386 lines
10 KiB
C++
386 lines
10 KiB
C++
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/*
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* Load_mus_km.cpp
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* ---------------
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* Purpose: Karl Morton Music Format module loader
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* Notes : This is probably not the official name of this format.
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* Karl Morton's engine has been used in Psycho Pinball and Micro Machines 2 and also Back To Baghdad
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* but the latter game only uses its sound effect format, not the music format.
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* So there are only two known games using this music format, and no official tools or documentation are available.
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* Authors: OpenMPT Devs
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* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
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*/
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#include "stdafx.h"
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#include "Loaders.h"
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OPENMPT_NAMESPACE_BEGIN
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struct KMChunkHeader
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{
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// 32-Bit chunk identifiers
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enum ChunkIdentifiers
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{
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idSONG = MagicLE("SONG"),
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idSMPL = MagicLE("SMPL"),
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};
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uint32le id; // See ChunkIdentifiers
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uint32le length; // Chunk size including header
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size_t GetLength() const
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{
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return length <= 8 ? 0 : (length - 8);
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}
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ChunkIdentifiers GetID() const
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{
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return static_cast<ChunkIdentifiers>(id.get());
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}
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};
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MPT_BINARY_STRUCT(KMChunkHeader, 8)
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struct KMSampleHeader
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{
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char name[32];
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uint32le loopStart;
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uint32le size;
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};
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MPT_BINARY_STRUCT(KMSampleHeader, 40)
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struct KMSampleReference
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{
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char name[32];
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uint8 finetune;
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uint8 volume;
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};
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MPT_BINARY_STRUCT(KMSampleReference, 34)
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struct KMSongHeader
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{
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char name[32];
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KMSampleReference samples[31];
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uint16le unknown; // always 0
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uint32le numChannels;
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uint32le restartPos;
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uint32le musicSize;
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};
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MPT_BINARY_STRUCT(KMSongHeader, 32 + 31 * 34 + 14)
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struct KMFileHeader
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{
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KMChunkHeader chunkHeader;
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KMSongHeader songHeader;
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};
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MPT_BINARY_STRUCT(KMFileHeader, sizeof(KMChunkHeader) + sizeof(KMSongHeader))
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static uint64 GetHeaderMinimumAdditionalSize(const KMFileHeader &fileHeader)
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{
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// Require room for at least one more sample chunk header
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return static_cast<uint64>(fileHeader.songHeader.musicSize) + sizeof(KMChunkHeader);
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}
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// Check if string only contains printable characters and doesn't contain any garbage after the required terminating null
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static bool IsValidKMString(const char (&str)[32])
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{
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bool nullFound = false;
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for(char c : str)
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{
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if(c > 0x00 && c < 0x20)
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return false;
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else if(c == 0x00)
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nullFound = true;
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else if(nullFound)
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return false;
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}
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return nullFound;
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}
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static bool ValidateHeader(const KMFileHeader &fileHeader)
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{
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if(fileHeader.chunkHeader.id != KMChunkHeader::idSONG
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|| fileHeader.chunkHeader.length < sizeof(fileHeader)
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|| fileHeader.chunkHeader.length - sizeof(fileHeader) != fileHeader.songHeader.musicSize
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|| fileHeader.chunkHeader.length > 0x40000 // That's enough space for 256 crammed 64-row patterns ;)
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|| fileHeader.songHeader.unknown != 0
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|| fileHeader.songHeader.numChannels < 1
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|| fileHeader.songHeader.numChannels > 4 // Engine rejects anything above 32, channels 5 to 32 are simply ignored
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|| !IsValidKMString(fileHeader.songHeader.name))
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{
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return false;
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}
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for(const auto &sample : fileHeader.songHeader.samples)
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{
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if(sample.finetune > 15 || sample.volume > 64 || !IsValidKMString(sample.name))
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return false;
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}
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return true;
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}
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CSoundFile::ProbeResult CSoundFile::ProbeFileHeaderMUS_KM(MemoryFileReader file, const uint64 *pfilesize)
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{
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KMFileHeader fileHeader;
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if(!file.Read(fileHeader))
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return ProbeWantMoreData;
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if(!ValidateHeader(fileHeader))
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return ProbeFailure;
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return ProbeAdditionalSize(file, pfilesize, GetHeaderMinimumAdditionalSize(fileHeader));
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}
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bool CSoundFile::ReadMUS_KM(FileReader &file, ModLoadingFlags loadFlags)
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{
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{
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file.Rewind();
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KMFileHeader fileHeader;
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if(!file.Read(fileHeader))
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return false;
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if(!ValidateHeader(fileHeader))
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return false;
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if(!file.CanRead(mpt::saturate_cast<FileReader::off_t>(GetHeaderMinimumAdditionalSize(fileHeader))))
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return false;
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if(loadFlags == onlyVerifyHeader)
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return true;
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}
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file.Rewind();
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const auto chunks = ChunkReader(file).ReadChunks<KMChunkHeader>(1);
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auto songChunks = chunks.GetAllChunks(KMChunkHeader::idSONG);
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auto sampleChunks = chunks.GetAllChunks(KMChunkHeader::idSMPL);
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if(songChunks.empty() || sampleChunks.empty())
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return false;
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InitializeGlobals(MOD_TYPE_MOD);
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InitializeChannels();
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m_SongFlags = SONG_AMIGALIMITS | SONG_IMPORTED | SONG_ISAMIGA; // Yes, those were not Amiga games but the format fully conforms to Amiga limits, so allow the Amiga Resampler to be used.
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m_nChannels = 4;
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m_nSamples = 0;
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static constexpr uint16 MUS_SAMPLE_UNUSED = 255; // Sentinel value to check if a sample needs to be duplicated
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for(auto &chunk : sampleChunks)
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{
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if(!CanAddMoreSamples())
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break;
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m_nSamples++;
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ModSample &mptSample = Samples[m_nSamples];
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mptSample.Initialize(MOD_TYPE_MOD);
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KMSampleHeader sampleHeader;
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if(!chunk.Read(sampleHeader)
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|| !IsValidKMString(sampleHeader.name))
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return false;
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m_szNames[m_nSamples] = sampleHeader.name;
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mptSample.nLoopEnd = mptSample.nLength = sampleHeader.size;
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mptSample.nLoopStart = sampleHeader.loopStart;
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mptSample.uFlags.set(CHN_LOOP);
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mptSample.nVolume = MUS_SAMPLE_UNUSED;
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if(!(loadFlags & loadSampleData))
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continue;
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SampleIO(SampleIO::_8bit,
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SampleIO::mono,
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SampleIO::littleEndian,
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SampleIO::signedPCM)
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.ReadSample(mptSample, chunk);
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}
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bool firstSong = true;
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for(auto &chunk : songChunks)
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{
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if(!firstSong && !Order.AddSequence())
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break;
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firstSong = false;
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Order().clear();
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KMSongHeader songHeader;
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if(!chunk.Read(songHeader)
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|| songHeader.unknown != 0
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|| songHeader.numChannels < 1
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|| songHeader.numChannels > 4)
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return false;
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Order().SetName(mpt::ToUnicode(mpt::Charset::CP437, songHeader.name));
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FileReader musicData = (loadFlags & loadPatternData) ? chunk.ReadChunk(songHeader.musicSize) : FileReader{};
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// Map the samples for this subsong
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std::array<SAMPLEINDEX, 32> sampleMap{};
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for(uint8 smp = 1; smp <= 31; smp++)
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{
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const auto &srcSample = songHeader.samples[smp - 1];
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const auto srcName = mpt::String::ReadAutoBuf(srcSample.name);
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if(srcName.empty())
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continue;
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if(srcSample.finetune > 15 || srcSample.volume > 64 || !IsValidKMString(srcSample.name))
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return false;
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const auto finetune = MOD2XMFineTune(srcSample.finetune);
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const uint16 volume = srcSample.volume * 4u;
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SAMPLEINDEX copyFrom = 0;
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for(SAMPLEINDEX srcSmp = 1; srcSmp <= m_nSamples; srcSmp++)
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{
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if(srcName != m_szNames[srcSmp])
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continue;
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auto &mptSample = Samples[srcSmp];
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sampleMap[smp] = srcSmp;
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if(mptSample.nVolume == MUS_SAMPLE_UNUSED
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|| (mptSample.nFineTune == finetune && mptSample.nVolume == volume))
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{
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// Sample was not used yet, or it uses the same finetune and volume
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mptSample.nFineTune = finetune;
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mptSample.nVolume = volume;
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copyFrom = 0;
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break;
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} else
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{
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copyFrom = srcSmp;
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}
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}
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if(copyFrom && CanAddMoreSamples())
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{
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m_nSamples++;
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sampleMap[smp] = m_nSamples;
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const auto &smpFrom = Samples[copyFrom];
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auto &newSample = Samples[m_nSamples];
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newSample.FreeSample();
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newSample = smpFrom;
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newSample.nFineTune = finetune;
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newSample.nVolume = volume;
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newSample.CopyWaveform(smpFrom);
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m_szNames[m_nSamples] = m_szNames[copyFrom];
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}
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}
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struct ChannelState
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{
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ModCommand prevCommand;
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uint8 repeat = 0;
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};
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std::array<ChannelState, 4> chnStates{};
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static constexpr ROWINDEX MUS_PATTERN_LENGTH = 64;
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const CHANNELINDEX numChannels = static_cast<CHANNELINDEX>(songHeader.numChannels);
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PATTERNINDEX pat = PATTERNINDEX_INVALID;
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ROWINDEX row = MUS_PATTERN_LENGTH;
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ROWINDEX restartRow = 0;
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uint32 repeatsLeft = 0;
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while(repeatsLeft || musicData.CanRead(1))
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{
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row++;
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if(row >= MUS_PATTERN_LENGTH)
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{
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pat = Patterns.InsertAny(MUS_PATTERN_LENGTH);
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if(pat == PATTERNINDEX_INVALID)
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break;
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Order().push_back(pat);
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row = 0;
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}
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ModCommand *m = Patterns[pat].GetpModCommand(row, 0);
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for(CHANNELINDEX chn = 0; chn < numChannels; chn++, m++)
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{
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auto &chnState = chnStates[chn];
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if(chnState.repeat)
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{
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chnState.repeat--;
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repeatsLeft--;
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*m = chnState.prevCommand;
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continue;
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}
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if(!musicData.CanRead(1))
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continue;
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if(musicData.GetPosition() == songHeader.restartPos)
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{
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Order().SetRestartPos(Order().GetLastIndex());
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restartRow = row;
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}
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const uint8 note = musicData.ReadUint8();
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if(note & 0x80)
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{
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chnState.repeat = note & 0x7F;
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repeatsLeft += chnState.repeat;
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*m = chnState.prevCommand;
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continue;
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}
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if(note > 0 && note <= 3 * 12)
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m->note = note + NOTE_MIDDLEC - 13;
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const auto instr = musicData.ReadUint8();
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m->instr = static_cast<ModCommand::INSTR>(sampleMap[instr & 0x1F]);
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if(instr & 0x80)
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{
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m->command = chnState.prevCommand.command;
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m->param = chnState.prevCommand.param;
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} else
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{
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static constexpr struct { ModCommand::COMMAND command; uint8 mask; } effTrans[] =
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{
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{CMD_VOLUME, 0x00}, {CMD_MODCMDEX, 0xA0}, {CMD_MODCMDEX, 0xB0}, {CMD_MODCMDEX, 0x10},
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{CMD_MODCMDEX, 0x20}, {CMD_MODCMDEX, 0x50}, {CMD_OFFSET, 0x00}, {CMD_TONEPORTAMENTO, 0x00},
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{CMD_TONEPORTAVOL, 0x00}, {CMD_VIBRATO, 0x00}, {CMD_VIBRATOVOL, 0x00}, {CMD_ARPEGGIO, 0x00},
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{CMD_PORTAMENTOUP, 0x00}, {CMD_PORTAMENTODOWN, 0x00}, {CMD_VOLUMESLIDE, 0x00}, {CMD_MODCMDEX, 0x90},
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{CMD_TONEPORTAMENTO, 0xFF}, {CMD_MODCMDEX, 0xC0}, {CMD_SPEED, 0x00}, {CMD_TREMOLO, 0x00},
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};
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const auto [command, param] = musicData.ReadArray<uint8, 2>();
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if(command < std::size(effTrans))
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{
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m->command = effTrans[command].command;
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m->param = param;
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if(m->command == CMD_SPEED && m->param >= 0x20)
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m->command = CMD_TEMPO;
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else if(effTrans[command].mask)
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m->param = effTrans[command].mask | (m->param & 0x0F);
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}
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}
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chnState.prevCommand = *m;
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}
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}
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if((restartRow != 0 || row < (MUS_PATTERN_LENGTH - 1u)) && pat != PATTERNINDEX_INVALID)
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{
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Patterns[pat].WriteEffect(EffectWriter(CMD_PATTERNBREAK, static_cast<ModCommand::PARAM>(restartRow)).Row(row).RetryNextRow());
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}
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}
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Order.SetSequence(0);
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m_modFormat.formatName = U_("Karl Morton Music Format");
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m_modFormat.type = U_("mus");
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m_modFormat.charset = mpt::Charset::CP437;
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return true;
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}
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OPENMPT_NAMESPACE_END
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