winamp/Src/external_dependencies/openmpt-trunk/soundlib/Load_ams.cpp

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2024-09-24 08:54:57 -04:00
/*
* Load_ams.cpp
* ------------
* Purpose: AMS (Extreme's Tracker / Velvet Studio) module loader
* Notes : Extreme was renamed to Velvet Development at some point,
* and thus they also renamed their tracker from
* "Extreme's Tracker" to "Velvet Studio".
* While the two programs look rather similiar, the structure of both
* programs' "AMS" format is significantly different in some places -
* Velvet Studio is a rather advanced tracker in comparison to Extreme's Tracker.
* The source code of Velvet Studio has been released into the
* public domain in 2013: https://github.com/Patosc/VelvetStudio/commits/master
* Authors: OpenMPT Devs
* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
*/
#include "stdafx.h"
#include "Loaders.h"
OPENMPT_NAMESPACE_BEGIN
// Read AMS or AMS2 (newVersion = true) pattern. At least this part of the format is more or less identical between the two trackers...
static void ReadAMSPattern(CPattern &pattern, bool newVersion, FileReader &patternChunk)
{
enum
{
emptyRow = 0xFF, // No commands on row
endOfRowMask = 0x80, // If set, no more commands on this row
noteMask = 0x40, // If set, no note+instr in this command
channelMask = 0x1F, // Mask for extracting channel
// Note flags
readNextCmd = 0x80, // One more command follows
noteDataMask = 0x7F, // Extract note
// Command flags
volCommand = 0x40, // Effect is compressed volume command
commandMask = 0x3F, // Command or volume mask
};
// Effect translation table for extended (non-Protracker) effects
static constexpr ModCommand::COMMAND effTrans[] =
{
CMD_S3MCMDEX, // Forward / Backward
CMD_PORTAMENTOUP, // Extra fine slide up
CMD_PORTAMENTODOWN, // Extra fine slide up
CMD_RETRIG, // Retrigger
CMD_NONE,
CMD_TONEPORTAVOL, // Toneporta with fine volume slide
CMD_VIBRATOVOL, // Vibrato with fine volume slide
CMD_NONE,
CMD_PANNINGSLIDE,
CMD_NONE,
CMD_VOLUMESLIDE, // Two times finder volume slide than Axx
CMD_NONE,
CMD_CHANNELVOLUME, // Channel volume (0...127)
CMD_PATTERNBREAK, // Long pattern break (in hex)
CMD_S3MCMDEX, // Fine slide commands
CMD_NONE, // Fractional BPM
CMD_KEYOFF, // Key off at tick xx
CMD_PORTAMENTOUP, // Porta up, but uses all octaves (?)
CMD_PORTAMENTODOWN, // Porta down, but uses all octaves (?)
CMD_NONE,
CMD_NONE,
CMD_NONE,
CMD_NONE,
CMD_NONE,
CMD_NONE,
CMD_NONE,
CMD_GLOBALVOLSLIDE, // Global volume slide
CMD_NONE,
CMD_GLOBALVOLUME, // Global volume (0... 127)
};
ModCommand dummy;
for(ROWINDEX row = 0; row < pattern.GetNumRows(); row++)
{
PatternRow baseRow = pattern.GetRow(row);
while(patternChunk.CanRead(1))
{
const uint8 flags = patternChunk.ReadUint8();
if(flags == emptyRow)
{
break;
}
const CHANNELINDEX chn = (flags & channelMask);
ModCommand &m = chn < pattern.GetNumChannels() ? baseRow[chn] : dummy;
bool moreCommands = true;
if(!(flags & noteMask))
{
// Read note + instr
uint8 note = patternChunk.ReadUint8();
moreCommands = (note & readNextCmd) != 0;
note &= noteDataMask;
if(note == 1)
{
m.note = NOTE_KEYOFF;
} else if(note >= 2 && note <= 121 && newVersion)
{
m.note = note - 2 + NOTE_MIN;
} else if(note >= 12 && note <= 108 && !newVersion)
{
m.note = note + 12 + NOTE_MIN;
}
m.instr = patternChunk.ReadUint8();
}
while(moreCommands)
{
// Read one more effect command
ModCommand origCmd = m;
const uint8 command = patternChunk.ReadUint8(), effect = (command & commandMask);
moreCommands = (command & readNextCmd) != 0;
if(command & volCommand)
{
m.volcmd = VOLCMD_VOLUME;
m.vol = effect;
} else
{
m.param = patternChunk.ReadUint8();
if(effect < 0x10)
{
// PT commands
m.command = effect;
CSoundFile::ConvertModCommand(m);
// Post-fix some commands
switch(m.command)
{
case CMD_PANNING8:
// 4-Bit panning
m.command = CMD_PANNING8;
m.param = (m.param & 0x0F) * 0x11;
break;
case CMD_VOLUME:
m.command = CMD_NONE;
m.volcmd = VOLCMD_VOLUME;
m.vol = static_cast<ModCommand::VOL>(std::min((m.param + 1) / 2, 64));
break;
case CMD_MODCMDEX:
if(m.param == 0x80)
{
// Break sample loop (cut after loop)
m.command = CMD_NONE;
} else
{
m.ExtendedMODtoS3MEffect();
}
break;
}
} else if(effect < 0x10 + mpt::array_size<decltype(effTrans)>::size)
{
// Extended commands
m.command = effTrans[effect - 0x10];
// Post-fix some commands
switch(effect)
{
case 0x10:
// Play sample forwards / backwards
if(m.param <= 0x01)
{
m.param |= 0x9E;
} else
{
m.command = CMD_NONE;
}
break;
case 0x11:
case 0x12:
// Extra fine slides
m.param = static_cast<ModCommand::PARAM>(std::min(uint8(0x0F), m.param) | 0xE0);
break;
case 0x15:
case 0x16:
// Fine slides
m.param = static_cast<ModCommand::PARAM>((std::min(0x10, m.param + 1) / 2) | 0xF0);
break;
case 0x1E:
// More fine slides
switch(m.param >> 4)
{
case 0x1:
// Fine porta up
m.command = CMD_PORTAMENTOUP;
m.param |= 0xF0;
break;
case 0x2:
// Fine porta down
m.command = CMD_PORTAMENTODOWN;
m.param |= 0xF0;
break;
case 0xA:
// Extra fine volume slide up
m.command = CMD_VOLUMESLIDE;
m.param = ((((m.param & 0x0F) + 1) / 2) << 4) | 0x0F;
break;
case 0xB:
// Extra fine volume slide down
m.command = CMD_VOLUMESLIDE;
m.param = (((m.param & 0x0F) + 1) / 2) | 0xF0;
break;
default:
m.command = CMD_NONE;
break;
}
break;
case 0x1C:
// Adjust channel volume range
m.param = static_cast<ModCommand::PARAM>(std::min((m.param + 1) / 2, 64));
break;
}
}
// Try merging commands first
ModCommand::CombineEffects(m.command, m.param, origCmd.command, origCmd.param);
if(ModCommand::GetEffectWeight(origCmd.command) > ModCommand::GetEffectWeight(m.command))
{
if(m.volcmd == VOLCMD_NONE && ModCommand::ConvertVolEffect(m.command, m.param, true))
{
// Volume column to the rescue!
m.volcmd = m.command;
m.vol = m.param;
}
m.command = origCmd.command;
m.param = origCmd.param;
}
}
}
if(flags & endOfRowMask)
{
// End of row
break;
}
}
}
}
/////////////////////////////////////////////////////////////////////
// AMS (Extreme's Tracker) 1.x loader
// AMS File Header
struct AMSFileHeader
{
uint8le versionLow;
uint8le versionHigh;
uint8le channelConfig;
uint8le numSamps;
uint16le numPats;
uint16le numOrds;
uint8le midiChannels;
uint16le extraSize;
};
MPT_BINARY_STRUCT(AMSFileHeader, 11)
// AMS Sample Header
struct AMSSampleHeader
{
enum SampleFlags
{
smp16BitOld = 0x04, // AMS 1.0 (at least according to docs, I yet have to find such a file)
smp16Bit = 0x80, // AMS 1.1+
smpPacked = 0x03,
};
uint32le length;
uint32le loopStart;
uint32le loopEnd;
uint8le panFinetune; // High nibble = pan position, low nibble = finetune value
uint16le sampleRate;
uint8le volume; // 0...127
uint8le flags; // See SampleFlags
// Convert sample header to OpenMPT's internal format.
void ConvertToMPT(ModSample &mptSmp) const
{
mptSmp.Initialize();
mptSmp.nLength = length;
mptSmp.nLoopStart = std::min(loopStart, length);
mptSmp.nLoopEnd = std::min(loopEnd, length);
mptSmp.nVolume = (std::min(uint8(127), volume.get()) * 256 + 64) / 127;
if(panFinetune & 0xF0)
{
mptSmp.nPan = (panFinetune & 0xF0);
mptSmp.uFlags = CHN_PANNING;
}
mptSmp.nC5Speed = 2 * sampleRate;
if(sampleRate == 0)
{
mptSmp.nC5Speed = 2 * 8363;
}
uint32 newC4speed = ModSample::TransposeToFrequency(0, MOD2XMFineTune(panFinetune & 0x0F));
mptSmp.nC5Speed = (mptSmp.nC5Speed * newC4speed) / 8363;
if(mptSmp.nLoopStart < mptSmp.nLoopEnd)
{
mptSmp.uFlags.set(CHN_LOOP);
}
if(flags & (smp16Bit | smp16BitOld))
{
mptSmp.uFlags.set(CHN_16BIT);
}
}
};
MPT_BINARY_STRUCT(AMSSampleHeader, 17)
static bool ValidateHeader(const AMSFileHeader &fileHeader)
{
if(fileHeader.versionHigh != 0x01)
{
return false;
}
return true;
}
static uint64 GetHeaderMinimumAdditionalSize(const AMSFileHeader &fileHeader)
{
return fileHeader.extraSize + 3u + fileHeader.numSamps * (1u + sizeof(AMSSampleHeader)) + fileHeader.numOrds * 2u + fileHeader.numPats * 4u;
}
CSoundFile::ProbeResult CSoundFile::ProbeFileHeaderAMS(MemoryFileReader file, const uint64 *pfilesize)
{
if(!file.CanRead(7))
{
return ProbeWantMoreData;
}
if(!file.ReadMagic("Extreme"))
{
return ProbeFailure;
}
AMSFileHeader fileHeader;
if(!file.ReadStruct(fileHeader))
{
return ProbeWantMoreData;
}
if(!ValidateHeader(fileHeader))
{
return ProbeFailure;
}
return ProbeAdditionalSize(file, pfilesize, GetHeaderMinimumAdditionalSize(fileHeader));
}
bool CSoundFile::ReadAMS(FileReader &file, ModLoadingFlags loadFlags)
{
file.Rewind();
if(!file.ReadMagic("Extreme"))
{
return false;
}
AMSFileHeader fileHeader;
if(!file.ReadStruct(fileHeader))
{
return false;
}
if(!ValidateHeader(fileHeader))
{
return false;
}
if(!file.CanRead(mpt::saturate_cast<FileReader::off_t>(GetHeaderMinimumAdditionalSize(fileHeader))))
{
return false;
}
if(!file.Skip(fileHeader.extraSize))
{
return false;
}
if(loadFlags == onlyVerifyHeader)
{
return true;
}
InitializeGlobals(MOD_TYPE_AMS);
m_SongFlags = SONG_ITCOMPATGXX | SONG_ITOLDEFFECTS;
m_nChannels = (fileHeader.channelConfig & 0x1F) + 1;
m_nSamples = fileHeader.numSamps;
SetupMODPanning(true);
m_modFormat.formatName = U_("Extreme's Tracker");
m_modFormat.type = U_("ams");
m_modFormat.madeWithTracker = MPT_UFORMAT("Extreme's Tracker {}.{}")(fileHeader.versionHigh, fileHeader.versionLow);
m_modFormat.charset = mpt::Charset::CP437;
std::vector<bool> packSample(fileHeader.numSamps);
static_assert(MAX_SAMPLES > 255);
for(SAMPLEINDEX smp = 1; smp <= GetNumSamples(); smp++)
{
AMSSampleHeader sampleHeader;
file.ReadStruct(sampleHeader);
sampleHeader.ConvertToMPT(Samples[smp]);
packSample[smp - 1] = (sampleHeader.flags & AMSSampleHeader::smpPacked) != 0;
}
// Texts
file.ReadSizedString<uint8le, mpt::String::spacePadded>(m_songName);
// Read sample names
for(SAMPLEINDEX smp = 1; smp <= GetNumSamples(); smp++)
{
file.ReadSizedString<uint8le, mpt::String::spacePadded>(m_szNames[smp]);
}
// Read channel names
for(CHANNELINDEX chn = 0; chn < GetNumChannels(); chn++)
{
ChnSettings[chn].Reset();
file.ReadSizedString<uint8le, mpt::String::spacePadded>(ChnSettings[chn].szName);
}
// Read pattern names and create patterns
Patterns.ResizeArray(fileHeader.numPats);
for(PATTERNINDEX pat = 0; pat < fileHeader.numPats; pat++)
{
char name[11];
const bool ok = file.ReadSizedString<uint8le, mpt::String::spacePadded>(name);
// Create pattern now, so name won't be reset later.
if(Patterns.Insert(pat, 64) && ok)
{
Patterns[pat].SetName(name);
}
}
// Read packed song message
const uint16 packedLength = file.ReadUint16LE();
if(packedLength && file.CanRead(packedLength))
{
std::vector<uint8> textIn;
file.ReadVector(textIn, packedLength);
std::string textOut;
textOut.reserve(packedLength);
for(auto c : textIn)
{
if(c & 0x80)
{
textOut.insert(textOut.end(), (c & 0x7F), ' ');
} else
{
textOut.push_back(c);
}
}
textOut = mpt::ToCharset(mpt::Charset::CP437, mpt::Charset::CP437AMS, textOut);
// Packed text doesn't include any line breaks!
m_songMessage.ReadFixedLineLength(mpt::byte_cast<const std::byte*>(textOut.c_str()), textOut.length(), 76, 0);
}
// Read Order List
ReadOrderFromFile<uint16le>(Order(), file, fileHeader.numOrds);
// Read patterns
for(PATTERNINDEX pat = 0; pat < fileHeader.numPats && file.CanRead(4); pat++)
{
uint32 patLength = file.ReadUint32LE();
FileReader patternChunk = file.ReadChunk(patLength);
if((loadFlags & loadPatternData) && Patterns.IsValidPat(pat))
{
ReadAMSPattern(Patterns[pat], false, patternChunk);
}
}
if(loadFlags & loadSampleData)
{
// Read Samples
for(SAMPLEINDEX smp = 1; smp <= GetNumSamples(); smp++)
{
SampleIO(
Samples[smp].uFlags[CHN_16BIT] ? SampleIO::_16bit : SampleIO::_8bit,
SampleIO::mono,
SampleIO::littleEndian,
packSample[smp - 1] ? SampleIO::AMS : SampleIO::signedPCM)
.ReadSample(Samples[smp], file);
}
}
return true;
}
/////////////////////////////////////////////////////////////////////
// AMS (Velvet Studio) 2.0 - 2.02 loader
// AMS2 File Header
struct AMS2FileHeader
{
enum FileFlags
{
linearSlides = 0x40,
};
uint8le versionLow; // Version of format (Hi = MainVer, Low = SubVer e.g. 0202 = 2.02)
uint8le versionHigh; // ditto
uint8le numIns; // Nr of Instruments (0-255)
uint16le numPats; // Nr of Patterns (1-1024)
uint16le numOrds; // Nr of Positions (1-65535)
// Rest of header differs between format revision 2.01 and 2.02
};
MPT_BINARY_STRUCT(AMS2FileHeader, 7)
// AMS2 Instument Envelope
struct AMS2Envelope
{
uint8 speed; // Envelope speed (currently not supported, always the same as current BPM)
uint8 sustainPoint; // Envelope sustain point
uint8 loopStart; // Envelope loop Start
uint8 loopEnd; // Envelope loop End
uint8 numPoints; // Envelope length
// Read envelope and do partial conversion.
void ConvertToMPT(InstrumentEnvelope &mptEnv, FileReader &file)
{
file.ReadStruct(*this);
// Read envelope points
uint8 data[64][3];
file.ReadStructPartial(data, numPoints * 3);
if(numPoints <= 1)
{
// This is not an envelope.
return;
}
static_assert(MAX_ENVPOINTS >= std::size(data));
mptEnv.resize(std::min(numPoints, mpt::saturate_cast<uint8>(std::size(data))));
mptEnv.nLoopStart = loopStart;
mptEnv.nLoopEnd = loopEnd;
mptEnv.nSustainStart = mptEnv.nSustainEnd = sustainPoint;
for(uint32 i = 0; i < mptEnv.size(); i++)
{
if(i != 0)
{
mptEnv[i].tick = mptEnv[i - 1].tick + static_cast<uint16>(std::max(1, data[i][0] | ((data[i][1] & 0x01) << 8)));
}
mptEnv[i].value = data[i][2];
}
}
};
MPT_BINARY_STRUCT(AMS2Envelope, 5)
// AMS2 Instrument Data
struct AMS2Instrument
{
enum EnvelopeFlags
{
envLoop = 0x01,
envSustain = 0x02,
envEnabled = 0x04,
// Flag shift amounts
volEnvShift = 0,
panEnvShift = 1,
vibEnvShift = 2,
vibAmpMask = 0x3000,
vibAmpShift = 12,
fadeOutMask = 0xFFF,
};
uint8le shadowInstr; // Shadow Instrument. If non-zero, the value=the shadowed inst.
uint16le vibampFadeout; // Vib.Amplify + Volume fadeout in one variable!
uint16le envFlags; // See EnvelopeFlags
void ApplyFlags(InstrumentEnvelope &mptEnv, EnvelopeFlags shift) const
{
const int flags = envFlags >> (shift * 3);
mptEnv.dwFlags.set(ENV_ENABLED, (flags & envEnabled) != 0);
mptEnv.dwFlags.set(ENV_LOOP, (flags & envLoop) != 0);
mptEnv.dwFlags.set(ENV_SUSTAIN, (flags & envSustain) != 0);
// "Break envelope" should stop the envelope loop when encountering a note-off... We can only use the sustain loop to emulate this behaviour.
if(!(flags & envSustain) && (flags & envLoop) != 0 && (flags & (1 << (9 - shift * 2))) != 0)
{
mptEnv.nSustainStart = mptEnv.nLoopStart;
mptEnv.nSustainEnd = mptEnv.nLoopEnd;
mptEnv.dwFlags.set(ENV_SUSTAIN);
mptEnv.dwFlags.reset(ENV_LOOP);
}
}
};
MPT_BINARY_STRUCT(AMS2Instrument, 5)
// AMS2 Sample Header
struct AMS2SampleHeader
{
enum SampleFlags
{
smpPacked = 0x03,
smp16Bit = 0x04,
smpLoop = 0x08,
smpBidiLoop = 0x10,
smpReverse = 0x40,
};
uint32le length;
uint32le loopStart;
uint32le loopEnd;
uint16le sampledRate; // Whyyyy?
uint8le panFinetune; // High nibble = pan position, low nibble = finetune value
uint16le c4speed; // Why is all of this so redundant?
int8le relativeTone; // q.e.d.
uint8le volume; // 0...127
uint8le flags; // See SampleFlags
// Convert sample header to OpenMPT's internal format.
void ConvertToMPT(ModSample &mptSmp) const
{
mptSmp.Initialize();
mptSmp.nLength = length;
mptSmp.nLoopStart = std::min(loopStart, length);
mptSmp.nLoopEnd = std::min(loopEnd, length);
mptSmp.nC5Speed = c4speed * 2;
if(c4speed == 0)
{
mptSmp.nC5Speed = 8363 * 2;
}
// Why, oh why, does this format need a c5speed and transpose/finetune at the same time...
uint32 newC4speed = ModSample::TransposeToFrequency(relativeTone, MOD2XMFineTune(panFinetune & 0x0F));
mptSmp.nC5Speed = (mptSmp.nC5Speed * newC4speed) / 8363;
mptSmp.nVolume = (std::min(volume.get(), uint8(127)) * 256 + 64) / 127;
if(panFinetune & 0xF0)
{
mptSmp.nPan = (panFinetune & 0xF0);
mptSmp.uFlags = CHN_PANNING;
}
if(flags & smp16Bit) mptSmp.uFlags.set(CHN_16BIT);
if((flags & smpLoop) && mptSmp.nLoopStart < mptSmp.nLoopEnd)
{
mptSmp.uFlags.set(CHN_LOOP);
if(flags & smpBidiLoop) mptSmp.uFlags.set(CHN_PINGPONGLOOP);
if(flags & smpReverse) mptSmp.uFlags.set(CHN_REVERSE);
}
}
};
MPT_BINARY_STRUCT(AMS2SampleHeader, 20)
// AMS2 Song Description Header
struct AMS2Description
{
uint32le packedLen; // Including header
uint32le unpackedLen;
uint8le packRoutine; // 01
uint8le preProcessing; // None!
uint8le packingMethod; // RLE
};
MPT_BINARY_STRUCT(AMS2Description, 11)
static bool ValidateHeader(const AMS2FileHeader &fileHeader)
{
if(fileHeader.versionHigh != 2 || fileHeader.versionLow > 2)
{
return false;
}
return true;
}
static uint64 GetHeaderMinimumAdditionalSize(const AMS2FileHeader &fileHeader)
{
return 36u + sizeof(AMS2Description) + fileHeader.numIns * 2u + fileHeader.numOrds * 2u + fileHeader.numPats * 4u;
}
CSoundFile::ProbeResult CSoundFile::ProbeFileHeaderAMS2(MemoryFileReader file, const uint64 *pfilesize)
{
if(!file.CanRead(7))
{
return ProbeWantMoreData;
}
if(!file.ReadMagic("AMShdr\x1A"))
{
return ProbeFailure;
}
if(!file.CanRead(1))
{
return ProbeWantMoreData;
}
const uint8 songNameLength = file.ReadUint8();
if(!file.Skip(songNameLength))
{
return ProbeWantMoreData;
}
AMS2FileHeader fileHeader;
if(!file.ReadStruct(fileHeader))
{
return ProbeWantMoreData;
}
if(!ValidateHeader(fileHeader))
{
return ProbeFailure;
}
return ProbeAdditionalSize(file, pfilesize, GetHeaderMinimumAdditionalSize(fileHeader));
}
bool CSoundFile::ReadAMS2(FileReader &file, ModLoadingFlags loadFlags)
{
file.Rewind();
if(!file.ReadMagic("AMShdr\x1A"))
{
return false;
}
std::string songName;
if(!file.ReadSizedString<uint8le, mpt::String::spacePadded>(songName))
{
return false;
}
AMS2FileHeader fileHeader;
if(!file.ReadStruct(fileHeader))
{
return false;
}
if(!ValidateHeader(fileHeader))
{
return false;
}
if(!file.CanRead(mpt::saturate_cast<FileReader::off_t>(GetHeaderMinimumAdditionalSize(fileHeader))))
{
return false;
}
if(loadFlags == onlyVerifyHeader)
{
return true;
}
InitializeGlobals(MOD_TYPE_AMS);
m_songName = songName;
m_nInstruments = fileHeader.numIns;
m_nChannels = 32;
SetupMODPanning(true);
m_modFormat.formatName = U_("Velvet Studio");
m_modFormat.type = U_("ams");
m_modFormat.madeWithTracker = MPT_UFORMAT("Velvet Studio {}.{}")(fileHeader.versionHigh.get(), mpt::ufmt::dec0<2>(fileHeader.versionLow.get()));
m_modFormat.charset = mpt::Charset::CP437;
uint16 headerFlags;
if(fileHeader.versionLow >= 2)
{
uint16 tempo = std::max(uint16(32 << 8), file.ReadUint16LE()); // 8.8 tempo
m_nDefaultTempo.SetRaw((tempo * TEMPO::fractFact) >> 8);
m_nDefaultSpeed = std::max(uint8(1), file.ReadUint8());
file.Skip(3); // Default values for pattern editor
headerFlags = file.ReadUint16LE();
} else
{
m_nDefaultTempo.Set(std::max(uint8(32), file.ReadUint8()));
m_nDefaultSpeed = std::max(uint8(1), file.ReadUint8());
headerFlags = file.ReadUint8();
}
m_SongFlags = SONG_ITCOMPATGXX | SONG_ITOLDEFFECTS | ((headerFlags & AMS2FileHeader::linearSlides) ? SONG_LINEARSLIDES : SongFlags(0));
// Instruments
std::vector<SAMPLEINDEX> firstSample; // First sample of instrument
std::vector<uint16> sampleSettings; // Shadow sample map... Lo byte = Instrument, Hi byte, lo nibble = Sample index in instrument, Hi byte, hi nibble = Sample pack status
enum
{
instrIndexMask = 0xFF, // Shadow instrument
sampleIndexMask = 0x7F00, // Sample index in instrument
sampleIndexShift = 8,
packStatusMask = 0x8000, // If bit is set, sample is packed
};
static_assert(MAX_INSTRUMENTS > 255);
for(INSTRUMENTINDEX ins = 1; ins <= m_nInstruments; ins++)
{
ModInstrument *instrument = AllocateInstrument(ins);
if(instrument == nullptr
|| !file.ReadSizedString<uint8le, mpt::String::spacePadded>(instrument->name))
{
break;
}
uint8 numSamples = file.ReadUint8();
uint8 sampleAssignment[120];
MemsetZero(sampleAssignment); // Only really needed for v2.0, where the lowest and highest octave aren't cleared.
if(numSamples == 0
|| (fileHeader.versionLow > 0 && !file.ReadArray(sampleAssignment)) // v2.01+: 120 Notes
|| (fileHeader.versionLow == 0 && !file.ReadRaw(mpt::span(sampleAssignment + 12, 96)).size())) // v2.0: 96 Notes
{
continue;
}
static_assert(mpt::array_size<decltype(instrument->Keyboard)>::size >= std::size(sampleAssignment));
for(size_t i = 0; i < 120; i++)
{
instrument->Keyboard[i] = sampleAssignment[i] + GetNumSamples() + 1;
}
AMS2Envelope volEnv, panEnv, vibratoEnv;
volEnv.ConvertToMPT(instrument->VolEnv, file);
panEnv.ConvertToMPT(instrument->PanEnv, file);
vibratoEnv.ConvertToMPT(instrument->PitchEnv, file);
AMS2Instrument instrHeader;
file.ReadStruct(instrHeader);
instrument->nFadeOut = (instrHeader.vibampFadeout & AMS2Instrument::fadeOutMask);
const int16 vibAmp = 1 << ((instrHeader.vibampFadeout & AMS2Instrument::vibAmpMask) >> AMS2Instrument::vibAmpShift);
instrHeader.ApplyFlags(instrument->VolEnv, AMS2Instrument::volEnvShift);
instrHeader.ApplyFlags(instrument->PanEnv, AMS2Instrument::panEnvShift);
instrHeader.ApplyFlags(instrument->PitchEnv, AMS2Instrument::vibEnvShift);
// Scale envelopes to correct range
for(auto &p : instrument->VolEnv)
{
p.value = std::min(uint8(ENVELOPE_MAX), static_cast<uint8>((p.value * ENVELOPE_MAX + 64u) / 127u));
}
for(auto &p : instrument->PanEnv)
{
p.value = std::min(uint8(ENVELOPE_MAX), static_cast<uint8>((p.value * ENVELOPE_MAX + 128u) / 255u));
}
for(auto &p : instrument->PitchEnv)
{
#ifdef MODPLUG_TRACKER
p.value = std::min(uint8(ENVELOPE_MAX), static_cast<uint8>(32 + Util::muldivrfloor(static_cast<int8>(p.value - 128), vibAmp, 255)));
#else
// Try to keep as much precision as possible... divide by 8 since that's the highest possible vibAmp factor.
p.value = static_cast<uint8>(128 + Util::muldivrfloor(static_cast<int8>(p.value - 128), vibAmp, 8));
#endif
}
// Sample headers - we will have to read them even for shadow samples, and we will have to load them several times,
// as it is possible that shadow samples use different sample settings like base frequency or panning.
const SAMPLEINDEX firstSmp = GetNumSamples() + 1;
for(SAMPLEINDEX smp = 0; smp < numSamples; smp++)
{
if(firstSmp + smp >= MAX_SAMPLES)
{
file.Skip(sizeof(AMS2SampleHeader));
break;
}
file.ReadSizedString<uint8le, mpt::String::spacePadded>(m_szNames[firstSmp + smp]);
AMS2SampleHeader sampleHeader;
file.ReadStruct(sampleHeader);
sampleHeader.ConvertToMPT(Samples[firstSmp + smp]);
uint16 settings = (instrHeader.shadowInstr & instrIndexMask)
| ((smp << sampleIndexShift) & sampleIndexMask)
| ((sampleHeader.flags & AMS2SampleHeader::smpPacked) ? packStatusMask : 0);
sampleSettings.push_back(settings);
}
firstSample.push_back(firstSmp);
m_nSamples = static_cast<SAMPLEINDEX>(std::min(MAX_SAMPLES - 1, GetNumSamples() + numSamples));
}
// Text
// Read composer name
if(std::string composer; file.ReadSizedString<uint8le, mpt::String::spacePadded>(composer))
{
m_songArtist = mpt::ToUnicode(mpt::Charset::CP437AMS2, composer);
}
// Channel names
for(CHANNELINDEX chn = 0; chn < 32; chn++)
{
ChnSettings[chn].Reset();
file.ReadSizedString<uint8le, mpt::String::spacePadded>(ChnSettings[chn].szName);
}
// RLE-Packed description text
AMS2Description descriptionHeader;
if(!file.ReadStruct(descriptionHeader))
{
return true;
}
if(descriptionHeader.packedLen > sizeof(descriptionHeader) && file.CanRead(descriptionHeader.packedLen - sizeof(descriptionHeader)))
{
const uint32 textLength = descriptionHeader.packedLen - static_cast<uint32>(sizeof(descriptionHeader));
std::vector<uint8> textIn;
file.ReadVector(textIn, textLength);
// In the best case, every byte triplet can decode to 255 bytes, which is a ratio of exactly 1:85
const uint32 maxLength = std::min(textLength, Util::MaxValueOfType(textLength) / 85u) * 85u;
std::string textOut;
textOut.reserve(std::min(maxLength, descriptionHeader.unpackedLen.get()));
size_t readLen = 0;
while(readLen < textLength)
{
uint8 c = textIn[readLen++];
if(c == 0xFF && textLength - readLen >= 2)
{
c = textIn[readLen++];
uint32 count = textIn[readLen++];
textOut.insert(textOut.end(), count, c);
} else
{
textOut.push_back(c);
}
}
textOut = mpt::ToCharset(mpt::Charset::CP437, mpt::Charset::CP437AMS2, textOut);
// Packed text doesn't include any line breaks!
m_songMessage.ReadFixedLineLength(mpt::byte_cast<const std::byte*>(textOut.c_str()), textOut.length(), 74, 0);
}
// Read Order List
ReadOrderFromFile<uint16le>(Order(), file, fileHeader.numOrds);
// Read Patterns
if(loadFlags & loadPatternData)
Patterns.ResizeArray(fileHeader.numPats);
for(PATTERNINDEX pat = 0; pat < fileHeader.numPats && file.CanRead(4); pat++)
{
uint32 patLength = file.ReadUint32LE();
FileReader patternChunk = file.ReadChunk(patLength);
if(loadFlags & loadPatternData)
{
const ROWINDEX numRows = patternChunk.ReadUint8() + 1;
// We don't need to know the number of channels or commands.
patternChunk.Skip(1);
if(!Patterns.Insert(pat, numRows))
{
continue;
}
char patternName[11];
if(patternChunk.ReadSizedString<uint8le, mpt::String::spacePadded>(patternName))
Patterns[pat].SetName(patternName);
ReadAMSPattern(Patterns[pat], true, patternChunk);
}
}
if(!(loadFlags & loadSampleData))
{
return true;
}
// Read Samples
for(SAMPLEINDEX smp = 0; smp < GetNumSamples(); smp++)
{
if((sampleSettings[smp] & instrIndexMask) == 0)
{
// Only load samples that aren't part of a shadow instrument
SampleIO(
(Samples[smp + 1].uFlags & CHN_16BIT) ? SampleIO::_16bit : SampleIO::_8bit,
SampleIO::mono,
SampleIO::littleEndian,
(sampleSettings[smp] & packStatusMask) ? SampleIO::AMS : SampleIO::signedPCM)
.ReadSample(Samples[smp + 1], file);
}
}
// Copy shadow samples
for(SAMPLEINDEX smp = 0; smp < GetNumSamples(); smp++)
{
INSTRUMENTINDEX sourceInstr = (sampleSettings[smp] & instrIndexMask);
if(sourceInstr == 0
|| --sourceInstr >= firstSample.size())
{
continue;
}
SAMPLEINDEX sourceSample = ((sampleSettings[smp] & sampleIndexMask) >> sampleIndexShift) + firstSample[sourceInstr];
if(sourceSample > GetNumSamples() || !Samples[sourceSample].HasSampleData())
{
continue;
}
// Copy over original sample
ModSample &sample = Samples[smp + 1];
ModSample &source = Samples[sourceSample];
sample.uFlags.set(CHN_16BIT, source.uFlags[CHN_16BIT]);
sample.nLength = source.nLength;
if(sample.AllocateSample())
{
memcpy(sample.sampleb(), source.sampleb(), source.GetSampleSizeInBytes());
}
}
return true;
}
/////////////////////////////////////////////////////////////////////
// AMS Sample unpacking
void AMSUnpack(const int8 * const source, size_t sourceSize, void * const dest, const size_t destSize, char packCharacter)
{
std::vector<int8> tempBuf(destSize, 0);
size_t depackSize = destSize;
// Unpack Loop
{
const int8 *in = source;
int8 *out = tempBuf.data();
size_t i = sourceSize, j = destSize;
while(i != 0 && j != 0)
{
int8 ch = *(in++);
if(--i != 0 && ch == packCharacter)
{
uint8 repCount = *(in++);
repCount = static_cast<uint8>(std::min(static_cast<size_t>(repCount), j));
if(--i != 0 && repCount)
{
ch = *(in++);
i--;
while(repCount-- != 0)
{
*(out++) = ch;
j--;
}
} else
{
*(out++) = packCharacter;
j--;
}
} else
{
*(out++) = ch;
j--;
}
}
// j should only be non-zero for truncated samples
depackSize -= j;
}
// Bit Unpack Loop
{
int8 *out = tempBuf.data();
uint16 bitcount = 0x80;
size_t k = 0;
uint8 *dst = static_cast<uint8 *>(dest);
for(size_t i = 0; i < depackSize; i++)
{
uint8 al = *out++;
uint16 dh = 0;
for(uint16 count = 0; count < 8; count++)
{
uint16 bl = al & bitcount;
bl = ((bl | (bl << 8)) >> ((dh + 8 - count) & 7)) & 0xFF;
bitcount = ((bitcount | (bitcount << 8)) >> 1) & 0xFF;
dst[k++] |= bl;
if(k >= destSize)
{
k = 0;
dh++;
}
}
bitcount = ((bitcount | (bitcount << 8)) >> dh) & 0xFF;
}
}
// Delta Unpack
{
int8 old = 0;
int8 *out = static_cast<int8 *>(dest);
for(size_t i = depackSize; i != 0; i--)
{
int pos = *reinterpret_cast<uint8 *>(out);
if(pos != 128 && (pos & 0x80) != 0)
{
pos = -(pos & 0x7F);
}
old -= static_cast<int8>(pos);
*(out++) = old;
}
}
}
OPENMPT_NAMESPACE_END