/*
* WAVTools.cpp
* ------------
* Purpose: Definition of WAV file structures and helper functions
* Notes : (currently none)
* Authors: OpenMPT Devs
* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
*/
#include "stdafx.h"
#include "Loaders.h"
#include "WAVTools.h"
#include "Tagging.h"
#include "../common/version.h"
#ifndef MODPLUG_NO_FILESAVE
#include "mpt/io/io.hpp"
#include "mpt/io/io_virtual_wrapper.hpp"
#include "../common/mptFileIO.h"
#endif
OPENMPT_NAMESPACE_BEGIN
///////////////////////////////////////////////////////////
// WAV Reading
WAVReader::WAVReader(FileReader &inputFile) : file(inputFile)
{
file.Rewind();
RIFFHeader fileHeader;
codePage = 28591; // ISO 8859-1
isDLS = false;
subFormat = 0;
mayBeCoolEdit16_8 = false;
if(!file.ReadStruct(fileHeader)
|| (fileHeader.magic != RIFFHeader::idRIFF && fileHeader.magic != RIFFHeader::idLIST)
|| (fileHeader.type != RIFFHeader::idWAVE && fileHeader.type != RIFFHeader::idwave))
{
return;
}
isDLS = (fileHeader.magic == RIFFHeader::idLIST);
auto chunks = file.ReadChunks<RIFFChunk>(2);
if(chunks.chunks.size() >= 4
&& chunks.chunks[1].GetHeader().GetID() == RIFFChunk::iddata
&& chunks.chunks[1].GetHeader().GetLength() % 2u != 0
&& chunks.chunks[2].GetHeader().GetLength() == 0
&& chunks.chunks[3].GetHeader().GetID() == RIFFChunk::id____)
{
// Houston, we have a problem: Old versions of (Open)MPT didn't write RIFF padding bytes. -_-
// Luckily, the only RIFF chunk with an odd size those versions would ever write would be the "data" chunk
// (which contains the sample data), and its size is only odd iff the sample has an odd length and is in
// 8-Bit mono format. In all other cases, the sample size (and thus the chunk size) is even.
// And we're even more lucky: The versions of (Open)MPT in question will always write a relatively small
// (smaller than 256 bytes) "smpl" chunk after the "data" chunk. This means that after an unpadded sample,
// we will always read "mpl?" (? being the length of the "smpl" chunk) as the next chunk magic. The first two
// 32-Bit members of the "smpl" chunk are always zero in our case, so we are going to read a chunk length of 0
// next and the next chunk magic, which will always consist of four zero bytes. Hooray! We just checked for those
// four zero bytes and can be pretty confident that we should not have applied padding.
file.Seek(sizeof(RIFFHeader));
chunks = file.ReadChunks<RIFFChunk>(1);
}
// Read format chunk
FileReader formatChunk = chunks.GetChunk(RIFFChunk::idfmt_);
if(!formatChunk.ReadStruct(formatInfo))
{
return;
}
if(formatInfo.format == WAVFormatChunk::fmtPCM && formatChunk.BytesLeft() == 4)
{
uint16 size = formatChunk.ReadIntLE<uint16>();
uint16 value = formatChunk.ReadIntLE<uint16>();
if(size == 2 && value == 1)
{
// May be Cool Edit 16.8 format.
// See SampleFormats.cpp for details.
mayBeCoolEdit16_8 = true;
}
} else if(formatInfo.format == WAVFormatChunk::fmtExtensible)
{
WAVFormatChunkExtension extFormat;
if(!formatChunk.ReadStruct(extFormat))
{
return;
}
subFormat = static_cast<uint16>(mpt::UUID(extFormat.subFormat).GetData1());
}
// Read sample data
sampleData = chunks.GetChunk(RIFFChunk::iddata);
if(!sampleData.IsValid())
{
// The old IMA ADPCM loader code looked for the "pcm " chunk instead of the "data" chunk...
// Dunno why (Windows XP's audio recorder saves IMA ADPCM files with a "data" chunk), but we will just look for both.
sampleData = chunks.GetChunk(RIFFChunk::idpcm_);
}
// "fact" chunk should contain sample length of compressed samples.
sampleLength = chunks.GetChunk(RIFFChunk::idfact).ReadUint32LE();
if((formatInfo.format != WAVFormatChunk::fmtIMA_ADPCM || sampleLength == 0) && GetSampleSize() != 0)
{
if((GetBlockAlign() == 0) || (GetBlockAlign() / GetNumChannels() >= 2 * GetSampleSize()))
{
// Some samples have an incorrect blockAlign / sample size set (e.g. it's 8 in SQUARE.WAV while it should be 1), so let's better not always trust this value.
// The idea here is, if block align is off by twice or more, it is unlikely to be describing sample padding inside the block.
// Ignore it in this case and calculate the length based on the single sample size and number of channels instead.
sampleLength = sampleData.GetLength() / GetSampleSize();
} else
{
// Correct case (so that 20bit WAVEFORMATEX files work).
sampleLength = sampleData.GetLength() / GetBlockAlign();
}
}
// Determine string encoding
codePage = GetFileCodePage(chunks);
// Check for loop points, texts, etc...
FindMetadataChunks(chunks);
// DLS bank chunk
wsmpChunk = chunks.GetChunk(RIFFChunk::idwsmp);
}
void WAVReader::FindMetadataChunks(FileReader::ChunkList<RIFFChunk> &chunks)
{
// Read sample loop points and other sampler information
smplChunk = chunks.GetChunk(RIFFChunk::idsmpl);
instChunk = chunks.GetChunk(RIFFChunk::idinst);
// Read sample cues
cueChunk = chunks.GetChunk(RIFFChunk::idcue_);
// Read text chunks
FileReader listChunk = chunks.GetChunk(RIFFChunk::idLIST);
if(listChunk.ReadMagic("INFO"))
{
infoChunk = listChunk.ReadChunks<RIFFChunk>(2);
}
// Read MPT sample information
xtraChunk = chunks.GetChunk(RIFFChunk::idxtra);
}
uint16 WAVReader::GetFileCodePage(FileReader::ChunkList<RIFFChunk> &chunks)
{
FileReader csetChunk = chunks.GetChunk(RIFFChunk::idCSET);
if(!csetChunk.IsValid())
{
FileReader iSFT = infoChunk.GetChunk(RIFFChunk::idISFT);
if(iSFT.ReadMagic("OpenMPT"))
{
std::string versionString;
iSFT.ReadString<mpt::String::maybeNullTerminated>(versionString, iSFT.BytesLeft());
versionString = mpt::trim(versionString);
Version version = Version::Parse(mpt::ToUnicode(mpt::Charset::ISO8859_1, versionString));
if(version && version < MPT_V("1.28.00.02"))
{
return 1252; // mpt::Charset::Windows1252; // OpenMPT up to and including 1.28.00.01 wrote metadata in windows-1252 encoding
} else
{
return 28591; // mpt::Charset::ISO8859_1; // as per spec
}
} else
{
return 28591; // mpt::Charset::ISO8859_1; // as per spec
}
}
if(!csetChunk.CanRead(2))
{
// chunk not parsable
return 28591; // mpt::Charset::ISO8859_1;
}
uint16 codepage = csetChunk.ReadUint16LE();
return codepage;
}
void WAVReader::ApplySampleSettings(ModSample &sample, mpt::Charset sampleCharset, mpt::charbuf<MAX_SAMPLENAME> &sampleName)
{
// Read sample name
FileReader textChunk = infoChunk.GetChunk(RIFFChunk::idINAM);
if(textChunk.IsValid())
{
std::string sampleNameEncoded;
textChunk.ReadString<mpt::String::nullTerminated>(sampleNameEncoded, textChunk.GetLength());
sampleName = mpt::ToCharset(sampleCharset, mpt::ToUnicode(codePage, mpt::Charset::Windows1252, sampleNameEncoded));
}
if(isDLS)
{
// DLS sample -> sample filename
sample.filename = sampleName;
}
// Read software name
const bool isOldMPT = infoChunk.GetChunk(RIFFChunk::idISFT).ReadMagic("Modplug Tracker");
// Convert loops
WAVSampleInfoChunk sampleInfo;
smplChunk.Rewind();
if(smplChunk.ReadStruct(sampleInfo))
{
WAVSampleLoop loopData;
if(sampleInfo.numLoops > 1 && smplChunk.ReadStruct(loopData))
{
// First loop: Sustain loop
loopData.ApplyToSample(sample.nSustainStart, sample.nSustainEnd, sample.nLength, sample.uFlags, CHN_SUSTAINLOOP, CHN_PINGPONGSUSTAIN, isOldMPT);
}
// First loop (if only one loop is present) or second loop (if more than one loop is present): Normal sample loop
if(smplChunk.ReadStruct(loopData))
{
loopData.ApplyToSample(sample.nLoopStart, sample.nLoopEnd, sample.nLength, sample.uFlags, CHN_LOOP, CHN_PINGPONGLOOP, isOldMPT);
}
//sample.Transpose((60 - sampleInfo.baseNote) / 12.0);
sample.rootNote = static_cast<uint8>(sampleInfo.baseNote);
if(sample.rootNote < 128)
sample.rootNote += NOTE_MIN;
else
sample.rootNote = NOTE_NONE;
sample.SanitizeLoops();
}
if(sample.rootNote == NOTE_NONE && instChunk.LengthIsAtLeast(sizeof(WAVInstrumentChunk)))
{
WAVInstrumentChunk inst;
instChunk.Rewind();
if(instChunk.ReadStruct(inst))
{
sample.rootNote = inst.unshiftedNote;
if(sample.rootNote < 128)
sample.rootNote += NOTE_MIN;
else
sample.rootNote = NOTE_NONE;
}
}
// Read cue points
if(cueChunk.IsValid())
{
uint32 numPoints = cueChunk.ReadUint32LE();
LimitMax(numPoints, mpt::saturate_cast<uint32>(std::size(sample.cues)));
for(uint32 i = 0; i < numPoints; i++)
{
WAVCuePoint cuePoint;
cueChunk.ReadStruct(cuePoint);
sample.cues[i] = cuePoint.position;
}
std::fill(std::begin(sample.cues) + numPoints, std::end(sample.cues), MAX_SAMPLE_LENGTH);
}
// Read MPT extra info
WAVExtraChunk mptInfo;
xtraChunk.Rewind();
if(xtraChunk.ReadStruct(mptInfo))
{
if(mptInfo.flags & WAVExtraChunk::setPanning) sample.uFlags.set(CHN_PANNING);
sample.nPan = std::min(static_cast<uint16>(mptInfo.defaultPan), uint16(256));
sample.nVolume = std::min(static_cast<uint16>(mptInfo.defaultVolume), uint16(256));
sample.nGlobalVol = std::min(static_cast<uint16>(mptInfo.globalVolume), uint16(64));
sample.nVibType = static_cast<VibratoType>(mptInfo.vibratoType.get());
sample.nVibSweep = mptInfo.vibratoSweep;
sample.nVibDepth = mptInfo.vibratoDepth;
sample.nVibRate = mptInfo.vibratoRate;
if(xtraChunk.CanRead(MAX_SAMPLENAME))
{
// Name present (clipboard only)
// FIXME: When modules can have individual encoding in OpenMPT or when
// internal metadata gets converted to Unicode, we must adjust this to
// also specify encoding.
xtraChunk.ReadString<mpt::String::nullTerminated>(sampleName, MAX_SAMPLENAME);
xtraChunk.ReadString<mpt::String::nullTerminated>(sample.filename, xtraChunk.BytesLeft());
}
}
}
// Apply WAV loop information to a mod sample.
void WAVSampleLoop::ApplyToSample(SmpLength &start, SmpLength &end, SmpLength sampleLength, SampleFlags &flags, ChannelFlags enableFlag, ChannelFlags bidiFlag, bool mptLoopFix) const
{
if(loopEnd == 0)
{
// Some WAV files seem to have loops going from 0 to 0... We should ignore those.
return;
}
start = std::min(static_cast<SmpLength>(loopStart), sampleLength);
end = Clamp(static_cast<SmpLength>(loopEnd), start, sampleLength);
if(!mptLoopFix && end < sampleLength)
{
// RIFF loop end points are inclusive - old versions of MPT didn't consider this.
end++;
}
flags.set(enableFlag);
if(loopType == loopBidi)
{
flags.set(bidiFlag);
}
}
// Convert internal loop information into a WAV loop.
void WAVSampleLoop::ConvertToWAV(SmpLength start, SmpLength end, bool bidi)
{
identifier = 0;
loopType = bidi ? loopBidi : loopForward;
loopStart = mpt::saturate_cast<uint32>(start);
// Loop ends are *inclusive* in the RIFF standard, while they're *exclusive* in OpenMPT.
if(end > start)
{
loopEnd = mpt::saturate_cast<uint32>(end - 1);
} else
{
loopEnd = loopStart;
}
fraction = 0;
playCount = 0;
}
#ifndef MODPLUG_NO_FILESAVE
///////////////////////////////////////////////////////////
// WAV Writing
// Output to stream: Initialize with std::ostream*.
WAVWriter::WAVWriter(mpt::IO::OFileBase &stream)
: s(stream)
{
// Skip file header for now
Seek(sizeof(RIFFHeader));
}
WAVWriter::~WAVWriter()
{
MPT_ASSERT(finalized);
}
// Finalize the file by closing the last open chunk and updating the file header. Returns total size of file.
std::size_t WAVWriter::Finalize()
{
FinalizeChunk();
RIFFHeader fileHeader;
Clear(fileHeader);
fileHeader.magic = RIFFHeader::idRIFF;
fileHeader.length = static_cast<uint32>(totalSize - 8);
fileHeader.type = RIFFHeader::idWAVE;
Seek(0);
Write(fileHeader);
finalized = true;
return totalSize;
}
// Write a new chunk header to the file.
void WAVWriter::StartChunk(RIFFChunk::ChunkIdentifiers id)
{
FinalizeChunk();
chunkStartPos = position;
chunkHeader.id = id;
Skip(sizeof(chunkHeader));
}
// End current chunk by updating the chunk header and writing a padding byte if necessary.
void WAVWriter::FinalizeChunk()
{
if(chunkStartPos != 0)
{
const std::size_t chunkSize = position - (chunkStartPos + sizeof(RIFFChunk));
chunkHeader.length = mpt::saturate_cast<uint32>(chunkSize);
std::size_t curPos = position;
Seek(chunkStartPos);
Write(chunkHeader);
Seek(curPos);
if((chunkSize % 2u) != 0)
{
// Write padding
uint8 padding = 0;
Write(padding);
}
chunkStartPos = 0;
}
}
// Seek to a position in file.
void WAVWriter::Seek(std::size_t pos)
{
position = pos;
totalSize = std::max(totalSize, position);
mpt::IO::SeekAbsolute(s, pos);
}
// Write some data to the file.
void WAVWriter::Write(mpt::const_byte_span data)
{
MPT_ASSERT(!finalized);
auto success = mpt::IO::WriteRaw(s, data);
MPT_ASSERT(success); // this assertion is useful to catch mis-calculation of required buffer size for pre-allocate in-memory file buffers (like in View_smp.cpp for clipboard)
if(!success)
{
return;
}
position += data.size();
totalSize = std::max(totalSize, position);
}
void WAVWriter::WriteBeforeDirect()
{
MPT_ASSERT(!finalized);
}
void WAVWriter::WriteAfterDirect(bool success, std::size_t count)
{
MPT_ASSERT(success); // this assertion is useful to catch mis-calculation of required buffer size for pre-allocate in-memory file buffers (like in View_smp.cpp for clipboard)
if (!success)
{
return;
}
position += count;
totalSize = std::max(totalSize, position);
}
// Write the WAV format to the file.
void WAVWriter::WriteFormat(uint32 sampleRate, uint16 bitDepth, uint16 numChannels, WAVFormatChunk::SampleFormats encoding)
{
StartChunk(RIFFChunk::idfmt_);
WAVFormatChunk wavFormat;
Clear(wavFormat);
bool extensible = (numChannels > 2);
wavFormat.format = static_cast<uint16>(extensible ? WAVFormatChunk::fmtExtensible : encoding);
wavFormat.numChannels = numChannels;
wavFormat.sampleRate = sampleRate;
wavFormat.blockAlign = (bitDepth * numChannels + 7) / 8;
wavFormat.byteRate = wavFormat.sampleRate * wavFormat.blockAlign;
wavFormat.bitsPerSample = bitDepth;
Write(wavFormat);
if(extensible)
{
WAVFormatChunkExtension extFormat;
Clear(extFormat);
extFormat.size = sizeof(WAVFormatChunkExtension) - sizeof(uint16);
extFormat.validBitsPerSample = bitDepth;
switch(numChannels)
{
case 1:
extFormat.channelMask = 0x0004; // FRONT_CENTER
break;
case 2:
extFormat.channelMask = 0x0003; // FRONT_LEFT | FRONT_RIGHT
break;
case 3:
extFormat.channelMask = 0x0103; // FRONT_LEFT | FRONT_RIGHT | BACK_CENTER
break;
case 4:
extFormat.channelMask = 0x0033; // FRONT_LEFT | FRONT_RIGHT | BACK_LEFT | BACK_RIGHT
break;
default:
extFormat.channelMask = 0;
break;
}
extFormat.subFormat = mpt::UUID(static_cast<uint16>(encoding), 0x0000, 0x0010, 0x800000AA00389B71ull);
Write(extFormat);
}
}
// Write text tags to the file.
void WAVWriter::WriteMetatags(const FileTags &tags)
{
StartChunk(RIFFChunk::idCSET);
Write(mpt::as_le(uint16(65001))); // code page (UTF-8)
Write(mpt::as_le(uint16(0))); // country code (unset)
Write(mpt::as_le(uint16(0))); // language (unset)
Write(mpt::as_le(uint16(0))); // dialect (unset)
StartChunk(RIFFChunk::idLIST);
const char info[] = { 'I', 'N', 'F', 'O' };
Write(info);
WriteTag(RIFFChunk::idINAM, tags.title);
WriteTag(RIFFChunk::idIART, tags.artist);
WriteTag(RIFFChunk::idIPRD, tags.album);
WriteTag(RIFFChunk::idICRD, tags.year);
WriteTag(RIFFChunk::idICMT, tags.comments);
WriteTag(RIFFChunk::idIGNR, tags.genre);
WriteTag(RIFFChunk::idTURL, tags.url);
WriteTag(RIFFChunk::idISFT, tags.encoder);
//WriteTag(RIFFChunk:: , tags.bpm);
WriteTag(RIFFChunk::idTRCK, tags.trackno);
}
// Write a single tag into a open idLIST chunk
void WAVWriter::WriteTag(RIFFChunk::ChunkIdentifiers id, const mpt::ustring &utext)
{
std::string text = mpt::ToCharset(mpt::Charset::UTF8, utext);
text = text.substr(0, uint32_max - 1u);
if(!text.empty())
{
const uint32 length = mpt::saturate_cast<uint32>(text.length() + 1);
RIFFChunk chunk;
Clear(chunk);
chunk.id = static_cast<uint32>(id);
chunk.length = length;
Write(chunk);
Write(mpt::byte_cast<mpt::const_byte_span>(mpt::span(text.c_str(), length)));
if((length % 2u) != 0)
{
uint8 padding = 0;
Write(padding);
}
}
}
// Write a sample loop information chunk to the file.
void WAVWriter::WriteLoopInformation(const ModSample &sample)
{
if(!sample.uFlags[CHN_LOOP | CHN_SUSTAINLOOP] && !ModCommand::IsNote(sample.rootNote))
{
return;
}
StartChunk(RIFFChunk::idsmpl);
WAVSampleInfoChunk info;
uint32 sampleRate = sample.nC5Speed;
if(sampleRate == 0)
{
sampleRate = ModSample::TransposeToFrequency(sample.RelativeTone, sample.nFineTune);
}
info.ConvertToWAV(sampleRate, sample.rootNote);
// Set up loops
WAVSampleLoop loops[2];
Clear(loops);
if(sample.uFlags[CHN_SUSTAINLOOP])
{
loops[info.numLoops++].ConvertToWAV(sample.nSustainStart, sample.nSustainEnd, sample.uFlags[CHN_PINGPONGSUSTAIN]);
}
if(sample.uFlags[CHN_LOOP])
{
loops[info.numLoops++].ConvertToWAV(sample.nLoopStart, sample.nLoopEnd, sample.uFlags[CHN_PINGPONGLOOP]);
} else if(sample.uFlags[CHN_SUSTAINLOOP])
{
// Since there are no "loop types" to distinguish between sustain and normal loops, OpenMPT assumes
// that the first loop is a sustain loop if there are two loops. If we only want a sustain loop,
// we will have to write a second bogus loop.
loops[info.numLoops++].ConvertToWAV(0, 0, false);
}
Write(info);
for(uint32 i = 0; i < info.numLoops; i++)
{
Write(loops[i]);
}
}
// Write a sample's cue points to the file.
void WAVWriter::WriteCueInformation(const ModSample &sample)
{
uint32 numMarkers = 0;
for(const auto cue : sample.cues)
{
if(cue < sample.nLength)
numMarkers++;
}
StartChunk(RIFFChunk::idcue_);
Write(mpt::as_le(numMarkers));
uint32 i = 0;
for(const auto cue : sample.cues)
{
if(cue < sample.nLength)
{
WAVCuePoint cuePoint;
cuePoint.ConvertToWAV(i++, cue);
Write(cuePoint);
}
}
}
// Write MPT's sample information chunk to the file.
void WAVWriter::WriteExtraInformation(const ModSample &sample, MODTYPE modType, const char *sampleName)
{
StartChunk(RIFFChunk::idxtra);
WAVExtraChunk mptInfo;
mptInfo.ConvertToWAV(sample, modType);
Write(mptInfo);
if(sampleName != nullptr)
{
// Write sample name (clipboard only)
// FIXME: When modules can have individual encoding in OpenMPT or when
// internal metadata gets converted to Unicode, we must adjust this to
// also specify encoding.
char name[MAX_SAMPLENAME];
mpt::String::WriteBuf(mpt::String::nullTerminated, name) = sampleName;
Write(name);
char filename[MAX_SAMPLEFILENAME];
mpt::String::WriteBuf(mpt::String::nullTerminated, filename) = sample.filename;
Write(filename);
}
}
#endif // MODPLUG_NO_FILESAVE
OPENMPT_NAMESPACE_END