/*
* Copyright (C) 2003-2013 The Music Player Daemon Project
* 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.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
/* \file
*
* This plugin decodes DSDIFF data (SACD) embedded in DSF files.
*
* The DSF code was created using the specification found here:
* http://dsd-guide.com/sonys-dsf-file-format-spec
*
* All functions common to both DSD decoders have been moved to dsdlib
*/
#include "config.h"
#include "DsfDecoderPlugin.hxx"
#include "DecoderAPI.hxx"
#include "InputStream.hxx"
#include "CheckAudioFormat.hxx"
#include "util/bit_reverse.h"
#include "util/Error.hxx"
#include "DsdLib.hxx"
#include "tag/TagHandler.hxx"
#include <unistd.h>
#include <stdio.h> /* for SEEK_SET, SEEK_CUR */
#undef G_LOG_DOMAIN
#define G_LOG_DOMAIN "dsf"
struct DsfMetaData {
unsigned sample_rate, channels;
bool bitreverse;
uint64_t chunk_size;
#ifdef HAVE_ID3TAG
goffset id3_offset;
uint64_t id3_size;
#endif
};
struct DsfHeader {
/** DSF header id: "DSD " */
struct dsdlib_id id;
/** DSD chunk size, including id = 28 */
uint32_t size_low, size_high;
/** total file size */
uint32_t fsize_low, fsize_high;
/** pointer to id3v2 metadata, should be at the end of the file */
uint32_t pmeta_low, pmeta_high;
};
/** DSF file fmt chunk */
struct DsfFmtChunk {
/** id: "fmt " */
struct dsdlib_id id;
/** fmt chunk size, including id, normally 52 */
uint32_t size_low, size_high;
/** version of this format = 1 */
uint32_t version;
/** 0: DSD raw */
uint32_t formatid;
/** channel type, 1 = mono, 2 = stereo, 3 = 3 channels, etc */
uint32_t channeltype;
/** Channel number, 1 = mono, 2 = stereo, ... 6 = 6 channels */
uint32_t channelnum;
/** sample frequency: 2822400, 5644800 */
uint32_t sample_freq;
/** bits per sample 1 or 8 */
uint32_t bitssample;
/** Sample count per channel in bytes */
uint32_t scnt_low, scnt_high;
/** block size per channel = 4096 */
uint32_t block_size;
/** reserved, should be all zero */
uint32_t reserved;
};
struct DsfDataChunk {
struct dsdlib_id id;
/** "data" chunk size, includes header (id+size) */
uint32_t size_low, size_high;
};
/**
* Read and parse all needed metadata chunks for DSF files.
*/
static bool
dsf_read_metadata(struct decoder *decoder, struct input_stream *is,
DsfMetaData *metadata)
{
uint64_t chunk_size;
DsfHeader dsf_header;
if (!dsdlib_read(decoder, is, &dsf_header, sizeof(dsf_header)) ||
!dsdlib_id_equals(&dsf_header.id, "DSD "))
return false;
chunk_size = (((uint64_t)GUINT32_FROM_LE(dsf_header.size_high)) << 32) |
((uint64_t)GUINT32_FROM_LE(dsf_header.size_low));
if (sizeof(dsf_header) != chunk_size)
return false;
#ifdef HAVE_ID3TAG
uint64_t metadata_offset;
metadata_offset = (((uint64_t)GUINT32_FROM_LE(dsf_header.pmeta_high)) << 32) |
((uint64_t)GUINT32_FROM_LE(dsf_header.pmeta_low));
#endif
/* read the 'fmt ' chunk of the DSF file */
DsfFmtChunk dsf_fmt_chunk;
if (!dsdlib_read(decoder, is, &dsf_fmt_chunk, sizeof(dsf_fmt_chunk)) ||
!dsdlib_id_equals(&dsf_fmt_chunk.id, "fmt "))
return false;
uint64_t fmt_chunk_size;
fmt_chunk_size = (((uint64_t)GUINT32_FROM_LE(dsf_fmt_chunk.size_high)) << 32) |
((uint64_t)GUINT32_FROM_LE(dsf_fmt_chunk.size_low));
if (fmt_chunk_size != sizeof(dsf_fmt_chunk))
return false;
uint32_t samplefreq = (uint32_t)GUINT32_FROM_LE(dsf_fmt_chunk.sample_freq);
/* for now, only support version 1 of the standard, DSD raw stereo
files with a sample freq of 2822400 Hz */
if (dsf_fmt_chunk.version != 1 || dsf_fmt_chunk.formatid != 0
|| dsf_fmt_chunk.channeltype != 2
|| dsf_fmt_chunk.channelnum != 2
|| samplefreq != 2822400)
return false;
uint32_t chblksize = (uint32_t)GUINT32_FROM_LE(dsf_fmt_chunk.block_size);
/* according to the spec block size should always be 4096 */
if (chblksize != 4096)
return false;
/* read the 'data' chunk of the DSF file */
DsfDataChunk data_chunk;
if (!dsdlib_read(decoder, is, &data_chunk, sizeof(data_chunk)) ||
!dsdlib_id_equals(&data_chunk.id, "data"))
return false;
/* data size of DSF files are padded to multiple of 4096,
we use the actual data size as chunk size */
uint64_t data_size;
data_size = (((uint64_t)GUINT32_FROM_LE(data_chunk.size_high)) << 32) |
((uint64_t)GUINT32_FROM_LE(data_chunk.size_low));
data_size -= sizeof(data_chunk);
metadata->chunk_size = data_size;
/* data_size cannot be bigger or equal to total file size */
const uint64_t size = (uint64_t)is->GetSize();
if (data_size >= size)
return false;
metadata->channels = (unsigned) dsf_fmt_chunk.channelnum;
metadata->sample_rate = samplefreq;
#ifdef HAVE_ID3TAG
/* metada_offset cannot be bigger then or equal to total file size */
if (metadata_offset >= size)
metadata->id3_offset = 0;
else
metadata->id3_offset = (goffset) metadata_offset;
#endif
/* check bits per sample format, determine if bitreverse is needed */
metadata->bitreverse = dsf_fmt_chunk.bitssample == 1;
return true;
}
static void
bit_reverse_buffer(uint8_t *p, uint8_t *end)
{
for (; p < end; ++p)
*p = bit_reverse(*p);
}
/**
* DSF data is build up of alternating 4096 blocks of DSD samples for left and
* right. Convert the buffer holding 1 block of 4096 DSD left samples and 1
* block of 4096 DSD right samples to 8k of samples in normal PCM left/right
* order.
*/
static void
dsf_to_pcm_order(uint8_t *dest, uint8_t *scratch, size_t nrbytes)
{
for (unsigned i = 0, j = 0; i < (unsigned)nrbytes; i += 2) {
scratch[i] = *(dest+j);
j++;
}
for (unsigned i = 1, j = 0; i < (unsigned) nrbytes; i += 2) {
scratch[i] = *(dest+4096+j);
j++;
}
for (unsigned i = 0; i < (unsigned)nrbytes; i++) {
*dest = scratch[i];
dest++;
}
}
/**
* Decode one complete DSF 'data' chunk i.e. a complete song
*/
static bool
dsf_decode_chunk(struct decoder *decoder, struct input_stream *is,
unsigned channels,
uint64_t chunk_size,
bool bitreverse)
{
uint8_t buffer[8192];
/* scratch buffer for DSF samples to convert to the needed
normal left/right regime of samples */
uint8_t dsf_scratch_buffer[8192];
const size_t sample_size = sizeof(buffer[0]);
const size_t frame_size = channels * sample_size;
const unsigned buffer_frames = sizeof(buffer) / frame_size;
const unsigned buffer_samples = buffer_frames * frame_size;
const size_t buffer_size = buffer_samples * sample_size;
while (chunk_size > 0) {
/* see how much aligned data from the remaining chunk
fits into the local buffer */
unsigned now_frames = buffer_frames;
size_t now_size = buffer_size;
if (chunk_size < (uint64_t)now_size) {
now_frames = (unsigned)chunk_size / frame_size;
now_size = now_frames * frame_size;
}
size_t nbytes = decoder_read(decoder, is, buffer, now_size);
if (nbytes != now_size)
return false;
chunk_size -= nbytes;
if (bitreverse)
bit_reverse_buffer(buffer, buffer + nbytes);
dsf_to_pcm_order(buffer, dsf_scratch_buffer, nbytes);
const auto cmd = decoder_data(decoder, is, buffer, nbytes, 0);
switch (cmd) {
case DecoderCommand::NONE:
break;
case DecoderCommand::START:
case DecoderCommand::STOP:
return false;
case DecoderCommand::SEEK:
/* not implemented yet */
decoder_seek_error(decoder);
break;
}
}
return dsdlib_skip(decoder, is, chunk_size);
}
static void
dsf_stream_decode(struct decoder *decoder, struct input_stream *is)
{
/* check if it is a proper DSF file */
DsfMetaData metadata;
if (!dsf_read_metadata(decoder, is, &metadata))
return;
Error error;
AudioFormat audio_format;
if (!audio_format_init_checked(audio_format, metadata.sample_rate / 8,
SampleFormat::DSD,
metadata.channels, error)) {
g_warning("%s", error.GetMessage());
return;
}
/* Calculate song time from DSD chunk size and sample frequency */
uint64_t chunk_size = metadata.chunk_size;
float songtime = ((chunk_size / metadata.channels) * 8) /
(float) metadata.sample_rate;
/* success: file was recognized */
decoder_initialized(decoder, audio_format, false, songtime);
if (!dsf_decode_chunk(decoder, is, metadata.channels,
chunk_size,
metadata.bitreverse))
return;
}
static bool
dsf_scan_stream(struct input_stream *is,
gcc_unused const struct tag_handler *handler,
gcc_unused void *handler_ctx)
{
/* check DSF metadata */
DsfMetaData metadata;
if (!dsf_read_metadata(NULL, is, &metadata))
return false;
AudioFormat audio_format;
if (!audio_format_init_checked(audio_format, metadata.sample_rate / 8,
SampleFormat::DSD,
metadata.channels, IgnoreError()))
/* refuse to parse files which we cannot play anyway */
return false;
/* calculate song time and add as tag */
unsigned songtime = ((metadata.chunk_size / metadata.channels) * 8) /
metadata.sample_rate;
tag_handler_invoke_duration(handler, handler_ctx, songtime);
#ifdef HAVE_ID3TAG
/* Add available tags from the ID3 tag */
dsdlib_tag_id3(is, handler, handler_ctx, metadata.id3_offset);
#endif
return true;
}
static const char *const dsf_suffixes[] = {
"dsf",
NULL
};
static const char *const dsf_mime_types[] = {
"application/x-dsf",
NULL
};
const struct decoder_plugin dsf_decoder_plugin = {
"dsf",
nullptr,
nullptr,
dsf_stream_decode,
nullptr,
nullptr,
dsf_scan_stream,
nullptr,
dsf_suffixes,
dsf_mime_types,
};