/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2020 - Raw Material Software Limited JUCE is an open source library subject to commercial or open-source licensing. The code included in this file is provided under the terms of the ISC license http://www.isc.org/downloads/software-support-policy/isc-license. Permission To use, copy, modify, and/or distribute this software for any purpose with or without fee is hereby granted provided that the above copyright notice and this permission notice appear in all copies. JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { namespace MidiFileHelpers { static void writeVariableLengthInt (OutputStream& out, uint32 v) { auto buffer = v & 0x7f; while ((v >>= 7) != 0) { buffer <<= 8; buffer |= ((v & 0x7f) | 0x80); } for (;;) { out.writeByte ((char) buffer); if (buffer & 0x80) buffer >>= 8; else break; } } template struct Optional { Optional() = default; Optional (const Value& v) : value (v), valid (true) {} Value value = Value(); bool valid = false; }; template struct ReadTrait; template <> struct ReadTrait { static constexpr auto read = ByteOrder::bigEndianInt; }; template <> struct ReadTrait { static constexpr auto read = ByteOrder::bigEndianShort; }; template Optional tryRead (const uint8*& data, size_t& remaining) { using Trait = ReadTrait; constexpr auto size = sizeof (Integral); if (remaining < size) return {}; const Optional result { Trait::read (data) }; data += size; remaining -= size; return result; } struct HeaderDetails { size_t bytesRead = 0; short timeFormat = 0; short fileType = 0; short numberOfTracks = 0; }; static Optional parseMidiHeader (const uint8* const initialData, const size_t maxSize) { auto* data = initialData; auto remaining = maxSize; auto ch = tryRead (data, remaining); if (! ch.valid) return {}; if (ch.value != ByteOrder::bigEndianInt ("MThd")) { auto ok = false; if (ch.value == ByteOrder::bigEndianInt ("RIFF")) { for (int i = 0; i < 8; ++i) { ch = tryRead (data, remaining); if (! ch.valid) return {}; if (ch.value == ByteOrder::bigEndianInt ("MThd")) { ok = true; break; } } } if (! ok) return {}; } const auto bytesRemaining = tryRead (data, remaining); if (! bytesRemaining.valid || bytesRemaining.value > remaining) return {}; const auto optFileType = tryRead (data, remaining); if (! optFileType.valid || 2 < optFileType.value) return {}; const auto optNumTracks = tryRead (data, remaining); if (! optNumTracks.valid || (optFileType.value == 0 && optNumTracks.value != 1)) return {}; const auto optTimeFormat = tryRead (data, remaining); if (! optTimeFormat.valid) return {}; HeaderDetails result; result.fileType = (short) optFileType.value; result.timeFormat = (short) optTimeFormat.value; result.numberOfTracks = (short) optNumTracks.value; result.bytesRead = maxSize - remaining; return { result }; } static double convertTicksToSeconds (double time, const MidiMessageSequence& tempoEvents, int timeFormat) { if (timeFormat < 0) return time / (-(timeFormat >> 8) * (timeFormat & 0xff)); double lastTime = 0, correctedTime = 0; auto tickLen = 1.0 / (timeFormat & 0x7fff); auto secsPerTick = 0.5 * tickLen; auto numEvents = tempoEvents.getNumEvents(); for (int i = 0; i < numEvents; ++i) { auto& m = tempoEvents.getEventPointer(i)->message; auto eventTime = m.getTimeStamp(); if (eventTime >= time) break; correctedTime += (eventTime - lastTime) * secsPerTick; lastTime = eventTime; if (m.isTempoMetaEvent()) secsPerTick = tickLen * m.getTempoSecondsPerQuarterNote(); while (i + 1 < numEvents) { auto& m2 = tempoEvents.getEventPointer(i + 1)->message; if (m2.getTimeStamp() != eventTime) break; if (m2.isTempoMetaEvent()) secsPerTick = tickLen * m2.getTempoSecondsPerQuarterNote(); ++i; } } return correctedTime + (time - lastTime) * secsPerTick; } template static void findAllMatchingEvents (const OwnedArray& tracks, MidiMessageSequence& results, MethodType method) { for (auto* track : tracks) { auto numEvents = track->getNumEvents(); for (int j = 0; j < numEvents; ++j) { auto& m = track->getEventPointer(j)->message; if ((m.*method)()) results.addEvent (m); } } } static MidiMessageSequence readTrack (const uint8* data, int size) { double time = 0; uint8 lastStatusByte = 0; MidiMessageSequence result; while (size > 0) { const auto delay = MidiMessage::readVariableLengthValue (data, (int) size); if (! delay.isValid()) break; data += delay.bytesUsed; size -= delay.bytesUsed; time += delay.value; if (size <= 0) break; int messSize = 0; const MidiMessage mm (data, size, messSize, lastStatusByte, time); if (messSize <= 0) break; size -= messSize; data += messSize; result.addEvent (mm); auto firstByte = *(mm.getRawData()); if ((firstByte & 0xf0) != 0xf0) lastStatusByte = firstByte; } return result; } } //============================================================================== MidiFile::MidiFile() : timeFormat ((short) (unsigned short) 0xe728) {} MidiFile::~MidiFile() {} MidiFile::MidiFile (const MidiFile& other) : timeFormat (other.timeFormat) { tracks.addCopiesOf (other.tracks); } MidiFile& MidiFile::operator= (const MidiFile& other) { tracks.clear(); tracks.addCopiesOf (other.tracks); timeFormat = other.timeFormat; return *this; } MidiFile::MidiFile (MidiFile&& other) : tracks (std::move (other.tracks)), timeFormat (other.timeFormat) { } MidiFile& MidiFile::operator= (MidiFile&& other) { tracks = std::move (other.tracks); timeFormat = other.timeFormat; return *this; } void MidiFile::clear() { tracks.clear(); } //============================================================================== int MidiFile::getNumTracks() const noexcept { return tracks.size(); } const MidiMessageSequence* MidiFile::getTrack (int index) const noexcept { return tracks[index]; } void MidiFile::addTrack (const MidiMessageSequence& trackSequence) { tracks.add (new MidiMessageSequence (trackSequence)); } //============================================================================== short MidiFile::getTimeFormat() const noexcept { return timeFormat; } void MidiFile::setTicksPerQuarterNote (int ticks) noexcept { timeFormat = (short) ticks; } void MidiFile::setSmpteTimeFormat (int framesPerSecond, int subframeResolution) noexcept { timeFormat = (short) (((-framesPerSecond) << 8) | subframeResolution); } //============================================================================== void MidiFile::findAllTempoEvents (MidiMessageSequence& results) const { MidiFileHelpers::findAllMatchingEvents (tracks, results, &MidiMessage::isTempoMetaEvent); } void MidiFile::findAllTimeSigEvents (MidiMessageSequence& results) const { MidiFileHelpers::findAllMatchingEvents (tracks, results, &MidiMessage::isTimeSignatureMetaEvent); } void MidiFile::findAllKeySigEvents (MidiMessageSequence& results) const { MidiFileHelpers::findAllMatchingEvents (tracks, results, &MidiMessage::isKeySignatureMetaEvent); } double MidiFile::getLastTimestamp() const { double t = 0.0; for (auto* ms : tracks) t = jmax (t, ms->getEndTime()); return t; } //============================================================================== bool MidiFile::readFrom (InputStream& sourceStream, bool createMatchingNoteOffs, int* fileType) { clear(); MemoryBlock data; const int maxSensibleMidiFileSize = 200 * 1024 * 1024; // (put a sanity-check on the file size, as midi files are generally small) if (! sourceStream.readIntoMemoryBlock (data, maxSensibleMidiFileSize)) return false; auto size = data.getSize(); auto d = static_cast (data.getData()); const auto optHeader = MidiFileHelpers::parseMidiHeader (d, size); if (! optHeader.valid) return false; const auto header = optHeader.value; timeFormat = header.timeFormat; d += header.bytesRead; size -= (size_t) header.bytesRead; for (int track = 0; track < header.numberOfTracks; ++track) { const auto optChunkType = MidiFileHelpers::tryRead (d, size); if (! optChunkType.valid) return false; const auto optChunkSize = MidiFileHelpers::tryRead (d, size); if (! optChunkSize.valid) return false; const auto chunkSize = optChunkSize.value; if (size < chunkSize) return false; if (optChunkType.value == ByteOrder::bigEndianInt ("MTrk")) readNextTrack (d, (int) chunkSize, createMatchingNoteOffs); size -= chunkSize; d += chunkSize; } const auto successful = (size == 0); if (successful && fileType != nullptr) *fileType = header.fileType; return successful; } void MidiFile::readNextTrack (const uint8* data, int size, bool createMatchingNoteOffs) { auto sequence = MidiFileHelpers::readTrack (data, size); // sort so that we put all the note-offs before note-ons that have the same time std::stable_sort (sequence.list.begin(), sequence.list.end(), [] (const MidiMessageSequence::MidiEventHolder* a, const MidiMessageSequence::MidiEventHolder* b) { auto t1 = a->message.getTimeStamp(); auto t2 = b->message.getTimeStamp(); if (t1 < t2) return true; if (t2 < t1) return false; return a->message.isNoteOff() && b->message.isNoteOn(); }); if (createMatchingNoteOffs) sequence.updateMatchedPairs(); addTrack (sequence); } //============================================================================== void MidiFile::convertTimestampTicksToSeconds() { MidiMessageSequence tempoEvents; findAllTempoEvents (tempoEvents); findAllTimeSigEvents (tempoEvents); if (timeFormat != 0) { for (auto* ms : tracks) { for (int j = ms->getNumEvents(); --j >= 0;) { auto& m = ms->getEventPointer(j)->message; m.setTimeStamp (MidiFileHelpers::convertTicksToSeconds (m.getTimeStamp(), tempoEvents, timeFormat)); } } } } //============================================================================== bool MidiFile::writeTo (OutputStream& out, int midiFileType) const { jassert (midiFileType >= 0 && midiFileType <= 2); if (! out.writeIntBigEndian ((int) ByteOrder::bigEndianInt ("MThd"))) return false; if (! out.writeIntBigEndian (6)) return false; if (! out.writeShortBigEndian ((short) midiFileType)) return false; if (! out.writeShortBigEndian ((short) tracks.size())) return false; if (! out.writeShortBigEndian (timeFormat)) return false; for (auto* ms : tracks) if (! writeTrack (out, *ms)) return false; out.flush(); return true; } bool MidiFile::writeTrack (OutputStream& mainOut, const MidiMessageSequence& ms) const { MemoryOutputStream out; int lastTick = 0; uint8 lastStatusByte = 0; bool endOfTrackEventWritten = false; for (int i = 0; i < ms.getNumEvents(); ++i) { auto& mm = ms.getEventPointer(i)->message; if (mm.isEndOfTrackMetaEvent()) endOfTrackEventWritten = true; auto tick = roundToInt (mm.getTimeStamp()); auto delta = jmax (0, tick - lastTick); MidiFileHelpers::writeVariableLengthInt (out, (uint32) delta); lastTick = tick; auto* data = mm.getRawData(); auto dataSize = mm.getRawDataSize(); auto statusByte = data[0]; if (statusByte == lastStatusByte && (statusByte & 0xf0) != 0xf0 && dataSize > 1 && i > 0) { ++data; --dataSize; } else if (statusByte == 0xf0) // Write sysex message with length bytes. { out.writeByte ((char) statusByte); ++data; --dataSize; MidiFileHelpers::writeVariableLengthInt (out, (uint32) dataSize); } out.write (data, (size_t) dataSize); lastStatusByte = statusByte; } if (! endOfTrackEventWritten) { out.writeByte (0); // (tick delta) auto m = MidiMessage::endOfTrack(); out.write (m.getRawData(), (size_t) m.getRawDataSize()); } if (! mainOut.writeIntBigEndian ((int) ByteOrder::bigEndianInt ("MTrk"))) return false; if (! mainOut.writeIntBigEndian ((int) out.getDataSize())) return false; mainOut << out; return true; } //============================================================================== //============================================================================== #if JUCE_UNIT_TESTS struct MidiFileTest : public UnitTest { MidiFileTest() : UnitTest ("MidiFile", UnitTestCategories::midi) {} void runTest() override { beginTest ("ReadTrack respects running status"); { const auto sequence = parseSequence ([] (OutputStream& os) { MidiFileHelpers::writeVariableLengthInt (os, 100); writeBytes (os, { 0x90, 0x40, 0x40 }); MidiFileHelpers::writeVariableLengthInt (os, 200); writeBytes (os, { 0x40, 0x40 }); MidiFileHelpers::writeVariableLengthInt (os, 300); writeBytes (os, { 0xff, 0x2f, 0x00 }); }); expectEquals (sequence.getNumEvents(), 3); expect (sequence.getEventPointer (0)->message.isNoteOn()); expect (sequence.getEventPointer (1)->message.isNoteOn()); expect (sequence.getEventPointer (2)->message.isEndOfTrackMetaEvent()); } beginTest ("ReadTrack returns available messages if input is truncated"); { { const auto sequence = parseSequence ([] (OutputStream& os) { // Incomplete delta time writeBytes (os, { 0xff }); }); expectEquals (sequence.getNumEvents(), 0); } { const auto sequence = parseSequence ([] (OutputStream& os) { // Complete delta with no following event MidiFileHelpers::writeVariableLengthInt (os, 0xffff); }); expectEquals (sequence.getNumEvents(), 0); } { const auto sequence = parseSequence ([] (OutputStream& os) { // Complete delta with malformed following event MidiFileHelpers::writeVariableLengthInt (os, 0xffff); writeBytes (os, { 0x90, 0x40 }); }); expectEquals (sequence.getNumEvents(), 1); expect (sequence.getEventPointer (0)->message.isNoteOff()); expectEquals (sequence.getEventPointer (0)->message.getNoteNumber(), 0x40); expectEquals (sequence.getEventPointer (0)->message.getVelocity(), (uint8) 0x00); } } beginTest ("Header parsing works"); { { // No data const auto header = parseHeader ([] (OutputStream&) {}); expect (! header.valid); } { // Invalid initial byte const auto header = parseHeader ([] (OutputStream& os) { writeBytes (os, { 0xff }); }); expect (! header.valid); } { // Type block, but no header data const auto header = parseHeader ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd' }); }); expect (! header.valid); } { // We (ll-formed header, but track type is 0 and channels != 1 const auto header = parseHeader ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 0, 0, 16, 0, 1 }); }); expect (! header.valid); } { // Well-formed header, but track type is 5 const auto header = parseHeader ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 5, 0, 16, 0, 1 }); }); expect (! header.valid); } { // Well-formed header const auto header = parseHeader ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1, 0, 16, 0, 1 }); }); expect (header.valid); expectEquals (header.value.fileType, (short) 1); expectEquals (header.value.numberOfTracks, (short) 16); expectEquals (header.value.timeFormat, (short) 1); expectEquals ((int) header.value.bytesRead, 14); } } beginTest ("Read from stream"); { { // Empty input const auto file = parseFile ([] (OutputStream&) {}); expect (! file.valid); } { // Malformed header const auto file = parseFile ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd' }); }); expect (! file.valid); } { // Header, no channels const auto file = parseFile ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1, 0, 0, 0, 1 }); }); expect (file.valid); expectEquals (file.value.getNumTracks(), 0); } { // Header, one malformed channel const auto file = parseFile ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1, 0, 1, 0, 1 }); writeBytes (os, { 'M', 'T', 'r', '?' }); }); expect (! file.valid); } { // Header, one channel with malformed message const auto file = parseFile ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1, 0, 1, 0, 1 }); writeBytes (os, { 'M', 'T', 'r', 'k', 0, 0, 0, 1, 0xff }); }); expect (file.valid); expectEquals (file.value.getNumTracks(), 1); expectEquals (file.value.getTrack (0)->getNumEvents(), 0); } { // Header, one channel with incorrect length message const auto file = parseFile ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1, 0, 1, 0, 1 }); writeBytes (os, { 'M', 'T', 'r', 'k', 0x0f, 0, 0, 0, 0xff }); }); expect (! file.valid); } { // Header, one channel, all well-formed const auto file = parseFile ([] (OutputStream& os) { writeBytes (os, { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1, 0, 1, 0, 1 }); writeBytes (os, { 'M', 'T', 'r', 'k', 0, 0, 0, 4 }); MidiFileHelpers::writeVariableLengthInt (os, 0x0f); writeBytes (os, { 0x80, 0x00, 0x00 }); }); expect (file.valid); expectEquals (file.value.getNumTracks(), 1); auto& track = *file.value.getTrack (0); expectEquals (track.getNumEvents(), 1); expect (track.getEventPointer (0)->message.isNoteOff()); expectEquals (track.getEventPointer (0)->message.getTimeStamp(), (double) 0x0f); } } } template static MidiMessageSequence parseSequence (Fn&& fn) { MemoryOutputStream os; fn (os); return MidiFileHelpers::readTrack (reinterpret_cast (os.getData()), (int) os.getDataSize()); } template static MidiFileHelpers::Optional parseHeader (Fn&& fn) { MemoryOutputStream os; fn (os); return MidiFileHelpers::parseMidiHeader (reinterpret_cast (os.getData()), os.getDataSize()); } template static MidiFileHelpers::Optional parseFile (Fn&& fn) { MemoryOutputStream os; fn (os); MemoryInputStream is (os.getData(), os.getDataSize(), false); MidiFile mf; int fileType = 0; if (mf.readFrom (is, true, &fileType)) return mf; return {}; } static void writeBytes (OutputStream& os, const std::vector& bytes) { for (const auto& byte : bytes) os.writeByte ((char) byte); } }; static MidiFileTest midiFileTests; #endif } // namespace juce