sm64coopdx/tools/audiofile-0.3.6/libaudiofile/CAF.cpp

725 lines
18 KiB
C++

/*
Audio File Library
Copyright (C) 2011-2013, Michael Pruett <michael@68k.org>
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library 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
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the
Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301 USA
*/
#include "config.h"
#include "CAF.h"
#include "Buffer.h"
#include "File.h"
#include "PacketTable.h"
#include "Setup.h"
#include "Tag.h"
#include "Track.h"
#include "byteorder.h"
#include "util.h"
#include <stdint.h>
#include <string.h>
#include <string>
#include <vector>
const int _af_caf_compression_types[_AF_CAF_NUM_COMPTYPES] =
{
AF_COMPRESSION_G711_ULAW,
AF_COMPRESSION_G711_ALAW,
AF_COMPRESSION_IMA,
AF_COMPRESSION_ALAC
};
enum
{
kCAFLinearPCMFormatFlagIsFloat = (1L << 0),
kCAFLinearPCMFormatFlagIsLittleEndian = (1L << 1)
};
enum
{
kALACFormatFlag_16BitSourceData = 1,
kALACFormatFlag_20BitSourceData = 2,
kALACFormatFlag_24BitSourceData = 3,
kALACFormatFlag_32BitSourceData = 4
};
static const unsigned kALACDefaultFramesPerPacket = 4096;
static const _AFfilesetup cafDefaultFileSetup =
{
_AF_VALID_FILESETUP, // valid
AF_FILE_CAF, // fileFormat
true, // trackSet
true, // instrumentSet
true, // miscellaneousSet
1, // trackCount
NULL, // tracks
1, // instrumentCount
NULL, // instruments
0, // miscellaneousCount
NULL // miscellaneous
};
CAFFile::CAFFile() :
m_dataOffset(-1),
m_cookieDataOffset(-1)
{
setFormatByteOrder(AF_BYTEORDER_BIGENDIAN);
}
CAFFile::~CAFFile()
{
}
bool CAFFile::recognize(File *file)
{
file->seek(0, File::SeekFromBeginning);
uint8_t buffer[8];
if (file->read(buffer, 8) != 8 || memcmp(buffer, "caff", 4) != 0)
return false;
const uint8_t versionAndFlags[4] = { 0, 1, 0, 0 };
if (memcmp(buffer + 4, versionAndFlags, 4) != 0)
return false;
return true;
}
status CAFFile::readInit(AFfilesetup setup)
{
m_fh->seek(8, File::SeekFromBeginning);
if (!allocateTrack())
return AF_FAIL;
off_t currentOffset = m_fh->tell();
off_t fileLength = m_fh->length();
while (currentOffset < fileLength)
{
Tag chunkType;
int64_t chunkLength;
if (!readTag(&chunkType) ||
!readS64(&chunkLength))
return AF_FAIL;
currentOffset += 12;
if (chunkType == "data" && chunkLength == -1)
chunkLength = fileLength - currentOffset;
else if (chunkLength < 0)
_af_error(AF_BAD_HEADER,
"invalid chunk length %jd for chunk type %s\n",
static_cast<intmax_t>(chunkLength), chunkType.name().c_str());
if (chunkType == "desc")
{
if (parseDescription(chunkType, chunkLength) == AF_FAIL)
return AF_FAIL;
}
else if (chunkType == "data")
{
if (parseData(chunkType, chunkLength) == AF_FAIL)
return AF_FAIL;
}
else if (chunkType == "pakt")
{
if (parsePacketTable(chunkType, chunkLength) == AF_FAIL)
return AF_FAIL;
}
else if (chunkType == "kuki")
{
if (parseCookieData(chunkType, chunkLength) == AF_FAIL)
return AF_FAIL;
}
currentOffset = m_fh->seek(currentOffset + chunkLength,
File::SeekFromBeginning);
}
return AF_SUCCEED;
}
status CAFFile::writeInit(AFfilesetup setup)
{
if (initFromSetup(setup) == AF_FAIL)
return AF_FAIL;
initCompressionParams();
Tag caff("caff");
if (!writeTag(&caff)) return AF_FAIL;
const uint8_t versionAndFlags[4] = { 0, 1, 0, 0 };
if (m_fh->write(versionAndFlags, 4) != 4) return AF_FAIL;
if (writeDescription() == AF_FAIL)
return AF_FAIL;
if (writeCookieData() == AF_FAIL)
return AF_FAIL;
if (writeData(false) == AF_FAIL)
return AF_FAIL;
return AF_SUCCEED;
}
AFfilesetup CAFFile::completeSetup(AFfilesetup setup)
{
if (setup->trackSet && setup->trackCount != 1)
{
_af_error(AF_BAD_NUMTRACKS, "CAF file must have 1 track");
return AF_NULL_FILESETUP;
}
TrackSetup *track = &setup->tracks[0];
if (track->sampleFormatSet)
{
if (track->f.isUnsigned())
{
_af_error(AF_BAD_FILEFMT, "CAF format does not support unsigned data");
return AF_NULL_FILESETUP;
}
}
else
_af_set_sample_format(&track->f, AF_SAMPFMT_TWOSCOMP,
track->f.sampleWidth);
if (track->f.isSigned() && (track->f.sampleWidth < 1 || track->f.sampleWidth > 32))
{
_af_error(AF_BAD_WIDTH,
"invalid sample width %d for CAF file (must be 1-32)",
track->f.sampleWidth);
return AF_NULL_FILESETUP;
}
if (!track->byteOrderSet)
track->f.byteOrder = _AF_BYTEORDER_NATIVE;
if (track->f.compressionType != AF_COMPRESSION_NONE &&
track->f.compressionType != AF_COMPRESSION_G711_ULAW &&
track->f.compressionType != AF_COMPRESSION_G711_ALAW &&
track->f.compressionType != AF_COMPRESSION_IMA &&
track->f.compressionType != AF_COMPRESSION_ALAC)
{
_af_error(AF_BAD_COMPTYPE,
"compression format %d not supported in CAF file",
track->f.compressionType);
return AF_NULL_FILESETUP;
}
if (track->markersSet && track->markerCount)
{
_af_error(AF_BAD_NOT_IMPLEMENTED, "CAF does not yet support markers");
return AF_NULL_FILESETUP;
}
if (track->aesDataSet)
{
_af_error(AF_BAD_FILESETUP, "CAF does not support AES data");
return AF_NULL_FILESETUP;
}
return _af_filesetup_copy(setup, &cafDefaultFileSetup, true);
}
status CAFFile::update()
{
if (writeCookieData() == AF_FAIL)
return AF_FAIL;
if (writeData(true) == AF_FAIL)
return AF_FAIL;
if (writePacketTable() == AF_FAIL)
return AF_FAIL;
return AF_SUCCEED;
}
status CAFFile::parseDescription(const Tag &, int64_t)
{
double sampleRate;
Tag formatID;
uint32_t formatFlags;
uint32_t bytesPerPacket;
uint32_t framesPerPacket;
uint32_t channelsPerFrame;
uint32_t bitsPerChannel;
if (!readDouble(&sampleRate) ||
!readTag(&formatID) ||
!readU32(&formatFlags) ||
!readU32(&bytesPerPacket) ||
!readU32(&framesPerPacket) ||
!readU32(&channelsPerFrame) ||
!readU32(&bitsPerChannel))
return AF_FAIL;
if (!channelsPerFrame)
{
_af_error(AF_BAD_CHANNELS, "invalid file with 0 channels");
return AF_FAIL;
}
Track *track = getTrack();
track->f.channelCount = channelsPerFrame;
track->f.sampleWidth = bitsPerChannel;
track->f.sampleRate = sampleRate;
track->f.framesPerPacket = 1;
if (formatID == "lpcm")
{
track->f.compressionType = AF_COMPRESSION_NONE;
if (formatFlags & kCAFLinearPCMFormatFlagIsFloat)
{
if (bitsPerChannel != 32 && bitsPerChannel != 64)
{
_af_error(AF_BAD_WIDTH, "invalid bits per sample %d for floating-point audio data", bitsPerChannel);
return AF_FAIL;
}
track->f.sampleFormat = bitsPerChannel == 32 ? AF_SAMPFMT_FLOAT :
AF_SAMPFMT_DOUBLE;
}
else
{
track->f.sampleFormat = AF_SAMPFMT_TWOSCOMP;
}
track->f.byteOrder = (formatFlags & kCAFLinearPCMFormatFlagIsLittleEndian) ?
AF_BYTEORDER_LITTLEENDIAN : AF_BYTEORDER_BIGENDIAN;
if (_af_set_sample_format(&track->f, track->f.sampleFormat, track->f.sampleWidth) == AF_FAIL)
return AF_FAIL;
track->f.computeBytesPerPacketPCM();
return AF_SUCCEED;
}
else if (formatID == "ulaw")
{
track->f.compressionType = AF_COMPRESSION_G711_ULAW;
track->f.byteOrder = _AF_BYTEORDER_NATIVE;
_af_set_sample_format(&track->f, AF_SAMPFMT_TWOSCOMP, 16);
track->f.bytesPerPacket = channelsPerFrame;
return AF_SUCCEED;
}
else if (formatID == "alaw")
{
track->f.compressionType = AF_COMPRESSION_G711_ALAW;
track->f.byteOrder = _AF_BYTEORDER_NATIVE;
_af_set_sample_format(&track->f, AF_SAMPFMT_TWOSCOMP, 16);
track->f.bytesPerPacket = channelsPerFrame;
return AF_SUCCEED;
}
else if (formatID == "ima4")
{
track->f.compressionType = AF_COMPRESSION_IMA;
track->f.byteOrder = _AF_BYTEORDER_NATIVE;
_af_set_sample_format(&track->f, AF_SAMPFMT_TWOSCOMP, 16);
initIMACompressionParams();
return AF_SUCCEED;
}
else if (formatID == "alac")
{
track->f.compressionType = AF_COMPRESSION_ALAC;
track->f.byteOrder = _AF_BYTEORDER_NATIVE;
switch (formatFlags)
{
case kALACFormatFlag_16BitSourceData:
track->f.sampleWidth = 16; break;
case kALACFormatFlag_20BitSourceData:
track->f.sampleWidth = 20; break;
case kALACFormatFlag_24BitSourceData:
track->f.sampleWidth = 24; break;
case kALACFormatFlag_32BitSourceData:
track->f.sampleWidth = 32; break;
default:
_af_error(AF_BAD_CODEC_TYPE,
"unsupported format flags for ALAC: %u", formatFlags);
return AF_FAIL;
}
_af_set_sample_format(&track->f, AF_SAMPFMT_TWOSCOMP,
track->f.sampleWidth);
track->f.framesPerPacket = framesPerPacket;
track->f.bytesPerPacket = 0;
return AF_SUCCEED;
}
else
{
_af_error(AF_BAD_NOT_IMPLEMENTED, "Compression type %s not supported",
formatID.name().c_str());
return AF_FAIL;
}
}
status CAFFile::parseData(const Tag &tag, int64_t length)
{
uint32_t editCount;
if (!readU32(&editCount))
return AF_FAIL;
Track *track = getTrack();
if (length == -1)
track->data_size = m_fh->length() - m_fh->tell();
else
track->data_size = length - 4;
track->fpos_first_frame = m_fh->tell();
track->computeTotalFileFrames();
return AF_SUCCEED;
}
static uint32_t readBERInteger(const uint8_t *input, size_t *numBytes)
{
uint32_t result = 0;
uint8_t data;
size_t size = 0;
do
{
data = input[size];
result = (result << 7) | (data & 0x7f);
if (++size > 5)
return 0;
} while ((data & 0x80) && size < *numBytes);
*numBytes = size;
return result;
}
static void encodeBERInteger(uint32_t value, uint8_t *buffer, size_t *numBytes)
{
if ((value & 0x7f) == value)
{
*numBytes = 1;
buffer[0] = value;
}
else if ((value & 0x3fff) == value)
{
*numBytes = 2;
buffer[0] = (value >> 7) | 0x80;
buffer[1] = value & 0x7f;
}
else if ((value & 0x1fffff) == value)
{
*numBytes = 3;
buffer[0] = (value >> 14) | 0x80;
buffer[1] = ((value >> 7) & 0x7f) | 0x80;
buffer[2] = value & 0x7f;
}
else if ((value & 0x0fffffff) == value)
{
*numBytes = 4;
buffer[0] = (value >> 21) | 0x80;
buffer[1] = ((value >> 14) & 0x7f) | 0x80;
buffer[2] = ((value >> 7) & 0x7f) | 0x80;
buffer[3] = value & 0x7f;
}
else
{
*numBytes = 5;
buffer[0] = (value >> 28) | 0x80;
buffer[1] = ((value >> 21) & 0x7f) | 0x80;
buffer[2] = ((value >> 14) & 0x7f) | 0x80;
buffer[3] = ((value >> 7) & 0x7f) | 0x80;
buffer[4] = value & 0x7f;
}
}
status CAFFile::parsePacketTable(const Tag &tag, int64_t length)
{
if (length < 24)
return AF_FAIL;
int64_t numPackets;
int64_t numValidFrames;
int32_t primingFrames;
int32_t remainderFrames;
if (!readS64(&numPackets) ||
!readS64(&numValidFrames) ||
!readS32(&primingFrames) ||
!readS32(&remainderFrames))
{
return AF_FAIL;
}
if (!numPackets)
return AF_SUCCEED;
int64_t tableLength = length - 24;
SharedPtr<Buffer> buffer = new Buffer(tableLength);
if (m_fh->read(buffer->data(), tableLength) != tableLength)
return AF_FAIL;
SharedPtr<PacketTable> packetTable = new PacketTable(numValidFrames,
primingFrames, remainderFrames);
const uint8_t *data = static_cast<const uint8_t *>(buffer->data());
size_t position = 0;
while (position < buffer->size())
{
size_t sizeRemaining = buffer->size() - position;
uint32_t bytesPerPacket = readBERInteger(data + position, &sizeRemaining);
if (bytesPerPacket == 0)
break;
packetTable->append(bytesPerPacket);
position += sizeRemaining;
}
assert(numPackets == packetTable->numPackets());
Track *track = getTrack();
track->m_packetTable = packetTable;
track->totalfframes = numValidFrames;
return AF_SUCCEED;
}
status CAFFile::parseCookieData(const Tag &tag, int64_t length)
{
m_codecData = new Buffer(length);
if (m_fh->read(m_codecData->data(), length) != length)
return AF_FAIL;
AUpvlist pv = AUpvnew(2);
AUpvsetparam(pv, 0, _AF_CODEC_DATA_SIZE);
AUpvsetvaltype(pv, 0, AU_PVTYPE_LONG);
long l = length;
AUpvsetval(pv, 0, &l);
AUpvsetparam(pv, 1, _AF_CODEC_DATA);
AUpvsetvaltype(pv, 1, AU_PVTYPE_PTR);
void *v = m_codecData->data();
AUpvsetval(pv, 1, &v);
Track *track = getTrack();
track->f.compressionParams = pv;
return AF_SUCCEED;
}
status CAFFile::writeDescription()
{
Track *track = getTrack();
Tag desc("desc");
int64_t chunkLength = 32;
double sampleRate = track->f.sampleRate;
Tag formatID("lpcm");
uint32_t formatFlags = 0;
if (track->f.byteOrder == AF_BYTEORDER_LITTLEENDIAN)
formatFlags |= kCAFLinearPCMFormatFlagIsLittleEndian;
if (track->f.isFloat())
formatFlags |= kCAFLinearPCMFormatFlagIsFloat;
uint32_t bytesPerPacket = track->f.bytesPerFrame(false);
uint32_t framesPerPacket = 1;
uint32_t channelsPerFrame = track->f.channelCount;
uint32_t bitsPerChannel = track->f.sampleWidth;
if (track->f.compressionType == AF_COMPRESSION_G711_ULAW)
{
formatID = "ulaw";
formatFlags = 0;
bytesPerPacket = channelsPerFrame;
bitsPerChannel = 8;
}
else if (track->f.compressionType == AF_COMPRESSION_G711_ALAW)
{
formatID = "alaw";
formatFlags = 0;
bytesPerPacket = channelsPerFrame;
bitsPerChannel = 8;
}
else if (track->f.compressionType == AF_COMPRESSION_IMA)
{
formatID = "ima4";
formatFlags = 0;
bytesPerPacket = track->f.bytesPerPacket;
framesPerPacket = track->f.framesPerPacket;
bitsPerChannel = 16;
}
else if (track->f.compressionType == AF_COMPRESSION_ALAC)
{
formatID = "alac";
switch (track->f.sampleWidth)
{
case 16: formatFlags = kALACFormatFlag_16BitSourceData; break;
case 20: formatFlags = kALACFormatFlag_20BitSourceData; break;
case 24: formatFlags = kALACFormatFlag_24BitSourceData; break;
case 32: formatFlags = kALACFormatFlag_32BitSourceData; break;
}
bytesPerPacket = track->f.bytesPerPacket;
framesPerPacket = track->f.framesPerPacket;
}
if (!writeTag(&desc) ||
!writeS64(&chunkLength) ||
!writeDouble(&sampleRate) ||
!writeTag(&formatID) ||
!writeU32(&formatFlags) ||
!writeU32(&bytesPerPacket) ||
!writeU32(&framesPerPacket) ||
!writeU32(&channelsPerFrame) ||
!writeU32(&bitsPerChannel))
return AF_FAIL;
return AF_SUCCEED;
}
status CAFFile::writeData(bool update)
{
Track *track = getTrack();
if (m_dataOffset == -1)
m_dataOffset = m_fh->tell();
else
m_fh->seek(m_dataOffset, File::SeekFromBeginning);
Tag data("data");
int64_t dataLength = -1;
uint32_t editCount = 0;
if (update)
dataLength = track->data_size + 4;
if (!writeTag(&data) ||
!writeS64(&dataLength) ||
!writeU32(&editCount))
return AF_FAIL;
if (track->fpos_first_frame == 0)
track->fpos_first_frame = m_fh->tell();
return AF_SUCCEED;
}
status CAFFile::writePacketTable()
{
Track *track = getTrack();
m_fh->seek(track->fpos_after_data, File::SeekFromBeginning);
SharedPtr<PacketTable> packetTable = track->m_packetTable;
if (!packetTable)
return AF_SUCCEED;
int64_t numPackets = packetTable->numPackets();
int64_t numValidFrames = packetTable->numValidFrames();
int32_t primingFrames = packetTable->primingFrames();
int32_t remainderFrames = packetTable->remainderFrames();
SharedPtr<Buffer> buffer = new Buffer(packetTable->numPackets() * 5);
uint8_t *data = static_cast<uint8_t *>(buffer->data());
size_t position = 0;
for (unsigned i=0; i<packetTable->numPackets(); i++)
{
uint32_t bytesPerPacket = packetTable->bytesPerPacket(i);
size_t numBytes = 0;
encodeBERInteger(bytesPerPacket, data + position, &numBytes);
position += numBytes;
}
Tag pakt("pakt");
int64_t packetTableLength = 24 + position;
if (!writeTag(&pakt) ||
!writeS64(&packetTableLength) ||
!writeS64(&numPackets) ||
!writeS64(&numValidFrames) ||
!writeS32(&primingFrames) ||
!writeS32(&remainderFrames) ||
m_fh->write(buffer->data(), position) != static_cast<ssize_t>(position))
{
return AF_FAIL;
}
return AF_SUCCEED;
}
status CAFFile::writeCookieData()
{
if (!m_codecData)
return AF_SUCCEED;
if (m_cookieDataOffset == -1)
m_cookieDataOffset = m_fh->tell();
else
m_fh->seek(m_cookieDataOffset, File::SeekFromBeginning);
Tag kuki("kuki");
int64_t cookieDataLength = m_codecData->size();
if (!writeTag(&kuki) ||
!writeS64(&cookieDataLength) ||
m_fh->write(m_codecData->data(), m_codecData->size()) != static_cast<ssize_t>(m_codecData->size()))
{
return AF_FAIL;
}
return AF_SUCCEED;
}
void CAFFile::initCompressionParams()
{
Track *track = getTrack();
if (track->f.compressionType == AF_COMPRESSION_IMA)
initIMACompressionParams();
else if (track->f.compressionType == AF_COMPRESSION_ALAC)
initALACCompressionParams();
}
void CAFFile::initIMACompressionParams()
{
Track *track = getTrack();
track->f.bytesPerPacket = 34 * track->f.channelCount;
track->f.framesPerPacket = 64;
AUpvlist pv = AUpvnew(1);
AUpvsetparam(pv, 0, _AF_IMA_ADPCM_TYPE);
AUpvsetvaltype(pv, 0, AU_PVTYPE_LONG);
long l = _AF_IMA_ADPCM_TYPE_QT;
AUpvsetval(pv, 0, &l);
track->f.compressionParams = pv;
}
void CAFFile::initALACCompressionParams()
{
if (m_access == _AF_READ_ACCESS)
return;
Track *track = getTrack();
track->f.bytesPerPacket = 0;
track->f.framesPerPacket = kALACDefaultFramesPerPacket;
const unsigned kALACSpecificConfigSize = 24;
const unsigned kChannelAtomSize = 12;
const unsigned kALACAudioChannelLayoutSize = 12;
unsigned codecDataSize = kALACSpecificConfigSize;
if (track->f.channelCount > 2)
codecDataSize += kChannelAtomSize + kALACAudioChannelLayoutSize;
m_codecData = new Buffer(codecDataSize);
memset(m_codecData->data(), 0, m_codecData->size());
AUpvlist pv = AUpvnew(2);
AUpvsetparam(pv, 0, _AF_CODEC_DATA_SIZE);
AUpvsetvaltype(pv, 0, AU_PVTYPE_LONG);
long l = codecDataSize;
AUpvsetval(pv, 0, &l);
AUpvsetparam(pv, 1, _AF_CODEC_DATA);
AUpvsetvaltype(pv, 1, AU_PVTYPE_PTR);
void *v = m_codecData->data();
AUpvsetval(pv, 1, &v);
track->f.compressionParams = pv;
track->m_packetTable = new PacketTable();
}