/*
* Copyright (C) 2003-2014 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.
*/
#include "config.h"
#include "WavpackDecoderPlugin.hxx"
#include "../DecoderAPI.hxx"
#include "input/InputStream.hxx"
#include "CheckAudioFormat.hxx"
#include "tag/TagHandler.hxx"
#include "tag/ApeTag.hxx"
#include "fs/Path.hxx"
#include "util/Error.hxx"
#include "util/Domain.hxx"
#include "util/Macros.hxx"
#include "Log.hxx"
#include <wavpack/wavpack.h>
#include <glib.h>
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#define ERRORLEN 80
static constexpr Domain wavpack_domain("wavpack");
/** A pointer type for format converter function. */
typedef void (*format_samples_t)(
int bytes_per_sample,
void *buffer, uint32_t count
);
/*
* This function has been borrowed from the tiny player found on
* wavpack.com. Modifications were required because mpd only handles
* max 24-bit samples.
*/
static void
format_samples_int(int bytes_per_sample, void *buffer, uint32_t count)
{
int32_t *src = (int32_t *)buffer;
switch (bytes_per_sample) {
case 1: {
int8_t *dst = (int8_t *)buffer;
/*
* The asserts like the following one are because we do the
* formatting of samples within a single buffer. The size
* of the output samples never can be greater than the size
* of the input ones. Otherwise we would have an overflow.
*/
static_assert(sizeof(*dst) <= sizeof(*src), "Wrong size");
/* pass through and align 8-bit samples */
while (count--) {
*dst++ = *src++;
}
break;
}
case 2: {
uint16_t *dst = (uint16_t *)buffer;
static_assert(sizeof(*dst) <= sizeof(*src), "Wrong size");
/* pass through and align 16-bit samples */
while (count--) {
*dst++ = *src++;
}
break;
}
case 3:
case 4:
/* do nothing */
break;
}
}
/*
* This function converts floating point sample data to 24-bit integer.
*/
static void
format_samples_float(gcc_unused int bytes_per_sample, void *buffer,
uint32_t count)
{
float *p = (float *)buffer;
while (count--) {
*p /= (1 << 23);
++p;
}
}
/**
* Choose a MPD sample format from libwavpacks' number of bits.
*/
static SampleFormat
wavpack_bits_to_sample_format(bool is_float, int bytes_per_sample)
{
if (is_float)
return SampleFormat::FLOAT;
switch (bytes_per_sample) {
case 1:
return SampleFormat::S8;
case 2:
return SampleFormat::S16;
case 3:
return SampleFormat::S24_P32;
case 4:
return SampleFormat::S32;
default:
return SampleFormat::UNDEFINED;
}
}
/*
* This does the main decoding thing.
* Requires an already opened WavpackContext.
*/
static void
wavpack_decode(Decoder &decoder, WavpackContext *wpc, bool can_seek)
{
bool is_float = (WavpackGetMode(wpc) & MODE_FLOAT) != 0;
SampleFormat sample_format =
wavpack_bits_to_sample_format(is_float,
WavpackGetBytesPerSample(wpc));
Error error;
AudioFormat audio_format;
if (!audio_format_init_checked(audio_format,
WavpackGetSampleRate(wpc),
sample_format,
WavpackGetNumChannels(wpc), error)) {
LogError(error);
return;
}
const format_samples_t format_samples = is_float
? format_samples_float
: format_samples_int;
const float total_time = float(WavpackGetNumSamples(wpc))
/ audio_format.sample_rate;
const int bytes_per_sample = WavpackGetBytesPerSample(wpc);
const int output_sample_size = audio_format.GetFrameSize();
/* wavpack gives us all kind of samples in a 32-bit space */
int32_t chunk[1024];
const uint32_t samples_requested = ARRAY_SIZE(chunk) /
audio_format.channels;
decoder_initialized(decoder, audio_format, can_seek, total_time);
DecoderCommand cmd = decoder_get_command(decoder);
while (cmd != DecoderCommand::STOP) {
if (cmd == DecoderCommand::SEEK) {
if (can_seek) {
unsigned where = decoder_seek_where(decoder) *
audio_format.sample_rate;
if (WavpackSeekSample(wpc, where)) {
decoder_command_finished(decoder);
} else {
decoder_seek_error(decoder);
}
} else {
decoder_seek_error(decoder);
}
}
uint32_t samples_got = WavpackUnpackSamples(wpc, chunk,
samples_requested);
if (samples_got == 0)
break;
int bitrate = (int)(WavpackGetInstantBitrate(wpc) / 1000 +
0.5);
format_samples(bytes_per_sample, chunk,
samples_got * audio_format.channels);
cmd = decoder_data(decoder, nullptr, chunk,
samples_got * output_sample_size,
bitrate);
}
}
/**
* Locate and parse a floating point tag. Returns true if it was
* found.
*/
static bool
wavpack_tag_float(WavpackContext *wpc, const char *key, float *value_r)
{
char buffer[64];
if (WavpackGetTagItem(wpc, key, buffer, sizeof(buffer)) <= 0)
return false;
*value_r = atof(buffer);
return true;
}
static bool
wavpack_replaygain(ReplayGainInfo &rgi,
WavpackContext *wpc)
{
rgi.Clear();
bool found = false;
found |= wavpack_tag_float(wpc, "replaygain_track_gain",
&rgi.tuples[REPLAY_GAIN_TRACK].gain);
found |= wavpack_tag_float(wpc, "replaygain_track_peak",
&rgi.tuples[REPLAY_GAIN_TRACK].peak);
found |= wavpack_tag_float(wpc, "replaygain_album_gain",
&rgi.tuples[REPLAY_GAIN_ALBUM].gain);
found |= wavpack_tag_float(wpc, "replaygain_album_peak",
&rgi.tuples[REPLAY_GAIN_ALBUM].peak);
return found;
}
static void
wavpack_scan_tag_item(WavpackContext *wpc, const char *name,
TagType type,
const struct tag_handler *handler, void *handler_ctx)
{
char buffer[1024];
int len = WavpackGetTagItem(wpc, name, buffer, sizeof(buffer));
if (len <= 0 || (unsigned)len >= sizeof(buffer))
return;
tag_handler_invoke_tag(handler, handler_ctx, type, buffer);
}
static void
wavpack_scan_pair(WavpackContext *wpc, const char *name,
const struct tag_handler *handler, void *handler_ctx)
{
char buffer[8192];
int len = WavpackGetTagItem(wpc, name, buffer, sizeof(buffer));
if (len <= 0 || (unsigned)len >= sizeof(buffer))
return;
tag_handler_invoke_pair(handler, handler_ctx, name, buffer);
}
/*
* Reads metainfo from the specified file.
*/
static bool
wavpack_scan_file(Path path_fs,
const struct tag_handler *handler, void *handler_ctx)
{
char error[ERRORLEN];
WavpackContext *wpc = WavpackOpenFileInput(path_fs.c_str(), error,
OPEN_TAGS, 0);
if (wpc == nullptr) {
FormatError(wavpack_domain,
"failed to open WavPack file \"%s\": %s",
path_fs.c_str(), error);
return false;
}
tag_handler_invoke_duration(handler, handler_ctx,
WavpackGetNumSamples(wpc) /
WavpackGetSampleRate(wpc));
/* the WavPack format implies APEv2 tags, which means we can
reuse the mapping from tag_ape.c */
for (unsigned i = 0; i < TAG_NUM_OF_ITEM_TYPES; ++i) {
const char *name = tag_item_names[i];
if (name != nullptr)
wavpack_scan_tag_item(wpc, name, (TagType)i,
handler, handler_ctx);
}
for (const struct tag_table *i = ape_tags; i->name != nullptr; ++i)
wavpack_scan_tag_item(wpc, i->name, i->type,
handler, handler_ctx);
if (handler->pair != nullptr) {
char name[64];
for (int i = 0, n = WavpackGetNumTagItems(wpc);
i < n; ++i) {
int len = WavpackGetTagItemIndexed(wpc, i, name,
sizeof(name));
if (len <= 0 || (unsigned)len >= sizeof(name))
continue;
wavpack_scan_pair(wpc, name, handler, handler_ctx);
}
}
WavpackCloseFile(wpc);
return true;
}
/*
* mpd input_stream <=> WavpackStreamReader wrapper callbacks
*/
/* This struct is needed for per-stream last_byte storage. */
struct WavpackInput {
Decoder &decoder;
InputStream &is;
/* Needed for push_back_byte() */
int last_byte;
constexpr WavpackInput(Decoder &_decoder, InputStream &_is)
:decoder(_decoder), is(_is), last_byte(EOF) {}
int32_t ReadBytes(void *data, size_t bcount);
};
/**
* Little wrapper for struct WavpackInput to cast from void *.
*/
static WavpackInput *
wpin(void *id)
{
assert(id);
return (WavpackInput *)id;
}
static int32_t
wavpack_input_read_bytes(void *id, void *data, int32_t bcount)
{
return wpin(id)->ReadBytes(data, bcount);
}
int32_t
WavpackInput::ReadBytes(void *data, size_t bcount)
{
uint8_t *buf = (uint8_t *)data;
int32_t i = 0;
if (last_byte != EOF) {
*buf++ = last_byte;
last_byte = EOF;
--bcount;
++i;
}
/* wavpack fails if we return a partial read, so we just wait
until the buffer is full */
while (bcount > 0) {
size_t nbytes = decoder_read(&decoder, is, buf, bcount);
if (nbytes == 0) {
/* EOF, error or a decoder command */
break;
}
i += nbytes;
bcount -= nbytes;
buf += nbytes;
}
return i;
}
static uint32_t
wavpack_input_get_pos(void *id)
{
return wpin(id)->is.GetOffset();
}
static int
wavpack_input_set_pos_abs(void *id, uint32_t pos)
{
return wpin(id)->is.LockSeek(pos, SEEK_SET, IgnoreError()) ? 0 : -1;
}
static int
wavpack_input_set_pos_rel(void *id, int32_t delta, int mode)
{
return wpin(id)->is.LockSeek(delta, mode, IgnoreError()) ? 0 : -1;
}
static int
wavpack_input_push_back_byte(void *id, int c)
{
if (wpin(id)->last_byte == EOF) {
wpin(id)->last_byte = c;
return c;
} else {
return EOF;
}
}
static uint32_t
wavpack_input_get_length(void *id)
{
if (!wpin(id)->is.KnownSize())
return 0;
return wpin(id)->is.GetSize();
}
static int
wavpack_input_can_seek(void *id)
{
return wpin(id)->is.IsSeekable();
}
static WavpackStreamReader mpd_is_reader = {
wavpack_input_read_bytes,
wavpack_input_get_pos,
wavpack_input_set_pos_abs,
wavpack_input_set_pos_rel,
wavpack_input_push_back_byte,
wavpack_input_get_length,
wavpack_input_can_seek,
nullptr /* no need to write edited tags */
};
static WavpackInput *
wavpack_open_wvc(Decoder &decoder, const char *uri)
{
/*
* As we use dc->utf8url, this function will be bad for
* single files. utf8url is not absolute file path :/
*/
if (uri == nullptr)
return nullptr;
char *wvc_url = g_strconcat(uri, "c", nullptr);
InputStream *is_wvc = decoder_open_uri(decoder, uri, IgnoreError());
g_free(wvc_url);
if (is_wvc == nullptr)
return nullptr;
return new WavpackInput(decoder, *is_wvc);
}
/*
* Decodes a stream.
*/
static void
wavpack_streamdecode(Decoder &decoder, InputStream &is)
{
int open_flags = OPEN_NORMALIZE;
bool can_seek = is.IsSeekable();
WavpackInput *wvc = wavpack_open_wvc(decoder, is.GetURI());
if (wvc != nullptr) {
open_flags |= OPEN_WVC;
can_seek &= wvc->is.IsSeekable();
}
if (!can_seek) {
open_flags |= OPEN_STREAMING;
}
WavpackInput isp(decoder, is);
char error[ERRORLEN];
WavpackContext *wpc =
WavpackOpenFileInputEx(&mpd_is_reader, &isp, wvc,
error, open_flags, 23);
if (wpc == nullptr) {
FormatError(wavpack_domain,
"failed to open WavPack stream: %s", error);
return;
}
wavpack_decode(decoder, wpc, can_seek);
WavpackCloseFile(wpc);
if (wvc != nullptr) {
delete &wvc->is;
delete wvc;
}
}
/*
* Decodes a file.
*/
static void
wavpack_filedecode(Decoder &decoder, Path path_fs)
{
char error[ERRORLEN];
WavpackContext *wpc = WavpackOpenFileInput(path_fs.c_str(), error,
OPEN_TAGS | OPEN_WVC | OPEN_NORMALIZE,
23);
if (wpc == nullptr) {
FormatWarning(wavpack_domain,
"failed to open WavPack file \"%s\": %s",
path_fs.c_str(), error);
return;
}
ReplayGainInfo rgi;
if (wavpack_replaygain(rgi, wpc))
decoder_replay_gain(decoder, &rgi);
wavpack_decode(decoder, wpc, true);
WavpackCloseFile(wpc);
}
static char const *const wavpack_suffixes[] = {
"wv",
nullptr
};
static char const *const wavpack_mime_types[] = {
"audio/x-wavpack",
nullptr
};
const struct DecoderPlugin wavpack_decoder_plugin = {
"wavpack",
nullptr,
nullptr,
wavpack_streamdecode,
wavpack_filedecode,
wavpack_scan_file,
nullptr,
nullptr,
wavpack_suffixes,
wavpack_mime_types
};