ((float)mad_timer_count(duration,
MAD_UNITS_MILLISECONDS)) / 1000;
if (data->stream.this_frame != NULL)
offset -= data->stream.bufend - data->stream.this_frame;
else
offset -= data->stream.bufend - data->stream.buffer;
if (data->inStream->size >= offset) {
data->totalTime = ((data->inStream->size - offset) *
8.0) / (data->frame).header.bitrate;
data->maxFrames = data->totalTime / frameTime +
FRAMES_CUSHION;
} else {
data->maxFrames = FRAMES_CUSHION;
data->totalTime = 0;
}
}
/*
* if an xing tag exists, use that!
*/
if (parse_xing(&xing, &ptr, &bitlen)) {
data->foundXing = 1;
data->muteFrame = MUTEFRAME_SKIP;
if ((xing.flags & XING_FRAMES) && xing.frames) {
mad_timer_t duration = data->frame.header.duration;
mad_timer_multiply(&duration, xing.frames);
data->totalTime = ((float)mad_timer_count(duration, MAD_UNITS_MILLISECONDS)) / 1000;
data->maxFrames = xing.frames;
}
if (parse_lame(&lame, &ptr, &bitlen)) {
if (gaplessPlaybackEnabled &&
data->inStream->seekable) {
data->dropSamplesAtStart = lame.encoderDelay +
DECODERDELAY;
data->dropSamplesAtEnd = lame.encoderPadding;
}
/* Album gain isn't currently used. See comment in
* parse_lame() for details. -- jat */
if (replayGainInfo && !*replayGainInfo &&
lame.trackGain) {
*replayGainInfo = newReplayGainInfo();
(*replayGainInfo)->trackGain = lame.trackGain;
(*replayGainInfo)->trackPeak = lame.peak;
}
}
}
if (!data->maxFrames) return -1;
if (data->maxFrames > 8 * 1024 * 1024) {
ERROR("mp3 file header indicates too many frames: %lu",
data->maxFrames);
return -1;
}
data->frameOffset = xmalloc(sizeof(long) * data->maxFrames);
data->times = xmalloc(sizeof(mad_timer_t) * data->maxFrames);
return 0;
}
static void mp3DecodeDataFinalize(mp3DecodeData * data)
{
mad_synth_finish(&data->synth);
mad_frame_finish(&data->frame);
mad_stream_finish(&data->stream);
if (data->frameOffset) free(data->frameOffset);
if (data->times) free(data->times);
}
/* this is primarily used for getting total time for tags */
static int getMp3TotalTime(char *file)
{
InputStream inStream;
mp3DecodeData data;
int ret;
if (openInputStream(&inStream, file) < 0)
return -1;
initMp3DecodeData(&data, &inStream);
if (decodeFirstFrame(&data, NULL, NULL) < 0)
ret = -1;
else
ret = data.totalTime + 0.5;
mp3DecodeDataFinalize(&data);
closeInputStream(&inStream);
return ret;
}
static int openMp3FromInputStream(InputStream * inStream, mp3DecodeData * data,
struct mpd_tag ** tag,
ReplayGainInfo ** replayGainInfo)
{
initMp3DecodeData(data, inStream);
*tag = NULL;
if (decodeFirstFrame(data, tag, replayGainInfo) < 0) {
mp3DecodeDataFinalize(data);
if (tag && *tag)
tag_free(*tag);
return -1;
}
return 0;
}
static float frame_time(mp3DecodeData * data, long j)
{
return (((float)mad_timer_count(data->times[j],
MAD_UNITS_MILLISECONDS)) / 1000);
}
static void mp3Read_seek(mp3DecodeData * data)
{
unsigned long j = 0;
data->muteFrame = MUTEFRAME_SEEK;
assert(pthread_equal(pthread_self(), dc.thread));
assert(dc.action == DC_ACTION_SEEK);
while (j < data->highestFrame && dc.seek_where > frame_time(data, j))
j++;
if (j < data->highestFrame) {
dc_action_begin();
if (seekMp3InputBuffer(data, data->frameOffset[j]) < 0)
dc.seek_where = DC_SEEK_ERROR;
else
data->currentFrame = j;
data->muteFrame = MUTEFRAME_NONE;
dc_action_end();
}
}
static enum mp3_action
mp3Read(mp3DecodeData * data, ReplayGainInfo ** replayGainInfo)
{
unsigned int pcm_length, max_samples;
unsigned int i;
int ret;
int skip;
assert(pthread_equal(pthread_self(), dc.thread));
if (data->currentFrame >= data->highestFrame) {
mad_timer_add(&data->timer, (data->frame).header.duration);
data->bitRate = (data->frame).header.bitrate;
if (data->currentFrame >= data->maxFrames) {
data->currentFrame = data->maxFrames - 1;
} else {
data->highestFrame++;
}
data->frameOffset[data->currentFrame] = data->inStream->offset;
if (data->stream.this_frame != NULL) {
data->frameOffset[data->currentFrame] -=
data->stream.bufend - data->stream.this_frame;
} else {
data->frameOffset[data->currentFrame] -=
data->stream.bufend - data->stream.buffer;
}
data->times[data->currentFrame] = data->timer;
} else {
data->timer = data->times[data->currentFrame];
}
data->currentFrame++;
data->elapsedTime =
((float)mad_timer_count(data->timer, MAD_UNITS_MILLISECONDS)) /
1000;
switch (data->muteFrame) {
case MUTEFRAME_SKIP:
data->muteFrame = MUTEFRAME_NONE;
break;
case MUTEFRAME_SEEK:
if (dc.seek_where <= data->elapsedTime) {
dc_action_begin();
assert(dc.action == DC_ACTION_SEEK);
data->muteFrame = MUTEFRAME_NONE;
dc_action_end();
}
break;
case MUTEFRAME_NONE:
mad_synth_frame(&data->synth, &data->frame);
if (!data->foundFirstFrame) {
unsigned int samplesPerFrame = (data->synth).pcm.length;
data->dropFramesAtStart = data->dropSamplesAtStart / samplesPerFrame;
data->dropFramesAtEnd = data->dropSamplesAtEnd / samplesPerFrame;
data->dropSamplesAtStart = data->dropSamplesAtStart % samplesPerFrame;
data->dropSamplesAtEnd = data->dropSamplesAtEnd % samplesPerFrame;
data->foundFirstFrame = 1;
}
if (data->dropFramesAtStart > 0) {
data->dropFramesAtStart--;
break;
} else if ((data->dropFramesAtEnd > 0) &&
(data->currentFrame == (data->maxFrames + 1 - data->dropFramesAtEnd))) {
/* stop decoding, effectively dropping all remaining
* frames */
return DECODE_BREAK;
}
if (data->inStream->metaTitle) {
struct mpd_tag *tag = tag_new();
if (data->inStream->metaName) {
tag_add_item(tag, TAG_ITEM_NAME,
data->inStream->metaName);
}
tag_add_item(tag, TAG_ITEM_TITLE,
data->inStream->metaTitle);
free(data->inStream->metaTitle);
data->inStream->metaTitle = NULL;
metadata_pipe_send(tag, data->elapsedTime);
}
if (!data->decodedFirstFrame) {
i = data->dropSamplesAtStart;
data->decodedFirstFrame = 1;
} else
i = 0;
pcm_length = data->synth.pcm.length;
if (data->dropSamplesAtEnd &&
(data->currentFrame == data->maxFrames - data->dropFramesAtEnd)) {
if (data->dropSamplesAtEnd >= pcm_length)
pcm_length = 0;
else
pcm_length -= data->dropSamplesAtEnd;
}
max_samples = sizeof(data->outputBuffer) /
(2 * MAD_NCHANNELS(&(data->frame).header));
while (i < pcm_length) {
enum dc_action action;
unsigned int num_samples = pcm_length - i;
if (num_samples > max_samples)
num_samples = max_samples;
i += num_samples;
num_samples = dither_buffer(data->outputBuffer,
&data->synth, &data->dither,
i - num_samples, i,
MAD_NCHANNELS(
&(data->frame).header));
action = ob_send(data->outputBuffer,
2 * num_samples,
data->elapsedTime,
data->bitRate / 1000,
replayGainInfo ? *replayGainInfo : NULL);
if (action == DC_ACTION_STOP)
return DECODE_BREAK;
if (action == DC_ACTION_SEEK)
break;
}
if (data->dropSamplesAtEnd &&
(data->currentFrame ==
(data->maxFrames - data->dropFramesAtEnd)))
/* stop decoding, effectively dropping
* all remaining samples */
return DECODE_BREAK;
if (dc_seek()) {
if (data->inStream->seekable)
mp3Read_seek(data);
else
dc_action_seek_fail(DC_SEEK_ERROR);
}
}
while (1) {
skip = 0;
while ((ret =
decodeNextFrameHeader(data, NULL,
replayGainInfo)) == DECODE_CONT
&& dc_intr()) ;
if (ret == DECODE_BREAK || dc_intr() || dc_seek())
break;
else if (ret == DECODE_SKIP)
skip = 1;
if (data->muteFrame == MUTEFRAME_NONE) {
while ((ret = decodeNextFrame(data)) == DECODE_CONT &&
!dc_intr() && dc_seek()) ;
if (ret == DECODE_BREAK || dc_intr() || dc_seek())
break;
}
if (!skip && ret == DECODE_OK)
break;
}
if (dc_intr())
return DECODE_BREAK;
return ret;
}
static void initAudioFormatFromMp3DecodeData(mp3DecodeData * data,
AudioFormat * af)
{
af->bits = 16;
af->sampleRate = (data->frame).header.samplerate;
af->channels = MAD_NCHANNELS(&(data->frame).header);
}
static int mp3_decode(InputStream * inStream)
{
mp3DecodeData data;
struct mpd_tag *tag = NULL;
ReplayGainInfo *replayGainInfo = NULL;
if (openMp3FromInputStream(inStream, &data, &tag, &replayGainInfo) < 0) {
if (!dc_intr()) {
ERROR
("Input does not appear to be a mp3 bit stream.\n");
return -1;
}
return 0;
}
initAudioFormatFromMp3DecodeData(&data, &(dc.audio_format));
dc.total_time = data.totalTime;
if (inStream->metaTitle) {
if (tag)
tag_free(tag);
tag = tag_new();
tag_add_item(tag, TAG_ITEM_TITLE, inStream->metaTitle);
free(inStream->metaTitle);
inStream->metaTitle = NULL;
if (inStream->metaName) {
tag_add_item(tag, TAG_ITEM_NAME, inStream->metaName);
}
} else if (tag) {
if (inStream->metaName) {
tag_clear_items_by_type(tag, TAG_ITEM_NAME);
tag_add_item(tag, TAG_ITEM_NAME, inStream->metaName);
}
} else if (inStream->metaName) {
tag = tag_new();
if (inStream->metaName) {
tag_add_item(tag, TAG_ITEM_NAME, inStream->metaName);
}
}
if (tag)
metadata_pipe_send(tag, 0);
while (mp3Read(&data, &replayGainInfo) != DECODE_BREAK) ;
if (replayGainInfo)
freeReplayGainInfo(replayGainInfo);
mp3DecodeDataFinalize(&data);
return 0;
}
static struct mpd_tag *mp3_tagDup(char *file)
{
struct mpd_tag *ret = NULL;
int total_time;
ret = tag_id3_load(file);
total_time = getMp3TotalTime(file);
if (total_time >= 0) {
if (!ret)
ret = tag_new();
ret->time = total_time;
} else {
DEBUG("mp3_tagDup: Failed to get total song time from: %s\n",
file);
}
return ret;
}
static const char *mp3_suffixes[] = { "mp3", "mp2", NULL };
static const char *mp3_mimeTypes[] = { "audio/mpeg", NULL };
InputPlugin mp3Plugin = {
"mp3",
mp3_plugin_init,
NULL,
NULL,
mp3_decode,
NULL,
mp3_tagDup,
INPUT_PLUGIN_STREAM_FILE | INPUT_PLUGIN_STREAM_URL,
mp3_suffixes,
mp3_mimeTypes
};
#else
InputPlugin mp3Plugin;
#endif /* HAVE_MAD */