#ifndef cwMidi_h #define cwMidi_h namespace cw { namespace midi { enum { kMidiChCnt = 16, kInvalidMidiByte = 128, kMidiNoteCnt = kInvalidMidiByte, kMidiCtlCnt = kInvalidMidiByte, kMidiPgmCnt = kInvalidMidiByte, kInvalidMidiPitch = kInvalidMidiByte, kInvalidMidiVelocity = kInvalidMidiByte, kInvalidMidiCtl = kInvalidMidiByte, kInvalidMidiPgm = kInvalidMidiByte, kMidiSciPitchCharCnt = 5 // A#-1 }; // MIDI status bytes enum { kInvalidStatusMdId = 0x00, kNoteOffMdId = 0x80, kNoteOnMdId = 0x90, kPolyPresMdId = 0xa0, kCtlMdId = 0xb0, kPgmMdId = 0xc0, kChPresMdId = 0xd0, kPbendMdId = 0xe0, kSysExMdId = 0xf0, kSysComMtcMdId = 0xf1, kSysComSppMdId = 0xf2, kSysComSelMdId = 0xf3, kSysComUndef0MdId = 0xf4, kSysComUndef1MdId = 0xf5, kSysComTuneMdId = 0xf6, kSysComEoxMdId = 0xf7, kSysRtClockMdId = 0xf8, kSysRtUndef0MdId = 0xf9, kSysRtStartMdId = 0xfa, kSysRtContMdId = 0xfb, kSysRtStopMdId = 0xfc, kSysRtUndef1MdId = 0xfd, kSysRtSenseMdId = 0xfe, kSysRtResetMdId = 0xff, kMetaStId = 0xff, kSeqNumbMdId = 0x00, kTextMdId = 0x01, kCopyMdId = 0x02, kTrkNameMdId = 0x03, kInstrNameMdId = 0x04, kLyricsMdId = 0x05, kMarkerMdId = 0x06, kCuePointMdId = 0x07, kMidiChMdId = 0x20, kEndOfTrkMdId = 0x2f, kTempoMdId = 0x51, kSmpteMdId = 0x54, kTimeSigMdId = 0x58, kKeySigMdId = 0x59, kSeqSpecMdId = 0x7f, kInvalidMetaMdId = 0x80, kSustainCtlMdId = 0x40, kPortamentoCtlMdId = 0x41, kSostenutoCtlMdId = 0x42, kSoftPedalCtlMdId = 0x43, kLegatoCtlMdId = 0x44 }; typedef unsigned char byte_t; typedef struct timespec timestamp_t; //=============================================================================================== // Utility Functions // template< typename T> bool isStatus( T s ) { return (kNoteOffMdId <= (s) /*&& ((unsigned)(s)) <= kSysRtResetMdId*/ ); } template< typename T> bool isChStatus( T s ) { return (kNoteOffMdId <= (s) && (s) < kSysExMdId); } template< typename T> bool isNoteOn( T s ) { return ( kNoteOnMdId <= (s) && (s) <= (kNoteOnMdId + kMidiChCnt) ); } template< typename T> bool isNoteOff( T s, T d1 ) { return ( (cmMidiIsNoteOn(s) && (d1)==0) || (kNoteOffMdId <= (s) && (s) <= (kNoteOffMdId + kMidiChCnt)) ); } template< typename T> bool isCtl( T s ) { return ( kCtlMdId <= (s) && (s) <= (kCtlMdId + kMidiChCnt) ); } template< typename T> bool isSustainPedal( T s, T d0 ) { return ( kCtlMdId <= (s) && (s) <= (kCtlMdId + kMidiChCnt) && (d0)== kSustainCtlMdId ); } template< typename T> bool isSustainPedalDown( T s, T d0, T d1) { return ( cmMidiIsSustainPedal(s,d0) && (d1)>=64 ); } template< typename T> bool isSustainPedalUp( T s, T d0, T d1) { return ( cmMidiIsSustainPedal(s,d0) && (d1)<64 ); } template< typename T> bool isSostenutoPedal( T s, T d0 ) { return ( kCtlMdId <= (s) && (s) <= (kCtlMdId + kMidiChCnt) && (d0)== kSostenutoCtlMdId ); } template< typename T> bool isSostenutoPedalDown( T s, T d0, T d1) { return ( cmMidiIsSostenutoPedal(s,d0) && (d1)>=64 ); } template< typename T> bool isSostenutoPedalUp( T s, T d0, T d1) { return ( cmMidiIsSostenutoPedal(s,d0) && (d1)<64 ); } template< typename T> bool isPedal( T s, T d0 ) { return ( kCtlMdId <= (s) && (s) <= (kCtlMdId + kMidiChCnt) && (d0)>=kSustainCtlMdId && (d0)<=kLegatoCtlMdId ); } template< typename T> bool isPedalDown( T s, T d0, T d1 ) { return ( cmMidiIsPedal(s,d0) && (d1)>=64 ); } template< typename T> bool isPedalUp( T s, T d0, T d1 ) { return ( cmMidiIsPedal(s,d0) && (d1)<64 ); } const char* statusToLabel( byte_t status ); const char* metaStatusToLabel( byte_t metaStatus ); const char* pedalLabel( byte_t d0 ); // Returns kInvalidMidiByte if status is not a valid status byte byte_t statusToByteCount( byte_t status ); unsigned to14Bits( byte_t d0, byte_t d1 ); void split14Bits( unsigned v, byte_t& d0Ref, byte_t& d1Ref ); int toPbend( byte_t d0, byte_t d1 ); void splitPbend( int v, byte_t& d0Ref, byte_t& d1Ref ); //=============================================================================================== // MIDI Communication data types // typedef struct msg_str { //unsigned deltaUs; // time since last MIDI msg in microseconds timestamp_t timeStamp; byte_t status; // midi status byte byte_t d0; // midi data byte 0 byte_t d1; // midi data byte 1 byte_t pad; } msg_t; typedef struct packet_str { void* cbDataPtr; // application supplied reference value from mdParserCreate() unsigned devIdx; // the device the msg originated from unsigned portIdx; // the port index on the source device msg_t* msgArray; // pointer to an array of 'msgCnt' mdMsg records or NULL if sysExMsg is non-NULL byte_t* sysExMsg; // pointer to a sys-ex msg or NULL if msgArray is non-NULL (see note below) unsigned msgCnt; // count of mdMsg records or sys-ex bytes } packet_t; // Notes: If the sys-ex message can be contained in a single msg then // then the first msg byte is kSysExMdId and the last is kSysComEoxMdId. // If the sys-ex message is broken into multiple pieces then only the // first will begin with kSysExMdId and the last will end with kSysComEoxMdId. // If label is NULL or labelCharCnt==0 then a pointer to an internal static // buffer is returned. If label[] is given the it // should have at least 5 (kMidiPitchCharCnt) char's (including the terminating zero). // If 'pitch' is outside of the range 0-127 then a blank string is returned. const char* midiToSciPitch( byte_t pitch, char* label, unsigned labelCharCnt ); // Convert a scientific pitch to MIDI pitch. acc == 1 == sharp, acc == -1 == flat. // The pitch character must be in the range 'A' to 'G'. Upper or lower case is valid. // Return kInvalidMidiPitch if the arguments are not valid. byte_t sciPitchToMidiPitch( char pitch, int acc, int octave ); // Scientific pitch string: [A-Ga-g][#b][#] where # may be -1 to 9. // Return kInvalidMidiPitch if sciPtichStr does not contain a valid // scientific pitch string. This function will convert C-1 to G9 to // valid MIDI pitch values 0 to 127. Scientific pitch strings outside // of this range will be returned as kInvalidMidiPitch. byte_t sciPitchToMidi( const char* sciPitchStr ); } } #endif