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cog/Frameworks/OpenMPT.old/OpenMPT/soundlib/Load_stp.cpp

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Updated libopenmpt to version 0.6.0, with major new changes. This new version requires macOS 10.15 to work, due to libc++ features required. A compatibility plugin has been duplicated from the existing plugin, which will now load libopenmpt 0.5.14, or whatever newer version may come out that still supports as old as macOS 10.12.
2021-12-26 11:29:43 +00:00
/*
* Load_stp.cpp
* ------------
* Purpose: STP (Soundtracker Pro II) module loader
* Notes : A few exotic effects aren't supported.
* Multiple sample loops are supported, but only the first 10 can be used as cue points
* (with 16xx and 18xx).
* Fractional speed values and combined auto effects are handled whenever possible,
* but some effects may be omitted (and there may be tempo accuracy issues).
* Authors: Devin Acker
* OpenMPT Devs
* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
*
* Wisdom from the Soundtracker Pro II manual:
* "To create shorter patterns, simply create shorter patterns."
*/
#include "stdafx.h"
#include "Loaders.h"
OPENMPT_NAMESPACE_BEGIN
// File header
struct STPFileHeader
{
char magic[4];
uint16be version;
uint8be numOrders;
uint8be patternLength;
uint8be orderList[128];
uint16be speed;
uint16be speedFrac;
uint16be timerCount;
uint16be flags;
uint32be reserved;
uint16be midiCount; // always 50
uint8be midi[50];
uint16be numSamples;
uint16be sampleStructSize;
};
MPT_BINARY_STRUCT(STPFileHeader, 204)
// Sample header (common part between all versions)
struct STPSampleHeader
{
uint32be length;
uint8be volume;
uint8be reserved1;
uint32be loopStart;
uint32be loopLength;
uint16be defaultCommand; // Default command to put next to note when editing patterns; not relevant for playback
// The following 4 bytes are reserved in version 0 and 1.
uint16be defaultPeriod;
uint8be finetune;
uint8be reserved2;
void ConvertToMPT(ModSample &mptSmp) const
{
mptSmp.nLength = length;
mptSmp.nVolume = 4u * std::min(volume.get(), uint8(64));
mptSmp.nLoopStart = loopStart;
mptSmp.nLoopEnd = loopStart + loopLength;
if(mptSmp.nLoopStart >= mptSmp.nLength)
{
mptSmp.nLoopStart = mptSmp.nLength - 1;
}
if(mptSmp.nLoopEnd > mptSmp.nLength)
{
mptSmp.nLoopEnd = mptSmp.nLength;
}
if(mptSmp.nLoopStart > mptSmp.nLoopEnd)
{
mptSmp.nLoopStart = 0;
mptSmp.nLoopEnd = 0;
} else if(mptSmp.nLoopEnd > mptSmp.nLoopStart)
{
mptSmp.uFlags.set(CHN_LOOP);
mptSmp.cues[0] = mptSmp.nLoopStart;
}
}
};
MPT_BINARY_STRUCT(STPSampleHeader, 20)
struct STPLoopInfo
{
SmpLength loopStart;
SmpLength loopLength;
SAMPLEINDEX looped;
SAMPLEINDEX nonLooped;
};
typedef std::vector<STPLoopInfo> STPLoopList;
static TEMPO ConvertTempo(uint16 ciaSpeed)
{
// 3546 is the resulting CIA timer value when using 4F7D (tempo 125 bpm) command in STProII
return TEMPO((125.0 * 3546.0) / ciaSpeed);
}
static void ConvertLoopSlice(ModSample &src, ModSample &dest, SmpLength start, SmpLength len, bool loop)
{
if(!src.HasSampleData()
|| start >= src.nLength
|| src.nLength - start < len)
{
return;
}
dest.FreeSample();
dest = src;
dest.nLength = len;
dest.pData.pSample = nullptr;
if(!dest.AllocateSample())
{
return;
}
// only preserve cue points if the target sample length is the same
if(len != src.nLength)
MemsetZero(dest.cues);
std::memcpy(dest.sampleb(), src.sampleb() + start, len);
dest.uFlags.set(CHN_LOOP, loop);
if(loop)
{
dest.nLoopStart = 0;
dest.nLoopEnd = len;
} else
{
dest.nLoopStart = 0;
dest.nLoopEnd = 0;
}
}
static void ConvertLoopSequence(ModSample &smp, STPLoopList &loopList)
{
// This should only modify a sample if it has more than one loop
// (otherwise, it behaves like a normal sample loop)
if(!smp.HasSampleData() || loopList.size() < 2) return;
ModSample newSmp = smp;
newSmp.nLength = 0;
newSmp.pData.pSample = nullptr;
size_t numLoops = loopList.size();
// Get the total length of the sample after combining all looped sections
for(size_t i = 0; i < numLoops; i++)
{
STPLoopInfo &info = loopList[i];
// If adding this loop would cause the sample length to exceed maximum,
// then limit and bail out
if(info.loopStart >= smp.nLength
|| smp.nLength - info.loopStart < info.loopLength
|| newSmp.nLength > MAX_SAMPLE_LENGTH - info.loopLength)
{
numLoops = i;
break;
}
newSmp.nLength += info.loopLength;
}
if(!newSmp.AllocateSample())
{
return;
}
// start copying the looped sample data parts
SmpLength start = 0;
for(size_t i = 0; i < numLoops; i++)
{
STPLoopInfo &info = loopList[i];
memcpy(newSmp.sampleb() + start, smp.sampleb() + info.loopStart, info.loopLength);
// update loop info based on position in edited sample
info.loopStart = start;
if(i > 0 && i <= std::size(newSmp.cues))
{
newSmp.cues[i - 1] = start;
}
start += info.loopLength;
}
// replace old sample with new one
smp.FreeSample();
smp = newSmp;
smp.nLoopStart = 0;
smp.nLoopEnd = smp.nLength;
smp.uFlags.set(CHN_LOOP);
}
static bool ValidateHeader(const STPFileHeader &fileHeader)
{
if(std::memcmp(fileHeader.magic, "STP3", 4)
|| fileHeader.version > 2
|| fileHeader.numOrders > 128
|| fileHeader.numSamples >= MAX_SAMPLES
|| fileHeader.timerCount == 0
|| fileHeader.midiCount != 50)
{
return false;
}
return true;
}
CSoundFile::ProbeResult CSoundFile::ProbeFileHeaderSTP(MemoryFileReader file, const uint64 *pfilesize)
{
STPFileHeader fileHeader;
if(!file.ReadStruct(fileHeader))
{
return ProbeWantMoreData;
}
if(!ValidateHeader(fileHeader))
{
return ProbeFailure;
}
MPT_UNREFERENCED_PARAMETER(pfilesize);
return ProbeSuccess;
}
bool CSoundFile::ReadSTP(FileReader &file, ModLoadingFlags loadFlags)
{
file.Rewind();
STPFileHeader fileHeader;
if(!file.ReadStruct(fileHeader))
{
return false;
}
if(!ValidateHeader(fileHeader))
{
return false;
}
if(loadFlags == onlyVerifyHeader)
{
return true;
}
InitializeGlobals(MOD_TYPE_STP);
m_modFormat.formatName = mpt::format(U_("Soundtracker Pro II v%1"))(fileHeader.version);
m_modFormat.type = U_("stp");
m_modFormat.charset = mpt::Charset::ISO8859_1;
m_nChannels = 4;
m_nSamples = 0;
m_nDefaultSpeed = fileHeader.speed;
m_nDefaultTempo = ConvertTempo(fileHeader.timerCount);
m_nMinPeriod = 14 * 4;
m_nMaxPeriod = 3424 * 4;
ReadOrderFromArray(Order(), fileHeader.orderList, fileHeader.numOrders);
std::vector<STPLoopList> loopInfo;
// Non-looped versions of samples with loops (when needed)
std::vector<SAMPLEINDEX> nonLooped;
// Load sample headers
SAMPLEINDEX samplesInFile = 0;
for(SAMPLEINDEX smp = 0; smp < fileHeader.numSamples; smp++)
{
SAMPLEINDEX actualSmp = file.ReadUint16BE();
if(actualSmp == 0 || actualSmp >= MAX_SAMPLES)
return false;
uint32 chunkSize = fileHeader.sampleStructSize;
if(fileHeader.version == 2)
chunkSize = file.ReadUint32BE() - 2;
FileReader chunk = file.ReadChunk(chunkSize);
samplesInFile = m_nSamples = std::max(m_nSamples, actualSmp);
ModSample &mptSmp = Samples[actualSmp];
mptSmp.Initialize(MOD_TYPE_MOD);
if(fileHeader.version < 2)
{
// Read path
chunk.ReadString<mpt::String::maybeNullTerminated>(mptSmp.filename, 31);
// Ignore flags, they are all not relevant for us
chunk.Skip(1);
// Read filename / sample text
chunk.ReadString<mpt::String::maybeNullTerminated>(m_szNames[actualSmp], 30);
} else
{
std::string str;
// Read path
chunk.ReadNullString(str, 257);
mptSmp.filename = str;
// Ignore flags, they are all not relevant for us
chunk.Skip(1);
// Read filename / sample text
chunk.ReadNullString(str, 31);
m_szNames[actualSmp] = str;
// Seek to even boundary
if(chunk.GetPosition() % 2u)
chunk.Skip(1);
}
STPSampleHeader sampleHeader;
chunk.ReadStruct(sampleHeader);
sampleHeader.ConvertToMPT(mptSmp);
if(fileHeader.version == 2)
{
mptSmp.nFineTune = static_cast<int8>(sampleHeader.finetune << 3);
}
if(fileHeader.version >= 1)
{
nonLooped.resize(samplesInFile);
loopInfo.resize(samplesInFile);
STPLoopList &loopList = loopInfo[actualSmp - 1];
loopList.clear();
const uint16 numLoops = file.ReadUint16BE();
if(!file.CanRead(numLoops * 8u))
return false;
loopList.reserve(numLoops);
STPLoopInfo loop;
loop.looped = loop.nonLooped = 0;
if(numLoops == 0 && mptSmp.uFlags[CHN_LOOP])
{
loop.loopStart = mptSmp.nLoopStart;
loop.loopLength = mptSmp.nLoopEnd - mptSmp.nLoopStart;
loopList.push_back(loop);
} else for(uint16 i = 0; i < numLoops; i++)
{
loop.loopStart = file.ReadUint32BE();
loop.loopLength = file.ReadUint32BE();
loopList.push_back(loop);
}
}
}
// Load patterns
uint16 numPatterns = 128;
if(fileHeader.version == 0)
numPatterns = file.ReadUint16BE();
uint16 patternLength = fileHeader.patternLength;
CHANNELINDEX channels = 4;
if(fileHeader.version > 0)
{
// Scan for total number of channels
FileReader::off_t patOffset = file.GetPosition();
for(uint16 pat = 0; pat < numPatterns; pat++)
{
PATTERNINDEX actualPat = file.ReadUint16BE();
if(actualPat == 0xFFFF)
break;
patternLength = file.ReadUint16BE();
channels = file.ReadUint16BE();
if(channels > MAX_BASECHANNELS)
return false;
m_nChannels = std::max(m_nChannels, channels);
file.Skip(channels * patternLength * 4u);
}
file.Seek(patOffset);
}
struct ChannelMemory
{
uint8 autoFinePorta, autoPortaUp, autoPortaDown, autoVolSlide, autoVibrato;
uint8 vibratoMem, autoTremolo, autoTonePorta, tonePortaMem;
};
std::vector<ChannelMemory> channelMemory(m_nChannels);
uint8 globalVolSlide = 0;
uint8 speedFrac = static_cast<uint8>(fileHeader.speedFrac);
for(uint16 pat = 0; pat < numPatterns; pat++)
{
PATTERNINDEX actualPat = pat;
if(fileHeader.version > 0)
{
actualPat = file.ReadUint16BE();
if(actualPat == 0xFFFF)
break;
patternLength = file.ReadUint16BE();
channels = file.ReadUint16BE();
}
if(!file.CanRead(channels * patternLength * 4u))
break;
if(!(loadFlags & loadPatternData) || !Patterns.Insert(actualPat, patternLength))
{
file.Skip(channels * patternLength * 4u);
continue;
}
for(ROWINDEX row = 0; row < patternLength; row++)
{
auto rowBase = Patterns[actualPat].GetRow(row);
bool didGlobalVolSlide = false;
// if a fractional speed value is in use then determine if we should stick a fine pattern delay somewhere
bool shouldDelay;
switch(speedFrac & 3)
{
default: shouldDelay = false; break;
// 1/4
case 1: shouldDelay = (row & 3) == 0; break;
// 1/2
case 2: shouldDelay = (row & 1) == 0; break;
// 3/4
case 3: shouldDelay = (row & 3) != 3; break;
}
for(CHANNELINDEX chn = 0; chn < channels; chn++)
{
ChannelMemory &chnMem = channelMemory[chn];
ModCommand &m = rowBase[chn];
const auto [instr, note, command, param] = file.ReadArray<uint8, 4>();
m.instr = instr;
m.note = note;
m.param = param;
if(m.note)
{
m.note += 24 + NOTE_MIN;
chnMem = ChannelMemory();
}
// this is a nibble-swapped param value used for auto fine volside
// and auto global fine volside
uint8 swapped = (m.param >> 4) | (m.param << 4);
if((command & 0xF0) == 0xF0)
{
// 12-bit CIA tempo
uint16 ciaTempo = (static_cast<uint16>(command & 0x0F) << 8) | m.param;
if(ciaTempo)
{
m.param = mpt::saturate_round<ModCommand::PARAM>(ConvertTempo(ciaTempo).ToDouble());
m.command = CMD_TEMPO;
} else
{
m.command = CMD_NONE;
}
} else switch(command)
{
case 0x00: // arpeggio
if(m.param)
m.command = CMD_ARPEGGIO;
else
m.command = CMD_NONE;
break;
case 0x01: // portamento up
m.command = CMD_PORTAMENTOUP;
break;
case 0x02: // portamento down
m.command = CMD_PORTAMENTODOWN;
break;
case 0x03: // auto fine portamento up
chnMem.autoFinePorta = 0x10 | std::min(m.param, ModCommand::PARAM(15));
chnMem.autoPortaUp = 0;
chnMem.autoPortaDown = 0;
chnMem.autoTonePorta = 0;
m.command = CMD_NONE;
break;
case 0x04: // auto fine portamento down
chnMem.autoFinePorta = 0x20 | std::min(m.param, ModCommand::PARAM(15));
chnMem.autoPortaUp = 0;
chnMem.autoPortaDown = 0;
chnMem.autoTonePorta = 0;
m.command = CMD_NONE;
break;
case 0x05: // auto portamento up
chnMem.autoFinePorta = 0;
chnMem.autoPortaUp = m.param;
chnMem.autoPortaDown = 0;
chnMem.autoTonePorta = 0;
m.command = CMD_NONE;
break;
case 0x06: // auto portamento down
chnMem.autoFinePorta = 0;
chnMem.autoPortaUp = 0;
chnMem.autoPortaDown = m.param;
chnMem.autoTonePorta = 0;
m.command = CMD_NONE;
break;
case 0x07: // set global volume
m.command = CMD_GLOBALVOLUME;
globalVolSlide = 0;
break;
case 0x08: // auto global fine volume slide
globalVolSlide = swapped;
m.command = CMD_NONE;
break;
case 0x09: // fine portamento up
m.command = CMD_MODCMDEX;
m.param = 0x10 | std::min(m.param, ModCommand::PARAM(15));
break;
case 0x0A: // fine portamento down
m.command = CMD_MODCMDEX;
m.param = 0x20 | std::min(m.param, ModCommand::PARAM(15));
break;
case 0x0B: // auto fine volume slide
chnMem.autoVolSlide = swapped;
m.command = CMD_NONE;
break;
case 0x0C: // set volume
m.volcmd = VOLCMD_VOLUME;
m.vol = m.param;
chnMem.autoVolSlide = 0;
m.command = CMD_NONE;
break;
case 0x0D: // volume slide (param is swapped compared to .mod)
if(m.param & 0xF0)
{
m.volcmd = VOLCMD_VOLSLIDEDOWN;
m.vol = m.param >> 4;
} else if(m.param & 0x0F)
{
m.volcmd = VOLCMD_VOLSLIDEUP;
m.vol = m.param & 0xF;
}
chnMem.autoVolSlide = 0;
m.command = CMD_NONE;
break;
case 0x0E: // set filter (also uses opposite value compared to .mod)
m.command = CMD_MODCMDEX;
m.param = 1 ^ (m.param ? 1 : 0);
break;
case 0x0F: // set speed
m.command = CMD_SPEED;
speedFrac = m.param & 0x0F;
m.param >>= 4;
break;
case 0x10: // auto vibrato
chnMem.autoVibrato = m.param;
chnMem.vibratoMem = 0;
m.command = CMD_NONE;
break;
case 0x11: // auto tremolo
if(m.param & 0xF)
chnMem.autoTremolo = m.param;
else
chnMem.autoTremolo = 0;
m.command = CMD_NONE;
break;
case 0x12: // pattern break
m.command = CMD_PATTERNBREAK;
break;
case 0x13: // auto tone portamento
chnMem.autoFinePorta = 0;
chnMem.autoPortaUp = 0;
chnMem.autoPortaDown = 0;
chnMem.autoTonePorta = m.param;
chnMem.tonePortaMem = 0;
m.command = CMD_NONE;
break;
case 0x14: // position jump
m.command = CMD_POSITIONJUMP;
break;
case 0x16: // start loop sequence
if(m.instr && m.instr <= loopInfo.size())
{
STPLoopList &loopList = loopInfo[m.instr - 1];
m.param--;
if(m.param < std::min(std::size(ModSample().cues), loopList.size()))
{
m.volcmd = VOLCMD_OFFSET;
m.vol = m.param;
}
}
m.command = CMD_NONE;
break;
case 0x17: // play only loop nn
if(m.instr && m.instr <= loopInfo.size())
{
STPLoopList &loopList = loopInfo[m.instr - 1];
m.param--;
if(m.param < loopList.size())
{
if(!loopList[m.param].looped && CanAddMoreSamples())
loopList[m.param].looped = ++m_nSamples;
m.instr = static_cast<ModCommand::INSTR>(loopList[m.param].looped);
}
}
m.command = CMD_NONE;
break;
case 0x18: // play sequence without loop
if(m.instr && m.instr <= loopInfo.size())
{
STPLoopList &loopList = loopInfo[m.instr - 1];
m.param--;
if(m.param < std::min(std::size(ModSample().cues), loopList.size()))
{
m.volcmd = VOLCMD_OFFSET;
m.vol = m.param;
}
// switch to non-looped version of sample and create it if needed
if(!nonLooped[m.instr - 1] && CanAddMoreSamples())
nonLooped[m.instr - 1] = ++m_nSamples;
m.instr = static_cast<ModCommand::INSTR>(nonLooped[m.instr - 1]);
}
m.command = CMD_NONE;
break;
case 0x19: // play only loop nn without loop
if(m.instr && m.instr <= loopInfo.size())
{
STPLoopList &loopList = loopInfo[m.instr - 1];
m.param--;
if(m.param < loopList.size())
{
if(!loopList[m.param].nonLooped && CanAddMoreSamples())
loopList[m.param].nonLooped = ++m_nSamples;
m.instr = static_cast<ModCommand::INSTR>(loopList[m.param].nonLooped);
}
}
m.command = CMD_NONE;
break;
case 0x1D: // fine volume slide (nibble order also swapped)
m.command = CMD_VOLUMESLIDE;
m.param = swapped;
if(m.param & 0xF0) // slide down
m.param |= 0x0F;
else if(m.param & 0x0F)
m.param |= 0xF0;
break;
case 0x20: // "delayed fade"
// just behave like either a normal fade or a notecut
// depending on the speed
if(m.param & 0xF0)
{
chnMem.autoVolSlide = m.param >> 4;
m.command = CMD_NONE;
} else
{
m.command = CMD_MODCMDEX;
m.param = 0xC0 | (m.param & 0xF);
}
break;
case 0x21: // note delay
m.command = CMD_MODCMDEX;
m.param = 0xD0 | std::min(m.param, ModCommand::PARAM(15));
break;
case 0x22: // retrigger note
m.command = CMD_MODCMDEX;
m.param = 0x90 | std::min(m.param, ModCommand::PARAM(15));
break;
case 0x49: // set sample offset
m.command = CMD_OFFSET;
break;
case 0x4E: // other protracker commands (pattern loop / delay)
if((m.param & 0xF0) == 0x60 || (m.param & 0xF0) == 0xE0)
m.command = CMD_MODCMDEX;
else
m.command = CMD_NONE;
break;
case 0x4F: // set speed/tempo
if(m.param < 0x20)
{
m.command = CMD_SPEED;
speedFrac = 0;
} else
{
m.command = CMD_TEMPO;
}
break;
default:
m.command = CMD_NONE;
break;
}
bool didVolSlide = false;
// try to put volume slide in volume command
if(chnMem.autoVolSlide && m.volcmd == VOLCMD_NONE)
{
if(chnMem.autoVolSlide & 0xF0)
{
m.volcmd = VOLCMD_FINEVOLUP;
m.vol = chnMem.autoVolSlide >> 4;
} else
{
m.volcmd = VOLCMD_FINEVOLDOWN;
m.vol = chnMem.autoVolSlide & 0xF;
}
didVolSlide = true;
}
// try to place/combine all remaining running effects.
if(m.command == CMD_NONE)
{
if(chnMem.autoPortaUp)
{
m.command = CMD_PORTAMENTOUP;
m.param = chnMem.autoPortaUp;
} else if(chnMem.autoPortaDown)
{
m.command = CMD_PORTAMENTODOWN;
m.param = chnMem.autoPortaDown;
} else if(chnMem.autoFinePorta)
{
m.command = CMD_MODCMDEX;
m.param = chnMem.autoFinePorta;
} else if(chnMem.autoTonePorta)
{
m.command = CMD_TONEPORTAMENTO;
m.param = chnMem.tonePortaMem = chnMem.autoTonePorta;
} else if(chnMem.autoVibrato)
{
m.command = CMD_VIBRATO;
m.param = chnMem.vibratoMem = chnMem.autoVibrato;
} else if(!didVolSlide && chnMem.autoVolSlide)
{
m.command = CMD_VOLUMESLIDE;
m.param = chnMem.autoVolSlide;
// convert to a "fine" value by setting the other nibble to 0xF
if(m.param & 0x0F)
m.param |= 0xF0;
else if(m.param & 0xF0)
m.param |= 0x0F;
didVolSlide = true;
} else if(chnMem.autoTremolo)
{
m.command = CMD_TREMOLO;
m.param = chnMem.autoTremolo;
} else if(shouldDelay)
{
// insert a fine pattern delay here
m.command = CMD_S3MCMDEX;
m.param = 0x61;
shouldDelay = false;
} else if(!didGlobalVolSlide && globalVolSlide)
{
m.command = CMD_GLOBALVOLSLIDE;
m.param = globalVolSlide;
// convert to a "fine" value by setting the other nibble to 0xF
if(m.param & 0x0F)
m.param |= 0xF0;
else if(m.param & 0xF0)
m.param |= 0x0F;
didGlobalVolSlide = true;
}
}
}
// TODO: create/use extra channels for global volslide/delay if needed
}
}
// after we know how many channels there really are...
m_nSamplePreAmp = 256 / m_nChannels;
// Setup channel pan positions and volume
SetupMODPanning(true);
// Skip over scripts and drumpad info
if(fileHeader.version > 0)
{
while(file.CanRead(2))
{
uint16 scriptNum = file.ReadUint16BE();
if(scriptNum == 0xFFFF)
break;
file.Skip(2);
uint32 length = file.ReadUint32BE();
file.Skip(length);
}
// Skip drumpad stuff
file.Skip(17 * 2);
}
// Reading samples
if(loadFlags & loadSampleData)
{
for(SAMPLEINDEX smp = 1; smp <= samplesInFile; smp++) if(Samples[smp].nLength)
{
SampleIO(
SampleIO::_8bit,
SampleIO::mono,
SampleIO::littleEndian,
SampleIO::signedPCM)
.ReadSample(Samples[smp], file);
if(smp > loopInfo.size())
continue;
ConvertLoopSequence(Samples[smp], loopInfo[smp - 1]);
// make a non-looping duplicate of this sample if needed
if(nonLooped[smp - 1])
{
ConvertLoopSlice(Samples[smp], Samples[nonLooped[smp - 1]], 0, Samples[smp].nLength, false);
}
for(const auto &info : loopInfo[smp - 1])
{
// make duplicate samples for this individual section if needed
if(info.looped)
{
ConvertLoopSlice(Samples[smp], Samples[info.looped], info.loopStart, info.loopLength, true);
}
if(info.nonLooped)
{
ConvertLoopSlice(Samples[smp], Samples[info.nonLooped], info.loopStart, info.loopLength, false);
}
}
}
}
return true;
}
OPENMPT_NAMESPACE_END