/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2015 - ROLI Ltd. Permission is granted to use this software under the terms of either: a) the GPL v2 (or any later version) b) the Affero GPL v3 Details of these licenses can be found at: www.gnu.org/licenses JUCE is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. ------------------------------------------------------------------------------ To release a closed-source product which uses JUCE, commercial licenses are available: visit www.juce.com for more information. ============================================================================== */ namespace MidiHelpers { inline uint8 initialByte (const int type, const int channel) noexcept { return (uint8) (type | jlimit (0, 15, channel - 1)); } inline uint8 validVelocity (const int v) noexcept { return (uint8) jlimit (0, 127, v); } inline uint8 floatVelocityToByte (const float v) noexcept { return validVelocity (roundToInt (v * 127.0f)); } } //============================================================================== int MidiMessage::readVariableLengthVal (const uint8* data, int& numBytesUsed) noexcept { numBytesUsed = 0; int v = 0, i; do { i = (int) *data++; if (++numBytesUsed > 6) break; v = (v << 7) + (i & 0x7f); } while (i & 0x80); return v; } int MidiMessage::getMessageLengthFromFirstByte (const uint8 firstByte) noexcept { // this method only works for valid starting bytes of a short midi message jassert (firstByte >= 0x80 && firstByte != 0xf0 && firstByte != 0xf7); static const char messageLengths[] = { 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 1, 2, 3, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }; return messageLengths [firstByte & 0x7f]; } //============================================================================== MidiMessage::MidiMessage() noexcept : timeStamp (0), size (2) { preallocatedData.asBytes[0] = 0xf0; preallocatedData.asBytes[1] = 0xf7; } MidiMessage::MidiMessage (const void* const d, const int dataSize, const double t) : timeStamp (t), size (dataSize) { jassert (dataSize > 0); memcpy (allocateSpace (dataSize), d, (size_t) dataSize); // check that the length matches the data.. jassert (size > 3 || *(uint8*)d >= 0xf0 || getMessageLengthFromFirstByte (*(uint8*)d) == size); } MidiMessage::MidiMessage (const int byte1, const double t) noexcept : timeStamp (t), size (1) { preallocatedData.asBytes[0] = (uint8) byte1; // check that the length matches the data.. jassert (byte1 >= 0xf0 || getMessageLengthFromFirstByte ((uint8) byte1) == 1); } MidiMessage::MidiMessage (const int byte1, const int byte2, const double t) noexcept : timeStamp (t), size (2) { preallocatedData.asBytes[0] = (uint8) byte1; preallocatedData.asBytes[1] = (uint8) byte2; // check that the length matches the data.. jassert (byte1 >= 0xf0 || getMessageLengthFromFirstByte ((uint8) byte1) == 2); } MidiMessage::MidiMessage (const int byte1, const int byte2, const int byte3, const double t) noexcept : timeStamp (t), size (3) { preallocatedData.asBytes[0] = (uint8) byte1; preallocatedData.asBytes[1] = (uint8) byte2; preallocatedData.asBytes[2] = (uint8) byte3; // check that the length matches the data.. jassert (byte1 >= 0xf0 || getMessageLengthFromFirstByte ((uint8) byte1) == 3); } MidiMessage::MidiMessage (const MidiMessage& other) : timeStamp (other.timeStamp), size (other.size) { if (other.allocatedData != nullptr) { allocatedData.malloc ((size_t) size); memcpy (allocatedData, other.allocatedData, (size_t) size); } else { preallocatedData.asInt32 = other.preallocatedData.asInt32; } } MidiMessage::MidiMessage (const MidiMessage& other, const double newTimeStamp) : timeStamp (newTimeStamp), size (other.size) { if (other.allocatedData != nullptr) { allocatedData.malloc ((size_t) size); memcpy (allocatedData, other.allocatedData, (size_t) size); } else { preallocatedData.asInt32 = other.preallocatedData.asInt32; } } MidiMessage::MidiMessage (const void* srcData, int sz, int& numBytesUsed, const uint8 lastStatusByte, double t, bool sysexHasEmbeddedLength) : timeStamp (t) { const uint8* src = static_cast (srcData); unsigned int byte = (unsigned int) *src; if (byte < 0x80) { byte = (unsigned int) (uint8) lastStatusByte; numBytesUsed = -1; } else { numBytesUsed = 0; --sz; ++src; } if (byte >= 0x80) { if (byte == 0xf0) { const uint8* d = src; bool haveReadAllLengthBytes = ! sysexHasEmbeddedLength; int numVariableLengthSysexBytes = 0; while (d < src + sz) { if (*d >= 0x80) { if (*d == 0xf7) { ++d; // include the trailing 0xf7 when we hit it break; } if (haveReadAllLengthBytes) // if we see a 0x80 bit set after the initial data length break; // bytes, assume it's the end of the sysex ++numVariableLengthSysexBytes; } else if (! haveReadAllLengthBytes) { haveReadAllLengthBytes = true; ++numVariableLengthSysexBytes; } ++d; } src += numVariableLengthSysexBytes; size = 1 + (int) (d - src); uint8* dest = allocateSpace (size); *dest = (uint8) byte; memcpy (dest + 1, src, (size_t) (size - 1)); numBytesUsed += numVariableLengthSysexBytes; // (these aren't counted in the size) } else if (byte == 0xff) { int n; const int bytesLeft = readVariableLengthVal (src + 1, n); size = jmin (sz + 1, n + 2 + bytesLeft); uint8* dest = allocateSpace (size); *dest = (uint8) byte; memcpy (dest + 1, src, (size_t) size - 1); } else { preallocatedData.asInt32 = 0; size = getMessageLengthFromFirstByte ((uint8) byte); preallocatedData.asBytes[0] = (uint8) byte; if (size > 1) { preallocatedData.asBytes[1] = src[0]; if (size > 2) preallocatedData.asBytes[2] = src[1]; } } numBytesUsed += size; } else { preallocatedData.asInt32 = 0; size = 0; } } MidiMessage& MidiMessage::operator= (const MidiMessage& other) { if (this != &other) { timeStamp = other.timeStamp; size = other.size; if (other.allocatedData != nullptr) { allocatedData.malloc ((size_t) size); memcpy (allocatedData, other.allocatedData, (size_t) size); } else { allocatedData.free(); preallocatedData.asInt32 = other.preallocatedData.asInt32; } } return *this; } #if JUCE_COMPILER_SUPPORTS_MOVE_SEMANTICS MidiMessage::MidiMessage (MidiMessage&& other) noexcept : timeStamp (other.timeStamp), size (other.size) { if (other.allocatedData != nullptr) allocatedData.swapWith (other.allocatedData); else preallocatedData.asInt32 = other.preallocatedData.asInt32; } MidiMessage& MidiMessage::operator= (MidiMessage&& other) noexcept { jassert (this != &other); // shouldn't be possible timeStamp = other.timeStamp; size = other.size; allocatedData.swapWith (other.allocatedData); preallocatedData.asInt32 = other.preallocatedData.asInt32; return *this; } #endif MidiMessage::~MidiMessage() {} uint8* MidiMessage::allocateSpace (int bytes) { if (bytes > 4) { allocatedData.malloc ((size_t) bytes); return allocatedData; } return preallocatedData.asBytes; } int MidiMessage::getChannel() const noexcept { const uint8* const data = getRawData(); if ((data[0] & 0xf0) != 0xf0) return (data[0] & 0xf) + 1; return 0; } bool MidiMessage::isForChannel (const int channel) const noexcept { jassert (channel > 0 && channel <= 16); // valid channels are numbered 1 to 16 const uint8* const data = getRawData(); return ((data[0] & 0xf) == channel - 1) && ((data[0] & 0xf0) != 0xf0); } void MidiMessage::setChannel (const int channel) noexcept { jassert (channel > 0 && channel <= 16); // valid channels are numbered 1 to 16 uint8* const data = getData(); if ((data[0] & 0xf0) != (uint8) 0xf0) data[0] = (uint8) ((data[0] & (uint8) 0xf0) | (uint8)(channel - 1)); } bool MidiMessage::isNoteOn (const bool returnTrueForVelocity0) const noexcept { const uint8* const data = getRawData(); return ((data[0] & 0xf0) == 0x90) && (returnTrueForVelocity0 || data[2] != 0); } bool MidiMessage::isNoteOff (const bool returnTrueForNoteOnVelocity0) const noexcept { const uint8* const data = getRawData(); return ((data[0] & 0xf0) == 0x80) || (returnTrueForNoteOnVelocity0 && (data[2] == 0) && ((data[0] & 0xf0) == 0x90)); } bool MidiMessage::isNoteOnOrOff() const noexcept { const uint8* const data = getRawData(); const int d = data[0] & 0xf0; return (d == 0x90) || (d == 0x80); } int MidiMessage::getNoteNumber() const noexcept { return getRawData()[1]; } void MidiMessage::setNoteNumber (const int newNoteNumber) noexcept { if (isNoteOnOrOff() || isAftertouch()) getData()[1] = (uint8) (newNoteNumber & 127); } uint8 MidiMessage::getVelocity() const noexcept { if (isNoteOnOrOff()) return getRawData()[2]; return 0; } float MidiMessage::getFloatVelocity() const noexcept { return getVelocity() * (1.0f / 127.0f); } void MidiMessage::setVelocity (const float newVelocity) noexcept { if (isNoteOnOrOff()) getData()[2] = MidiHelpers::floatVelocityToByte (newVelocity); } void MidiMessage::multiplyVelocity (const float scaleFactor) noexcept { if (isNoteOnOrOff()) { uint8* const data = getData(); data[2] = MidiHelpers::validVelocity (roundToInt (scaleFactor * data[2])); } } bool MidiMessage::isAftertouch() const noexcept { return (getRawData()[0] & 0xf0) == 0xa0; } int MidiMessage::getAfterTouchValue() const noexcept { jassert (isAftertouch()); return getRawData()[2]; } MidiMessage MidiMessage::aftertouchChange (const int channel, const int noteNum, const int aftertouchValue) noexcept { jassert (channel > 0 && channel <= 16); // valid channels are numbered 1 to 16 jassert (isPositiveAndBelow (noteNum, (int) 128)); jassert (isPositiveAndBelow (aftertouchValue, (int) 128)); return MidiMessage (MidiHelpers::initialByte (0xa0, channel), noteNum & 0x7f, aftertouchValue & 0x7f); } bool MidiMessage::isChannelPressure() const noexcept { return (getRawData()[0] & 0xf0) == 0xd0; } int MidiMessage::getChannelPressureValue() const noexcept { jassert (isChannelPressure()); return getRawData()[1]; } MidiMessage MidiMessage::channelPressureChange (const int channel, const int pressure) noexcept { jassert (channel > 0 && channel <= 16); // valid channels are numbered 1 to 16 jassert (isPositiveAndBelow (pressure, (int) 128)); return MidiMessage (MidiHelpers::initialByte (0xd0, channel), pressure & 0x7f); } bool MidiMessage::isSustainPedalOn() const noexcept { return isControllerOfType (0x40) && getRawData()[2] >= 64; } bool MidiMessage::isSustainPedalOff() const noexcept { return isControllerOfType (0x40) && getRawData()[2] < 64; } bool MidiMessage::isSostenutoPedalOn() const noexcept { return isControllerOfType (0x42) && getRawData()[2] >= 64; } bool MidiMessage::isSostenutoPedalOff() const noexcept { return isControllerOfType (0x42) && getRawData()[2] < 64; } bool MidiMessage::isSoftPedalOn() const noexcept { return isControllerOfType (0x43) && getRawData()[2] >= 64; } bool MidiMessage::isSoftPedalOff() const noexcept { return isControllerOfType (0x43) && getRawData()[2] < 64; } bool MidiMessage::isProgramChange() const noexcept { return (getRawData()[0] & 0xf0) == 0xc0; } int MidiMessage::getProgramChangeNumber() const noexcept { jassert (isProgramChange()); return getRawData()[1]; } MidiMessage MidiMessage::programChange (const int channel, const int programNumber) noexcept { jassert (channel > 0 && channel <= 16); // valid channels are numbered 1 to 16 return MidiMessage (MidiHelpers::initialByte (0xc0, channel), programNumber & 0x7f); } bool MidiMessage::isPitchWheel() const noexcept { return (getRawData()[0] & 0xf0) == 0xe0; } int MidiMessage::getPitchWheelValue() const noexcept { jassert (isPitchWheel()); const uint8* const data = getRawData(); return data[1] | (data[2] << 7); } MidiMessage MidiMessage::pitchWheel (const int channel, const int position) noexcept { jassert (channel > 0 && channel <= 16); // valid channels are numbered 1 to 16 jassert (isPositiveAndBelow (position, (int) 0x4000)); return MidiMessage (MidiHelpers::initialByte (0xe0, channel), position & 127, (position >> 7) & 127); } bool MidiMessage::isController() const noexcept { return (getRawData()[0] & 0xf0) == 0xb0; } bool MidiMessage::isControllerOfType (const int controllerType) const noexcept { const uint8* const data = getRawData(); return (data[0] & 0xf0) == 0xb0 && data[1] == controllerType; } int MidiMessage::getControllerNumber() const noexcept { jassert (isController()); return getRawData()[1]; } int MidiMessage::getControllerValue() const noexcept { jassert (isController()); return getRawData()[2]; } MidiMessage MidiMessage::controllerEvent (const int channel, const int controllerType, const int value) noexcept { // the channel must be between 1 and 16 inclusive jassert (channel > 0 && channel <= 16); return MidiMessage (MidiHelpers::initialByte (0xb0, channel), controllerType & 127, value & 127); } MidiMessage MidiMessage::noteOn (const int channel, const int noteNumber, const uint8 velocity) noexcept { jassert (channel > 0 && channel <= 16); jassert (isPositiveAndBelow (noteNumber, (int) 128)); return MidiMessage (MidiHelpers::initialByte (0x90, channel), noteNumber & 127, MidiHelpers::validVelocity (velocity)); } MidiMessage MidiMessage::noteOn (const int channel, const int noteNumber, const float velocity) noexcept { return noteOn (channel, noteNumber, MidiHelpers::floatVelocityToByte (velocity)); } MidiMessage MidiMessage::noteOff (const int channel, const int noteNumber, uint8 velocity) noexcept { jassert (channel > 0 && channel <= 16); jassert (isPositiveAndBelow (noteNumber, (int) 128)); return MidiMessage (MidiHelpers::initialByte (0x80, channel), noteNumber & 127, MidiHelpers::validVelocity (velocity)); } MidiMessage MidiMessage::noteOff (const int channel, const int noteNumber, float velocity) noexcept { return noteOff (channel, noteNumber, MidiHelpers::floatVelocityToByte (velocity)); } MidiMessage MidiMessage::noteOff (const int channel, const int noteNumber) noexcept { jassert (channel > 0 && channel <= 16); jassert (isPositiveAndBelow (noteNumber, (int) 128)); return MidiMessage (MidiHelpers::initialByte (0x80, channel), noteNumber & 127, 0); } MidiMessage MidiMessage::allNotesOff (const int channel) noexcept { return controllerEvent (channel, 123, 0); } bool MidiMessage::isAllNotesOff() const noexcept { const uint8* const data = getRawData(); return (data[0] & 0xf0) == 0xb0 && data[1] == 123; } MidiMessage MidiMessage::allSoundOff (const int channel) noexcept { return controllerEvent (channel, 120, 0); } bool MidiMessage::isAllSoundOff() const noexcept { const uint8* const data = getRawData(); return (data[0] & 0xf0) == 0xb0 && data[1] == 120; } MidiMessage MidiMessage::allControllersOff (const int channel) noexcept { return controllerEvent (channel, 121, 0); } MidiMessage MidiMessage::masterVolume (const float volume) { const int vol = jlimit (0, 0x3fff, roundToInt (volume * 0x4000)); const uint8 buf[] = { 0xf0, 0x7f, 0x7f, 0x04, 0x01, (uint8) (vol & 0x7f), (uint8) (vol >> 7), 0xf7 }; return MidiMessage (buf, 8); } //============================================================================== bool MidiMessage::isSysEx() const noexcept { return *getRawData() == 0xf0; } MidiMessage MidiMessage::createSysExMessage (const void* sysexData, const int dataSize) { HeapBlock m ((size_t) dataSize + 2); m[0] = 0xf0; memcpy (m + 1, sysexData, (size_t) dataSize); m[dataSize + 1] = 0xf7; return MidiMessage (m, dataSize + 2); } const uint8* MidiMessage::getSysExData() const noexcept { return isSysEx() ? getRawData() + 1 : nullptr; } int MidiMessage::getSysExDataSize() const noexcept { return isSysEx() ? size - 2 : 0; } //============================================================================== bool MidiMessage::isMetaEvent() const noexcept { return *getRawData() == 0xff; } bool MidiMessage::isActiveSense() const noexcept { return *getRawData() == 0xfe; } int MidiMessage::getMetaEventType() const noexcept { const uint8* const data = getRawData(); return *data != 0xff ? -1 : data[1]; } int MidiMessage::getMetaEventLength() const noexcept { const uint8* const data = getRawData(); if (*data == 0xff) { int n; return jmin (size - 2, readVariableLengthVal (data + 2, n)); } return 0; } const uint8* MidiMessage::getMetaEventData() const noexcept { jassert (isMetaEvent()); int n; const uint8* d = getRawData() + 2; readVariableLengthVal (d, n); return d + n; } bool MidiMessage::isTrackMetaEvent() const noexcept { return getMetaEventType() == 0; } bool MidiMessage::isEndOfTrackMetaEvent() const noexcept { return getMetaEventType() == 47; } bool MidiMessage::isTextMetaEvent() const noexcept { const int t = getMetaEventType(); return t > 0 && t < 16; } String MidiMessage::getTextFromTextMetaEvent() const { const char* const textData = reinterpret_cast (getMetaEventData()); return String (CharPointer_UTF8 (textData), CharPointer_UTF8 (textData + getMetaEventLength())); } MidiMessage MidiMessage::textMetaEvent (int type, StringRef text) { jassert (type > 0 && type < 16); MidiMessage result; const size_t textSize = text.text.sizeInBytes() - 1; uint8 header[8]; size_t n = sizeof (header); header[--n] = (uint8) (textSize & 0x7f); for (size_t i = textSize; (i >>= 7) != 0;) header[--n] = (uint8) ((i & 0x7f) | 0x80); header[--n] = (uint8) type; header[--n] = 0xff; const size_t headerLen = sizeof (header) - n; uint8* const dest = result.allocateSpace ((int) (headerLen + textSize)); result.size = (int) (headerLen + textSize); memcpy (dest, header + n, headerLen); memcpy (dest + headerLen, text.text.getAddress(), textSize); return result; } bool MidiMessage::isTrackNameEvent() const noexcept { const uint8* data = getRawData(); return (data[1] == 3) && (*data == 0xff); } bool MidiMessage::isTempoMetaEvent() const noexcept { const uint8* data = getRawData(); return (data[1] == 81) && (*data == 0xff); } bool MidiMessage::isMidiChannelMetaEvent() const noexcept { const uint8* data = getRawData(); return (data[1] == 0x20) && (*data == 0xff) && (data[2] == 1); } int MidiMessage::getMidiChannelMetaEventChannel() const noexcept { jassert (isMidiChannelMetaEvent()); return getRawData()[3] + 1; } double MidiMessage::getTempoSecondsPerQuarterNote() const noexcept { if (! isTempoMetaEvent()) return 0.0; const uint8* const d = getMetaEventData(); return (((unsigned int) d[0] << 16) | ((unsigned int) d[1] << 8) | d[2]) / 1000000.0; } double MidiMessage::getTempoMetaEventTickLength (const short timeFormat) const noexcept { if (timeFormat > 0) { if (! isTempoMetaEvent()) return 0.5 / timeFormat; return getTempoSecondsPerQuarterNote() / timeFormat; } else { const int frameCode = (-timeFormat) >> 8; double framesPerSecond; switch (frameCode) { case 24: framesPerSecond = 24.0; break; case 25: framesPerSecond = 25.0; break; case 29: framesPerSecond = 29.97; break; case 30: framesPerSecond = 30.0; break; default: framesPerSecond = 30.0; break; } return (1.0 / framesPerSecond) / (timeFormat & 0xff); } } MidiMessage MidiMessage::tempoMetaEvent (int microsecondsPerQuarterNote) noexcept { const uint8 d[] = { 0xff, 81, 3, (uint8) (microsecondsPerQuarterNote >> 16), (uint8) (microsecondsPerQuarterNote >> 8), (uint8) microsecondsPerQuarterNote }; return MidiMessage (d, 6, 0.0); } bool MidiMessage::isTimeSignatureMetaEvent() const noexcept { const uint8* const data = getRawData(); return (data[1] == 0x58) && (*data == (uint8) 0xff); } void MidiMessage::getTimeSignatureInfo (int& numerator, int& denominator) const noexcept { if (isTimeSignatureMetaEvent()) { const uint8* const d = getMetaEventData(); numerator = d[0]; denominator = 1 << d[1]; } else { numerator = 4; denominator = 4; } } MidiMessage MidiMessage::timeSignatureMetaEvent (const int numerator, const int denominator) { int n = 1; int powerOfTwo = 0; while (n < denominator) { n <<= 1; ++powerOfTwo; } const uint8 d[] = { 0xff, 0x58, 0x04, (uint8) numerator, (uint8) powerOfTwo, 1, 96 }; return MidiMessage (d, 7, 0.0); } MidiMessage MidiMessage::midiChannelMetaEvent (const int channel) noexcept { const uint8 d[] = { 0xff, 0x20, 0x01, (uint8) jlimit (0, 0xff, channel - 1) }; return MidiMessage (d, 4, 0.0); } bool MidiMessage::isKeySignatureMetaEvent() const noexcept { return getMetaEventType() == 0x59; } int MidiMessage::getKeySignatureNumberOfSharpsOrFlats() const noexcept { return (int) getMetaEventData()[0]; } bool MidiMessage::isKeySignatureMajorKey() const noexcept { return getMetaEventData()[1] == 0; } MidiMessage MidiMessage::keySignatureMetaEvent (int numberOfSharpsOrFlats, bool isMinorKey) { jassert (numberOfSharpsOrFlats >= -7 && numberOfSharpsOrFlats <= 7); const uint8 d[] = { 0xff, 0x59, 0x02, (uint8) numberOfSharpsOrFlats, isMinorKey ? (uint8) 1 : (uint8) 0 }; return MidiMessage (d, 5, 0.0); } MidiMessage MidiMessage::endOfTrack() noexcept { return MidiMessage (0xff, 0x2f, 0, 0.0); } //============================================================================== bool MidiMessage::isSongPositionPointer() const noexcept { return *getRawData() == 0xf2; } int MidiMessage::getSongPositionPointerMidiBeat() const noexcept { const uint8* data = getRawData(); return data[1] | (data[2] << 7); } MidiMessage MidiMessage::songPositionPointer (const int positionInMidiBeats) noexcept { return MidiMessage (0xf2, positionInMidiBeats & 127, (positionInMidiBeats >> 7) & 127); } bool MidiMessage::isMidiStart() const noexcept { return *getRawData() == 0xfa; } MidiMessage MidiMessage::midiStart() noexcept { return MidiMessage (0xfa); } bool MidiMessage::isMidiContinue() const noexcept { return *getRawData() == 0xfb; } MidiMessage MidiMessage::midiContinue() noexcept { return MidiMessage (0xfb); } bool MidiMessage::isMidiStop() const noexcept { return *getRawData() == 0xfc; } MidiMessage MidiMessage::midiStop() noexcept { return MidiMessage (0xfc); } bool MidiMessage::isMidiClock() const noexcept { return *getRawData() == 0xf8; } MidiMessage MidiMessage::midiClock() noexcept { return MidiMessage (0xf8); } bool MidiMessage::isQuarterFrame() const noexcept { return *getRawData() == 0xf1; } int MidiMessage::getQuarterFrameSequenceNumber() const noexcept { return ((int) getRawData()[1]) >> 4; } int MidiMessage::getQuarterFrameValue() const noexcept { return ((int) getRawData()[1]) & 0x0f; } MidiMessage MidiMessage::quarterFrame (const int sequenceNumber, const int value) noexcept { return MidiMessage (0xf1, (sequenceNumber << 4) | value); } bool MidiMessage::isFullFrame() const noexcept { const uint8* const data = getRawData(); return data[0] == 0xf0 && data[1] == 0x7f && size >= 10 && data[3] == 0x01 && data[4] == 0x01; } void MidiMessage::getFullFrameParameters (int& hours, int& minutes, int& seconds, int& frames, MidiMessage::SmpteTimecodeType& timecodeType) const noexcept { jassert (isFullFrame()); const uint8* const data = getRawData(); timecodeType = (SmpteTimecodeType) (data[5] >> 5); hours = data[5] & 0x1f; minutes = data[6]; seconds = data[7]; frames = data[8]; } MidiMessage MidiMessage::fullFrame (const int hours, const int minutes, const int seconds, const int frames, MidiMessage::SmpteTimecodeType timecodeType) { const uint8 d[] = { 0xf0, 0x7f, 0x7f, 0x01, 0x01, (uint8) ((hours & 0x01f) | (timecodeType << 5)), (uint8) minutes, (uint8) seconds, (uint8) frames, 0xf7 }; return MidiMessage (d, 10, 0.0); } bool MidiMessage::isMidiMachineControlMessage() const noexcept { const uint8* const data = getRawData(); return data[0] == 0xf0 && data[1] == 0x7f && data[3] == 0x06 && size > 5; } MidiMessage::MidiMachineControlCommand MidiMessage::getMidiMachineControlCommand() const noexcept { jassert (isMidiMachineControlMessage()); return (MidiMachineControlCommand) getRawData()[4]; } MidiMessage MidiMessage::midiMachineControlCommand (MidiMessage::MidiMachineControlCommand command) { const uint8 d[] = { 0xf0, 0x7f, 0, 6, (uint8) command, 0xf7 }; return MidiMessage (d, 6, 0.0); } //============================================================================== bool MidiMessage::isMidiMachineControlGoto (int& hours, int& minutes, int& seconds, int& frames) const noexcept { const uint8* const data = getRawData(); if (size >= 12 && data[0] == 0xf0 && data[1] == 0x7f && data[3] == 0x06 && data[4] == 0x44 && data[5] == 0x06 && data[6] == 0x01) { hours = data[7] % 24; // (that some machines send out hours > 24) minutes = data[8]; seconds = data[9]; frames = data[10]; return true; } return false; } MidiMessage MidiMessage::midiMachineControlGoto (int hours, int minutes, int seconds, int frames) { const uint8 d[] = { 0xf0, 0x7f, 0, 6, 0x44, 6, 1, (uint8) hours, (uint8) minutes, (uint8) seconds, (uint8) frames, 0xf7 }; return MidiMessage (d, 12, 0.0); } //============================================================================== String MidiMessage::getMidiNoteName (int note, bool useSharps, bool includeOctaveNumber, int octaveNumForMiddleC) { static const char* const sharpNoteNames[] = { "C", "C#", "D", "D#", "E", "F", "F#", "G", "G#", "A", "A#", "B" }; static const char* const flatNoteNames[] = { "C", "Db", "D", "Eb", "E", "F", "Gb", "G", "Ab", "A", "Bb", "B" }; if (isPositiveAndBelow (note, (int) 128)) { String s (useSharps ? sharpNoteNames [note % 12] : flatNoteNames [note % 12]); if (includeOctaveNumber) s << (note / 12 + (octaveNumForMiddleC - 5)); return s; } return String(); } double MidiMessage::getMidiNoteInHertz (int noteNumber, const double frequencyOfA) noexcept { return frequencyOfA * pow (2.0, (noteNumber - 69) / 12.0); } bool MidiMessage::isMidiNoteBlack (int noteNumber) noexcept { return ((1 << (noteNumber % 12)) & 0x054a) != 0; } const char* MidiMessage::getGMInstrumentName (const int n) { static const char* names[] = { NEEDS_TRANS("Acoustic Grand Piano"), NEEDS_TRANS("Bright Acoustic Piano"), NEEDS_TRANS("Electric Grand Piano"), NEEDS_TRANS("Honky-tonk Piano"), NEEDS_TRANS("Electric Piano 1"), NEEDS_TRANS("Electric Piano 2"), NEEDS_TRANS("Harpsichord"), NEEDS_TRANS("Clavinet"), NEEDS_TRANS("Celesta"), NEEDS_TRANS("Glockenspiel"), NEEDS_TRANS("Music Box"), NEEDS_TRANS("Vibraphone"), NEEDS_TRANS("Marimba"), NEEDS_TRANS("Xylophone"), NEEDS_TRANS("Tubular Bells"), NEEDS_TRANS("Dulcimer"), NEEDS_TRANS("Drawbar Organ"), NEEDS_TRANS("Percussive Organ"), NEEDS_TRANS("Rock Organ"), NEEDS_TRANS("Church Organ"), NEEDS_TRANS("Reed Organ"), NEEDS_TRANS("Accordion"), NEEDS_TRANS("Harmonica"), NEEDS_TRANS("Tango Accordion"), NEEDS_TRANS("Acoustic Guitar (nylon)"), NEEDS_TRANS("Acoustic Guitar (steel)"), NEEDS_TRANS("Electric Guitar (jazz)"), NEEDS_TRANS("Electric Guitar (clean)"), NEEDS_TRANS("Electric Guitar (mute)"), NEEDS_TRANS("Overdriven Guitar"), NEEDS_TRANS("Distortion Guitar"), NEEDS_TRANS("Guitar Harmonics"), NEEDS_TRANS("Acoustic Bass"), NEEDS_TRANS("Electric Bass (finger)"), NEEDS_TRANS("Electric Bass (pick)"), NEEDS_TRANS("Fretless Bass"), NEEDS_TRANS("Slap Bass 1"), NEEDS_TRANS("Slap Bass 2"), NEEDS_TRANS("Synth Bass 1"), NEEDS_TRANS("Synth Bass 2"), NEEDS_TRANS("Violin"), NEEDS_TRANS("Viola"), NEEDS_TRANS("Cello"), NEEDS_TRANS("Contrabass"), NEEDS_TRANS("Tremolo Strings"), NEEDS_TRANS("Pizzicato Strings"), NEEDS_TRANS("Orchestral Harp"), NEEDS_TRANS("Timpani"), NEEDS_TRANS("String Ensemble 1"), NEEDS_TRANS("String Ensemble 2"), NEEDS_TRANS("SynthStrings 1"), NEEDS_TRANS("SynthStrings 2"), NEEDS_TRANS("Choir Aahs"), NEEDS_TRANS("Voice Oohs"), NEEDS_TRANS("Synth Voice"), NEEDS_TRANS("Orchestra Hit"), NEEDS_TRANS("Trumpet"), NEEDS_TRANS("Trombone"), NEEDS_TRANS("Tuba"), NEEDS_TRANS("Muted Trumpet"), NEEDS_TRANS("French Horn"), NEEDS_TRANS("Brass Section"), NEEDS_TRANS("SynthBrass 1"), NEEDS_TRANS("SynthBrass 2"), NEEDS_TRANS("Soprano Sax"), NEEDS_TRANS("Alto Sax"), NEEDS_TRANS("Tenor Sax"), NEEDS_TRANS("Baritone Sax"), NEEDS_TRANS("Oboe"), NEEDS_TRANS("English Horn"), NEEDS_TRANS("Bassoon"), NEEDS_TRANS("Clarinet"), NEEDS_TRANS("Piccolo"), NEEDS_TRANS("Flute"), NEEDS_TRANS("Recorder"), NEEDS_TRANS("Pan Flute"), NEEDS_TRANS("Blown Bottle"), NEEDS_TRANS("Shakuhachi"), NEEDS_TRANS("Whistle"), NEEDS_TRANS("Ocarina"), NEEDS_TRANS("Lead 1 (square)"), NEEDS_TRANS("Lead 2 (sawtooth)"), NEEDS_TRANS("Lead 3 (calliope)"), NEEDS_TRANS("Lead 4 (chiff)"), NEEDS_TRANS("Lead 5 (charang)"), NEEDS_TRANS("Lead 6 (voice)"), NEEDS_TRANS("Lead 7 (fifths)"), NEEDS_TRANS("Lead 8 (bass+lead)"), NEEDS_TRANS("Pad 1 (new age)"), NEEDS_TRANS("Pad 2 (warm)"), NEEDS_TRANS("Pad 3 (polysynth)"), NEEDS_TRANS("Pad 4 (choir)"), NEEDS_TRANS("Pad 5 (bowed)"), NEEDS_TRANS("Pad 6 (metallic)"), NEEDS_TRANS("Pad 7 (halo)"), NEEDS_TRANS("Pad 8 (sweep)"), NEEDS_TRANS("FX 1 (rain)"), NEEDS_TRANS("FX 2 (soundtrack)"), NEEDS_TRANS("FX 3 (crystal)"), NEEDS_TRANS("FX 4 (atmosphere)"), NEEDS_TRANS("FX 5 (brightness)"), NEEDS_TRANS("FX 6 (goblins)"), NEEDS_TRANS("FX 7 (echoes)"), NEEDS_TRANS("FX 8 (sci-fi)"), NEEDS_TRANS("Sitar"), NEEDS_TRANS("Banjo"), NEEDS_TRANS("Shamisen"), NEEDS_TRANS("Koto"), NEEDS_TRANS("Kalimba"), NEEDS_TRANS("Bag pipe"), NEEDS_TRANS("Fiddle"), NEEDS_TRANS("Shanai"), NEEDS_TRANS("Tinkle Bell"), NEEDS_TRANS("Agogo"), NEEDS_TRANS("Steel Drums"), NEEDS_TRANS("Woodblock"), NEEDS_TRANS("Taiko Drum"), NEEDS_TRANS("Melodic Tom"), NEEDS_TRANS("Synth Drum"), NEEDS_TRANS("Reverse Cymbal"), NEEDS_TRANS("Guitar Fret Noise"), NEEDS_TRANS("Breath Noise"), NEEDS_TRANS("Seashore"), NEEDS_TRANS("Bird Tweet"), NEEDS_TRANS("Telephone Ring"), NEEDS_TRANS("Helicopter"), NEEDS_TRANS("Applause"), NEEDS_TRANS("Gunshot") }; return isPositiveAndBelow (n, numElementsInArray (names)) ? names[n] : nullptr; } const char* MidiMessage::getGMInstrumentBankName (const int n) { static const char* names[] = { NEEDS_TRANS("Piano"), NEEDS_TRANS("Chromatic Percussion"), NEEDS_TRANS("Organ"), NEEDS_TRANS("Guitar"), NEEDS_TRANS("Bass"), NEEDS_TRANS("Strings"), NEEDS_TRANS("Ensemble"), NEEDS_TRANS("Brass"), NEEDS_TRANS("Reed"), NEEDS_TRANS("Pipe"), NEEDS_TRANS("Synth Lead"), NEEDS_TRANS("Synth Pad"), NEEDS_TRANS("Synth Effects"), NEEDS_TRANS("Ethnic"), NEEDS_TRANS("Percussive"), NEEDS_TRANS("Sound Effects") }; return isPositiveAndBelow (n, numElementsInArray (names)) ? names[n] : nullptr; } const char* MidiMessage::getRhythmInstrumentName (const int n) { static const char* names[] = { NEEDS_TRANS("Acoustic Bass Drum"), NEEDS_TRANS("Bass Drum 1"), NEEDS_TRANS("Side Stick"), NEEDS_TRANS("Acoustic Snare"), NEEDS_TRANS("Hand Clap"), NEEDS_TRANS("Electric Snare"), NEEDS_TRANS("Low Floor Tom"), NEEDS_TRANS("Closed Hi-Hat"), NEEDS_TRANS("High Floor Tom"), NEEDS_TRANS("Pedal Hi-Hat"), NEEDS_TRANS("Low Tom"), NEEDS_TRANS("Open Hi-Hat"), NEEDS_TRANS("Low-Mid Tom"), NEEDS_TRANS("Hi-Mid Tom"), NEEDS_TRANS("Crash Cymbal 1"), NEEDS_TRANS("High Tom"), NEEDS_TRANS("Ride Cymbal 1"), NEEDS_TRANS("Chinese Cymbal"), NEEDS_TRANS("Ride Bell"), NEEDS_TRANS("Tambourine"), NEEDS_TRANS("Splash Cymbal"), NEEDS_TRANS("Cowbell"), NEEDS_TRANS("Crash Cymbal 2"), NEEDS_TRANS("Vibraslap"), NEEDS_TRANS("Ride Cymbal 2"), NEEDS_TRANS("Hi Bongo"), NEEDS_TRANS("Low Bongo"), NEEDS_TRANS("Mute Hi Conga"), NEEDS_TRANS("Open Hi Conga"), NEEDS_TRANS("Low Conga"), NEEDS_TRANS("High Timbale"), NEEDS_TRANS("Low Timbale"), NEEDS_TRANS("High Agogo"), NEEDS_TRANS("Low Agogo"), NEEDS_TRANS("Cabasa"), NEEDS_TRANS("Maracas"), NEEDS_TRANS("Short Whistle"), NEEDS_TRANS("Long Whistle"), NEEDS_TRANS("Short Guiro"), NEEDS_TRANS("Long Guiro"), NEEDS_TRANS("Claves"), NEEDS_TRANS("Hi Wood Block"), NEEDS_TRANS("Low Wood Block"), NEEDS_TRANS("Mute Cuica"), NEEDS_TRANS("Open Cuica"), NEEDS_TRANS("Mute Triangle"), NEEDS_TRANS("Open Triangle") }; return (n >= 35 && n <= 81) ? names [n - 35] : nullptr; } const char* MidiMessage::getControllerName (const int n) { static const char* names[] = { NEEDS_TRANS("Bank Select"), NEEDS_TRANS("Modulation Wheel (coarse)"), NEEDS_TRANS("Breath controller (coarse)"), nullptr, NEEDS_TRANS("Foot Pedal (coarse)"), NEEDS_TRANS("Portamento Time (coarse)"), NEEDS_TRANS("Data Entry (coarse)"), NEEDS_TRANS("Volume (coarse)"), NEEDS_TRANS("Balance (coarse)"), nullptr, NEEDS_TRANS("Pan position (coarse)"), NEEDS_TRANS("Expression (coarse)"), NEEDS_TRANS("Effect Control 1 (coarse)"), NEEDS_TRANS("Effect Control 2 (coarse)"), nullptr, nullptr, NEEDS_TRANS("General Purpose Slider 1"), NEEDS_TRANS("General Purpose Slider 2"), NEEDS_TRANS("General Purpose Slider 3"), NEEDS_TRANS("General Purpose Slider 4"), nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, NEEDS_TRANS("Bank Select (fine)"), NEEDS_TRANS("Modulation Wheel (fine)"), NEEDS_TRANS("Breath controller (fine)"), nullptr, NEEDS_TRANS("Foot Pedal (fine)"), NEEDS_TRANS("Portamento Time (fine)"), NEEDS_TRANS("Data Entry (fine)"), NEEDS_TRANS("Volume (fine)"), NEEDS_TRANS("Balance (fine)"), nullptr, NEEDS_TRANS("Pan position (fine)"), NEEDS_TRANS("Expression (fine)"), NEEDS_TRANS("Effect Control 1 (fine)"), NEEDS_TRANS("Effect Control 2 (fine)"), nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, NEEDS_TRANS("Hold Pedal (on/off)"), NEEDS_TRANS("Portamento (on/off)"), NEEDS_TRANS("Sustenuto Pedal (on/off)"), NEEDS_TRANS("Soft Pedal (on/off)"), NEEDS_TRANS("Legato Pedal (on/off)"), NEEDS_TRANS("Hold 2 Pedal (on/off)"), NEEDS_TRANS("Sound Variation"), NEEDS_TRANS("Sound Timbre"), NEEDS_TRANS("Sound Release Time"), NEEDS_TRANS("Sound Attack Time"), NEEDS_TRANS("Sound Brightness"), NEEDS_TRANS("Sound Control 6"), NEEDS_TRANS("Sound Control 7"), NEEDS_TRANS("Sound Control 8"), NEEDS_TRANS("Sound Control 9"), NEEDS_TRANS("Sound Control 10"), NEEDS_TRANS("General Purpose Button 1 (on/off)"), NEEDS_TRANS("General Purpose Button 2 (on/off)"), NEEDS_TRANS("General Purpose Button 3 (on/off)"), NEEDS_TRANS("General Purpose Button 4 (on/off)"), nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, NEEDS_TRANS("Reverb Level"), NEEDS_TRANS("Tremolo Level"), NEEDS_TRANS("Chorus Level"), NEEDS_TRANS("Celeste Level"), NEEDS_TRANS("Phaser Level"), NEEDS_TRANS("Data Button increment"), NEEDS_TRANS("Data Button decrement"), NEEDS_TRANS("Non-registered Parameter (fine)"), NEEDS_TRANS("Non-registered Parameter (coarse)"), NEEDS_TRANS("Registered Parameter (fine)"), NEEDS_TRANS("Registered Parameter (coarse)"), nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, NEEDS_TRANS("All Sound Off"), NEEDS_TRANS("All Controllers Off"), NEEDS_TRANS("Local Keyboard (on/off)"), NEEDS_TRANS("All Notes Off"), NEEDS_TRANS("Omni Mode Off"), NEEDS_TRANS("Omni Mode On"), NEEDS_TRANS("Mono Operation"), NEEDS_TRANS("Poly Operation") }; return isPositiveAndBelow (n, numElementsInArray (names)) ? names[n] : nullptr; }