void processMidiCommand(MidiEvent& message) {
if (message.getP0() != 0x90 || message.getP2() == 0) {
return;
}
switch (message.getP1()) {
case 60: // Middle C = beat
keyboardCommand(' ');
break;
case 61: // C# = amplitude control
{
double amp = performance.getAmp();
amp = amp * message.getP2() / 64;
if (amp < 0) {
amp = 0;
} else if (amp > 127) {
amp = 127;
}
performance.setAmp((int)amp);
}
break;
case 71: // B = 1 beat tempo follow
keyboardCommand('1');
break;
case 72: // C = 2 beat tempo follow
keyboardCommand('2');
break;
case 73: // C# = 3 beat tempo follow
keyboardCommand('3');
break;
case 74: // D = 4 beat tempo follow
keyboardCommand('4');
break;
case 79: // G = constant tempo follow
keyboardCommand('9');
break;
case 80: // G# = automatic
keyboardCommand('0');
break;
case 62: // amplitude decrease
keyboardCommand('[');
break;
case 63: // amplitude increase
keyboardCommand(']');
break;
case 64: // tempo decrease
keyboardCommand('-');
break;
case 65: // tempo increase
keyboardCommand('=');
break;
}
}
void mainloopalgorithms(void) {
if (synth.getNoteCount() > 0) {
message = synth.extractNote();
if (message.getP2() != 0) {
startHenon(message.getP1(), message.getP2());
}
}
if (nextnotetime < t_time) {
nextnotetime += 100;
key = nextHenon();
voice.play(key, 64);
}
}
void recordRhythms(void) {
// remove all previous notes from input
while (synth.getNoteCount() > 0) synth.extractNote();
cout << "Play four notes to record rhythms and durations for chords" << endl;
int oncount = 0;
int offcount = 0;
int finished[4] = {0};
int offnote;
int offtime;
int playedNotes[4] = {0};
int startTime = 0;
MidiEvent noteMessage;
while (oncount <= 4 && offcount <=4 ) {
if (interfaceKeyboard.hit()) checkKeyboard();
synth.processIncomingMessages();
if (synth.getNoteCount() > 0) {
noteMessage = synth.extractNote();
if (oncount < 4 && noteMessage.getP2() != 0) {
if (oncount == 0) startTime = noteMessage.tick;
playedNotes[oncount] = noteMessage.getP1();
attack[oncount] = noteMessage.getP2();
onset[oncount] = noteMessage.tick - startTime;
oncount++;
} else if (noteMessage.getP2() == 0) {
offtime = noteMessage.tick;
offnote = noteMessage.getP1();
for (int i=0; i<oncount; i++) {
if ((offnote == playedNotes[i]) && (finished[i] == 0)) {
duration[i] = offtime - onset[i] - startTime;
offcount++;
finished[i] = 1;
break;
}
}
}
}
if ((oncount >= 4) && (offcount >=4)) break;
}
cout << "Finished recording new rhythms and durations" << endl;
cout << "Onsets: \t" << onset[0] << "\t" << onset[1]
<< "\t" << onset[2] << "\t" << onset[3] << endl;
cout << "durations: \t" << duration[0] << "\t" << duration[1]
<< "\t" << duration[2] << "\t" << duration[3] << endl;
}
void keyboard(int key) {
synth.play(0, keyboardnote, 0);
noteMessage.tick = mainTimer.getTime();
noteMessage.setP0(0x90);
noteMessage.setP1(keyboardnote);
noteMessage.setP2(0);
synth.insert(noteMessage);
switch (key) {
case 'z': keyboardnote = 12 * octave + 0; break; // C
case 's': keyboardnote = 12 * octave + 1; break; // C#
case 'x': keyboardnote = 12 * octave + 2; break; // D
case 'd': keyboardnote = 12 * octave + 3; break; // D#
case 'c': keyboardnote = 12 * octave + 4; break; // E
case 'v': keyboardnote = 12 * octave + 5; break; // F
case 'g': keyboardnote = 12 * octave + 6; break; // F#
case 'b': keyboardnote = 12 * octave + 7; break; // G
case 'h': keyboardnote = 12 * octave + 8; break; // G#
case 'n': keyboardnote = 12 * octave + 9; break; // A
case 'j': keyboardnote = 12 * octave + 10; break; // A#
case 'm': keyboardnote = 12 * octave + 11; break; // B
case ',': keyboardnote = 12 * octave + 12; break; // C
default: return;
}
if (keyboardnote < 0) keyboardnote = 0;
else if (keyboardnote > 127) keyboardnote = 127;
noteMessage.tick = mainTimer.getTime();
noteMessage.setP0(0x90);
noteMessage.setP1(keyboardnote);
noteMessage.setP2(rand()%47 + 80); // random int from 1 to 127
synth.play(0, noteMessage.getP1(), noteMessage.getP2());
synth.insert(noteMessage);
}
void mainloopalgorithms(void) {
eventBuffer.checkPoll(); // see if any notes to play
while (synth.getNoteCount() > 0) {
message = synth.extractNote();
if (message.getP2() != 0) {
lastnotes.insert(message.getP1());
lasttimes.insert(message.tick);
distancee = lastnotes[0] - lastnotes[1];
duration = lasttimes[0] - lasttimes[1];
channel = 0x0f & message.getP0();
if (distancee != 0) {
playgliss(message.getP1(), message.getP2(), channel, duration, distancee);
}
}
}
}
void mainloopalgorithms(void) {
// 1. check to see if we are in a new measure and update the
// metronome accordingly. If in 4/4, then the metronome will
// be guarenteed to be between 0 and 3.99999 after the following
// code is run. The update will make sure that the metronome remains
// synced exactly in time with the absolute beat. (Useful for
// polyphony, not really necessary in monophonic cases).
if (metronome.expired() >= meter) {
metronome.update(meter);
}
// 2. Determine the current beat of the meter.
// We will want to play automated chords on beats one and three.
beatfraction = metronome.getPeriodCount();
beat = (int)beatfraction + 1;
beatfraction -= beat - 1;
// 3. Process the incoming MIDI note messages (if any), keeping track
// of the last note, and whether it is currently on or off.
while (synth.getNoteCount() > 0) {
notemessage = synth.extractNote();
if (notemessage.getP2() != 0) {
note = notemessage.getP1();
notestates[note] = 1;
} else {
notestates[notemessage.getP1()] = 0;
}
}
// 4. Determine the position in time in the current beat.
// There are two beat-parts which are called states:
// state == 0: we are at the start of the beat and may need to
// choose a new chord.
// state == 1: we are past the maximum wait time for a chord decision
// Also, check to see if the state has changed from 0 to 1 or 1 to 0.
oldstate = state;
state = beatfraction < maxwait ? 0 : 1;
stateChange = (state != oldstate);
// 5. Check to see if a chord needs to be played.
if (stateChange && state == 0) {
playMetronome(beat);
if (chordBeat(beat, meter)) {
notescan = 1;
} else {
playChord(currentnote, OFF);
}
}
if (notescan && notestates[note]) { // if note played in beat window
currentnote = note;
playChord(currentnote, ON);
notescan = 0;
} else if (notescan && state == 1) { // if too late for a new note
playChord(currentnote, ON);
notescan = 0;
}
}
void mainloopalgorithms(void) {
eventBuffer.checkPoll(); // see if any notes need playing
while (synth.getNoteCount() > 0) {
noteMessage = synth.extractNote();
if (noteMessage.getP2() != 0) {
playchord(noteMessage, chordType, onset, duration);
}
}
}
int main(void) {
MidiInput midiin;
MidiOutput midiout;
midiout.setPort(0);
midiout.open();
midiin.setPort(0);
midiin.open();
MidiEvent message;
int sysexloc;
unsigned char *sysexdata = NULL;
int sysexsize = 0;
int i;
int running = 1;
cout << "sysexio -- display and echo SYSEX messages from MIDI input" << endl;
cout << "Press Middle C to quit." << endl;
while (running) {
if (midiin.getCount() > 0) {
midiin.extract(message);
if (message.getP0() == 0xf0) {
sysexloc = message.getP1();
sysexdata = midiin.getSysex(sysexloc);
sysexsize = midiin.getSysexSize(sysexloc);
// print out the sysex data to the screen:
for (i=0; i<sysexsize; i++) {
cout << hex << (int)sysexdata[i] << " ";
if ((i + 1) % 30 == 0) {
cout << endl;
}
}
cout << endl;
// Now echo the messages to MIDI output (as a demo
// for how to send Sysex outputs)
midiout.rawsend(sysexdata, sysexsize);
// As a courtesy, mark the midiin sysex buffer free
// but this is not necessay (it will be erased when
// more space is needed for storing a sysex.
midiin.clearSysex(sysexloc);
} else if ((message.getP0() & 0xf0) == 0x90) {
// Exit the program when a middle C note is pressed.
if (message.getP1() == 60 && message.getP2() > 0) {
running = 0;
}
}
}
}
return 0;
}
void mainloopalgorithms(void) {
if (synth.getNoteCount() > 0) {
while (synth.getNoteCount() > 0) {
message = synth.extractNote();
if ((message.getP2() == 0) || ((message.getP0() & 0xf0) == 0x80)) {
keystates[message.getP1()] = 0;
} else if (message.getP2() != 0) {
keystates[message.getP1()] = 1;
}
}
getNewChordInfo(tempchord, keystates);
lastnotetime = t_time;
}
if (t_time > lastnotetime + timedelta) {
if (!equalChord(tempchord, currentchord)) {
printNewChord(tempchord, chordset, names);
currentchord = tempchord;
}
}
}
void playchord(MidiEvent aMessage, int chordQuality,
int* rhythm, int* dur) {
int numNotes = 0; // the number of notes to play
NoteEvent tempNote; // temporary Note for copying into eventBuffer
int chordNote[4]; // the notes of the chord to be calculated
int rootNote = aMessage.getP1(); // root of chord to be created
chordNote[0] = rootNote;
switch (chordQuality) {
case DIMINISHED_TRIAD:
chordNote[1] = rootNote + 3; chordNote[2] = rootNote + 6;
numNotes = 3;
break;
case MINOR_TRIAD:
chordNote[1] = rootNote + 3; chordNote[2] = rootNote + 7;
numNotes = 3;
break;
case MAJOR_TRIAD:
chordNote[1] = rootNote + 4; chordNote[2] = rootNote + 7;
numNotes = 3;
break;
case AUGMENTED_TRIAD:
chordNote[1] = rootNote + 4; chordNote[2] = rootNote + 8;
numNotes = 3;
break;
case FULLY_DIM_7TH:
chordNote[1] = rootNote + 3;
chordNote[2] = rootNote + 6;
chordNote[3] = rootNote + 9;
numNotes = 4;
break;
case HALF_DIM_7TH:
chordNote[1] = rootNote + 3;
chordNote[2] = rootNote + 6;
chordNote[3] = rootNote + 10;
numNotes = 4;
break;
case mm_7TH:
chordNote[1] = rootNote + 3;
chordNote[2] = rootNote + 7;
chordNote[3] = rootNote + 10;
numNotes = 4;
break;
case mM_7TH:
chordNote[1] = rootNote + 3;
chordNote[2] = rootNote + 7;
chordNote[3] = rootNote + 11;
numNotes = 4;
break;
case Mm_7TH:
chordNote[1] = rootNote + 3;
chordNote[2] = rootNote + 4;
chordNote[3] = rootNote + 10;
numNotes = 4;
break;
case MM_7TH:
chordNote[1] = rootNote + 4;
chordNote[2] = rootNote + 7;
chordNote[3] = rootNote + 10;
numNotes = 4;
break;
default: // invalid quality
return;
}
cout << "Chord: (";
for (int i=0; i<numNotes; i++) {
tempNote.setKeyno(chordNote[i]);
if (tempNote.getKeyno() < 0 || tempNote.getKeyno() > 127) continue;
if (attack[i] == 0) {
tempNote.setVelocity(aMessage.getP2());
} else {
tempNote.setVelocity(attack[i]);
}
tempNote.setOnDur(t_time+rhythm[i]+offset, dur[i]);
tempNote.setStatus(0); // note hasn't been played yet
eventBuffer.insert(&tempNote);
cout << tempNote.getKeyno();
if (i != numNotes-1) cout << ",";
}
cout << ")" << endl;
}
void processNote(MidiEvent message, int seqLength, int direction) {
static Array<char> notes;
static Array<char> velocities;
static Array<int> durations;
static Array<int> iois;
static Array<int> ontimes;
static CircularBuffer<int> attacktimes;
static int init = 0;
static TumbleParameters temparam;
char vel;
if (!init) {
attacktimes.setSize(256);
attacktimes.reset();
notes.setSize(0);
velocities.setSize(0);
durations.setSize(0);
iois.setSize(0);
ontimes.setSize(128);
ontimes.zero();
init = 1;
}
char note;
int deltatime;
int ioi0;
int ioix;
if (message.isNoteOn()) {
attacktimes.insert(message.tick);
// check to see if the ioi is in the correct range
if (notes.getSize() == 0) {
// no notes yet, so don't know the first ioi
} else {
deltatime = attacktimes[0] - attacktimes[1];
iois.append(deltatime);
}
if (iois.getSize() > 1) {
ioi0 = iois[0];
ioix = iois[iois.getSize()-1];
if ((ioix < ioi0 * tolerance) || (ioix > ioi0 / tolerance)) {
goto resettrigger;
}
}
// at this point the note can be added to the sequence
if (notes.getSize() + 1 >= seqLength) {
// time to trigger an algorithm
if (durations.getSize() < notes.getSize()) {
// if the last note has not yet been turned off, approximate dur.
deltatime = iois[iois.getSize()-1];
durations.append(deltatime);
}
int i;
for (i=0; i<seqLength; i++) {
temparam.v[i] = velocities[i];
temparam.i[i] = iois[i];
temparam.d[i] = durations[i];
temparam.n[i] = notes[i] - notes[0];
}
temparam.n[0] = message.getP1() - notes[0];
temparam.current = message.getP1();
temparam.pos = 1;
temparam.max = seqLength;
temparam.active = 1;
startAlgorithm(temparam);
goto resettrigger;
} else {
// add the note info to the algorithm pile
note = message.getP1();
notes.append(note);
vel = message.getP2();
velocities.append(vel);
attacktimes[message.getP1()] = message.tick;
}
} else if (message.isNoteOff()) {
if (notes.getSize() > 0) {
if (notes[notes.getSize()-1] == message.getP1()) {
deltatime = message.tick - ontimes[message.getP1()];
durations.append(deltatime);
} else {
cout << "A funny error ocurred" << endl;
}
}
return;
resettrigger:
attacktimes.setSize(0);
notes.setSize(0);
velocities.setSize(0);
durations.setSize(0);
iois.setSize(0);
if (message.isNoteOn()) {
note = message.getP1();
notes.append(note);
ontimes[message.getP1()] = message.tick;
vel = message.getP2();
velocities.append(vel);
}
}
//////////////////////////////
//
// startAlgorithm -- start playing the tumble algorithm. Inserts a
// FunctionEvent into the eventBuffer which plays the tumble
// algorithm sequence. The algorithm will die after the notes
// fall off of the 88-note keyboard.
//
}
void mainloopalgorithms(void) {
if (comparestate && notetimer.expired()) {
if (notetimer.expired() > 2) {
notetimer.reset();
} else {
notetimer.update();
}
notestate = !notestate;
if (notestate == 1 || notestate == -1) {
synth.play(0, note, 64);
data = 0x90; sentout.insert(data);
data = note; sentout.insert(data);
data = 64; sentout.insert(data);
} else {
synth.play(0, note, 0);
data = 0x90; sentout.insert(data);
data = note; sentout.insert(data);
data = 0; sentout.insert(data);
note += step * direction;
if (note > highestnote) {
note = lowestnote;
}
if (note < lowestnote) {
note = highestnote;
}
}
}
if (midiinput.getCount() > 0) {
midiinput.extract(message);
receivedin.insert(message.getP0());
receivedin.insert(message.getP1());
receivedin.insert(message.getP2());
// check that the messages are identical
if (receivedin.getCount() < 3) {
cout << "Error: not enough received data" << endl;
} else {
receivedin.extract(checkin[0]);
receivedin.extract(checkin[1]);
receivedin.extract(checkin[2]);
}
if (sentout.getCount() < 3) {
cout << "Error: not enough sent data" << endl;
} else {
sentout.extract(checkout[0]);
sentout.extract(checkout[0]);
sentout.extract(checkout[0]);
}
if ((checkout[0] != checkin[0]) || (checkout[1] != checkin[1]) ||
(checkout[2] != checkin[2])) {
synth.rawsend(0xaa, 0x7f, 0x00);
cout << "Error "
<< "output was = (" << hex << (int)checkout[0] << ") "
<< dec << (int)checkout[1] << " "
<< dec << (int)checkout[2] << "\tbut input is = ("
<< hex << (int)checkin[0] << ") "
<< dec << (int)checkin[1] << " "
<< dec << (int)checkin[2] << " "
<< endl;
// assume that a note message was missed.
if (sentout.getCount() < 3) {
cout << "Error: not enough sent data during error" << endl;
} else {
sentout.extract(checkout[0]);
sentout.extract(checkout[1]);
sentout.extract(checkout[2]);
}
stop();
cout << "Press space to restart testing, "
"or press 'S' to silence synth" << endl;
}
}
}
int main(int argc, char** argv) {
options.setOptions(argc, argv);
checkOptions(options);
displayHeader(cout);
if (fileQ) {
displayHeader(outputfile);
}
KeyboardInput keyboard; // for typing comments into output file
char keych; // character from keyboard
MidiEvent message;
int lastTime = -1;
midi.open();
while (1) {
while (midi.getCount() > 0) {
midi.extract(message);
if (echoQ) {
midi.send(message);
}
if ((!activeSensingQ) && (message.getP0() == 0xfe)) {
// don't display incoming active-sensing messages
continue;
}
// filter any specified message types
if (suppressOffQ && ((message.getP0() & 0xf0) == 0x90) &&
(message.getP2() == 0)) {
continue;
} else if (filter[(message.getP0() >> 4) - 8]) {
continue;
} else if (cfilter[message.getP0() & 0x0f]) {
continue;
}
// adjust message time to delta time if necessary
if (!absoluteQ) {
if (lastTime == -1) {
lastTime = message.tick;
message.tick = 0;
} else {
int temp = message.tick;
message.tick = message.tick - lastTime;
lastTime = temp;
}
}
displayMessage(cout, message, style);
if (fileQ) {
displayMessage(outputfile, message, style);
}
}
if (keyboardQ && keyboard.hit()) {
keych = keyboard.getch();
switch (keych) {
case 27: // escape key
if (fileQ && bufferIndex != 0 && bufferIndex < MAX_KEY_BUFF) {
inputBuffer[bufferIndex] = '\0';
outputfile << inputBuffer;
}
keyboard.deinitialize();
exit(0);
break;
case 0x08: // backspace key
case 0x7f: // delete key
if (bufferIndex > 0) {
cout << "\b \b" << flush;
bufferIndex--;
}
break;
case 0x0a: // enter key only
#ifdef VISUAL
break;
#endif
case 13: // line feed
cout << endl;
if (bufferIndex < MAX_KEY_BUFF) {
inputBuffer[bufferIndex] = '\0';
if (fileQ) {
outputfile << inputBuffer << '\n';
}
examineInputForCommand(inputBuffer);
}
bufferIndex = 0;
break;
case 0x0c: // ^L key (redraw input)
cout << endl;
if (bufferIndex < MAX_KEY_BUFF) {
inputBuffer[bufferIndex] = '\0';
cout << inputBuffer << flush;
}
break;
default: // normal key
cout << keych << flush;
if (bufferIndex < MAX_KEY_BUFF) {
inputBuffer[bufferIndex++] = keych;
} else {
// buffer is WAY to long: kill it
bufferIndex = 0;
}
}
}
millisleep(1); // sleep for 1 millisec for multi-tasking courtesy
}
void processNote(MidiEvent message) {
int key = message.getP1();
int velocity = message.getP2();
int channel = message.getP0() & 0x0f;
int status = 1;
if (message.getP0() - channel == 0x80 || velocity == 0) {
status = 0;
}
if (status == 0) {
if (key == C8 || key == B7) {
trillcorrection = 0;
}
if (key == As7 || key == A7) {
velcorrection = 0;
}
return;
}
if (key == C8) {
trillcorrection = velocity / 10;
return;
}
if (key == B7) {
trillcorrection = -(velocity / 10);
return;
}
if (key == As7) {
velcorrection = +(velocity / 10);
return;
}
if (key == A7) {
velcorrection = -(velocity / 10);
return;
}
if (key == A0) {
for (int j=0; j<128; j++) {
noteontimes[j] = t_time;
}
return;
}
if (key == A0) {
for (int j=0; j<128; j++) {
noteontimes[j] = t_time;
}
return;
}
noteontimes[key] = t_time;
notetimes.insert(message.tick);
notes.insert(key);
if (notes[1] == 0) {
trills.insert(0);
return;
}
if (notes[2] != 0) {
if (trills[0] == 1 && notetimes[1] - notetimes[2] < TRIGTIME) {
trills.insert(0);
return;
}
}
trills.insert(1);
int duration = notetimes[0] - notetimes[1];
if (duration < TRIGTIME && duration > MINTRIGTIME &&
notes[0] - notes[1] != 0) {
createTrill(key, notes[1], velocity, channel, duration);
}
}
void PCH_ChartManager::LoadMidiToDB(PCH_CString filePath,PCH_CString fileHash, bool update)
{
std::ifstream in2(filePath, std::ios::in | std::ios::binary);
MidiFile midifile(in2);
if (!midifile.status())
{
printf("Error reading MIDI file %s\n",filePath);
return;
}
printf("Loading midi file data...\n");
if(update)
{
printf("Deleting existing data...\n");
_db->DeleteChart(filePath);
}
midifile.absoluteTicks();
midifile.linkNotePairs();
midifile.doTimeAnalysis();
printf("Analysis complete...\n");
int totalTracks =midifile.size();
MidiEvent* mev;
int chartID = _db->AddChart(filePath, fileHash);
int trackID = 0;
int trackItemCount = 0;
#ifndef PCH_USE_HEAP
PCH_ControllerEvent newEvent;
PCH_ChartInstrument newInst;
PCH_ChartTrackNote newNote;
PCH_PitchBend newBend;
#endif
for (int track=0; track < totalTracks; track++)
{
trackItemCount = midifile[track].size();
if(trackItemCount == 0) continue;
trackID = _db->AddTrack(chartID,track);
printf("Track #%d added...\n",trackID);
_db->BeginTransaction();
for (int i=0; i<trackItemCount; i++)
{
mev = &midifile[track][i];
if(mev->isTimbre())
{
#ifdef PCH_USE_HEAP
PCH_ChartInstrument* newInst = new PCH_ChartInstrument();
newInst->Channel = mev->getChannel();
newInst->Seconds = mev->seconds;
newInst->InstrumentID = mev->getP1();
_db->AddInstrument(trackID,newInst);
delete newInst;
newInst = NULL;
#else
newInst.Channel = mev->getChannel();
newInst.Seconds = mev->seconds;
newInst.InstrumentID = mev->getP1();
_db->AddInstrument(trackID,&newInst);
#endif
}
if(mev->getCommandByte() == 0xFF && mev->getP1() == 0x03)//Title
{
printf("Title found\n");
unsigned char* title = &midifile[track][i][3];//CMD + p1 + p2 are omitted
int titleSize = mev->getP2();
if(titleSize > 0)
{
char* strTitle = new char[titleSize+1];
memcpy(strTitle,title,titleSize);
strTitle[titleSize] = '\0';
_db->SetTrackTitle(trackID, strTitle);
}
printf("Title end\n");
}
if(mev->isNote()) //if(false)
{
if(mev->isNoteOn())
{
#ifdef PCH_USE_HEAP
PCH_ChartTrackNote* newNote = new PCH_ChartTrackNote();
newNote->Seconds = mev->seconds;
newNote->SecondsDuration = mev->getDurationInSeconds();
newNote->Channel = mev->getChannel();
newNote->KeyNumber = mev->getKeyNumber();
newNote->Velocity = mev->getVelocity();
_db->AddNote(trackID, newNote);
delete newNote;
newNote = NULL;
#else
newNote.Seconds = mev->seconds;
newNote.SecondsDuration = mev->getDurationInSeconds();
newNote.Channel = mev->getChannel();
newNote.KeyNumber = mev->getKeyNumber();
newNote.Velocity = mev->getVelocity();
_db->AddNote(trackID, &newNote);
#endif
}
}
if(mev->isController())
{
#ifdef PCH_USE_HEAP
PCH_ControllerEvent* newEvent = new PCH_ControllerEvent();
newEvent->Seconds = mev->seconds;
newEvent->Channel = mev->getChannel();
newEvent->ControllerID = mev->getP1();
newEvent->Value = mev->getP2();
_db->AddEvent(trackID, newEvent);
delete newEvent;
newEvent = NULL;
#else
newEvent.Seconds = mev->seconds;
newEvent.Channel = mev->getChannel();
newEvent.ControllerID = mev->getP1();
newEvent.Value = mev->getP2();
_db->AddEvent(trackID, &newEvent);
#endif
}
if(mev->isPitchbend())
{
#ifdef PCH_USE_HEAP
PCH_PitchBend* newBend = new PCH_PitchBend();
newBend->Seconds = mev->seconds;
newBend->Channel = mev->getChannel();
newBend->PitchBend = mev->getP1() + (mev->getP2() << 7);
_db->AddPitchBend(trackID, newBend);
delete newBend;
newBend = NULL;
#else
newBend.Seconds = mev->seconds;
newBend.Channel = mev->getChannel();
newBend.PitchBend = mev->getP1() + (mev->getP2() << 7);
_db->AddPitchBend(trackID, &newBend);
#endif
}
}
_db->CommitTransaction();
}
}