HINLINE void operator()(
T_SpeciesStorage& speciesStorage,
const uint32_t currentStep,
const EventTask& eventInt,
EventTask& pushEvent,
EventTask& commEvent
) const
{
typedef std::list<EventTask> EventList;
EventList updateEventList;
EventList commEventList;
/* push all species */
typedef typename PMacc::particles::traits::FilterByFlag
<
VectorAllSpecies,
particlePusher<>
>::type VectorSpeciesWithPusher;
ForEach<VectorSpeciesWithPusher, particles::PushSpecies<bmpl::_1>, MakeIdentifier<bmpl::_1> > pushSpecies;
pushSpecies(forward(speciesStorage), currentStep, eventInt, forward(updateEventList));
/* join all push events */
for (typename EventList::iterator iter = updateEventList.begin();
iter != updateEventList.end();
++iter)
{
pushEvent += *iter;
}
/* call communication for all species */
ForEach<VectorSpeciesWithPusher, particles::CommunicateSpecies<bmpl::_1>, MakeIdentifier<bmpl::_1> > communicateSpecies;
communicateSpecies(forward(speciesStorage), forward(updateEventList), forward(commEventList));
/* join all communication events */
for (typename EventList::iterator iter = commEventList.begin();
iter != commEventList.end();
++iter)
{
commEvent += *iter;
}
}
void Track::splitPart(Part* part, int tickpos, Part*& p1, Part*& p2)
{
int l1 = 0; // len of first new part (ticks or samples)
int l2 = 0; // len of second new part
int samplepos = tempomap.tick2frame(tickpos);
{
l1 = tickpos - part->tick();
l2 = part->lenTick() - l1;
}
if (l1 <= 0 || l2 <= 0)
return;
p1 = newPart(part); // new left part
p2 = newPart(part); // new right part
// Added by Tim. p3.3.6
//printf("Track::splitPart part ev %p sz:%d ref:%d p1 %p sz:%d ref:%d p2 %p sz:%d ref:%d\n", part->events(), part->events()->size(), part->events()->arefCount(), p1->events(), p1->events()->size(), p1->events()->arefCount(), p2->events(), p2->events()->size(), p2->events()->arefCount());
{
p1->setLenTick(l1);
p2->setTick(tickpos);
p2->setLenTick(l2);
}
p2->setSn(p2->newSn());
EventList* se = part->events();
EventList* de1 = p1->events();
EventList* de2 = p2->events();
p1->setColorIndex(part->colorIndex());
p2->setColorIndex(part->colorIndex());
{
for (iEvent ie = se->begin(); ie != se->end(); ++ie)
{
Event event = ie->second.clone();
int t = event.tick();
if (t >= l1)
{
event.move(-l1);
de2->add(event);
}
else
de1->add(event);
}
}
}
std::vector<double> beatTrack(const AgentParameters ¶ms,
const EventList &events,
const EventList &beats)
{
AgentList agents;
int count = 0;
double beatTime = -1;
if (!beats.empty()) {
count = beats.size() - 1;
EventList::const_iterator itr = beats.end();
--itr;
beatTime = itr->time;
}
if (count > 0) { // tempo given by mean of initial beats
double ioi = (beatTime - beats.begin()->time) / count;
agents.push_back(new Agent(params, ioi));
}
else // tempo not given; use tempo induction
agents = Induction::beatInduction(params, events);
if (!beats.empty()) {
for (AgentList::iterator itr = agents.begin(); itr != agents.end(); ++itr) {
(*itr)->beatTime = beatTime;
(*itr)->beatCount = count;
(*itr)->events = beats;
}
}
agents.beatTrack(events, params, -1);
Agent *best = agents.bestAgent();
std::vector<double> resultBeatTimes;
if (best) {
best->fillBeats(beatTime);
for (EventList::const_iterator itr = best->events.begin();
itr != best->events.end(); ++itr) {
resultBeatTimes.push_back(itr->time);
}
}
for (AgentList::iterator ai = agents.begin(); ai != agents.end(); ++ai) {
delete *ai;
}
return resultBeatTimes;
}
void AgentList::beatTrack(const EventList &el,
const AgentParameters ¶ms,
double stop)
{
EventList::const_iterator ei = el.begin();
bool phaseGiven = !empty() && ((*begin())->beatTime >= 0); // if given for one, assume given for others
while (ei != el.end()) {
Event ev = *ei;
++ei;
if ((stop > 0) && (ev.time > stop))
break;
bool created = phaseGiven;
double prevBeatInterval = -1.0;
// cc: Duplicate our list of agents, and scan through the
// copy. This means we can safely add agents to our own
// list while scanning without disrupting our scan. Each
// agent needs to be re-added to our own list explicitly
// (since it is modified by e.g. considerAsBeat)
Container currentAgents = list;
list.clear();
for (Container::iterator ai = currentAgents.begin();
ai != currentAgents.end(); ++ai) {
Agent *currentAgent = *ai;
if (currentAgent->beatInterval != prevBeatInterval) {
if ((prevBeatInterval >= 0) && !created && (ev.time < 5.0)) {
// Create new agent with different phase
Agent *newAgent = new Agent(params, prevBeatInterval);
// This may add another agent to our list as well
newAgent->considerAsBeat(ev, *this);
add(newAgent);
}
prevBeatInterval = currentAgent->beatInterval;
created = phaseGiven;
}
if (currentAgent->considerAsBeat(ev, *this))
created = true;
add(currentAgent);
} // loop for each agent
removeDuplicates();
} // loop for each event
}
void EventCanvas::songChanged(int flags)/*{{{*/
{
// Is it simply a midi controller value adjustment? Forget it.
if (flags == SC_MIDI_CONTROLLER)
return;
if (flags & ~SC_SELECTION)
{
_items.clear();
start_tick = MAXINT;
end_tick = 0;
_curPart = 0;
for (iPart p = editor->parts()->begin(); p != editor->parts()->end(); ++p)
{
MidiPart* part = (MidiPart*) (p->second);
if (part->sn() == _curPartId)
_curPart = part;
unsigned stick = part->tick();
unsigned len = part->lenTick();
unsigned etick = stick + len;
if (stick < start_tick)
start_tick = stick;
if (etick > end_tick)
end_tick = etick;
EventList* el = part->events();
for (iEvent i = el->begin(); i != el->end(); ++i)
{
Event e = i->second;
if (e.isNote())
{
addItem(part, e);
}
}
}
}
Event event;
MidiPart* part = 0;
int x = 0;
CItem* nevent = 0;
int n = 0; // count selections
for (iCItem k = _items.begin(); k != _items.end(); ++k)
{
Event ev = k->second->event();
bool selected = ev.selected();
if (selected)
{
k->second->setSelected(true);
++n;
if (!nevent)
{
nevent = k->second;
Event mi = nevent->event();
curVelo = mi.velo();
}
}
}
start_tick = song->roundDownBar(start_tick);
end_tick = song->roundUpBar(end_tick);
if (n == 1)
{
x = nevent->x();
event = nevent->event();
part = (MidiPart*) nevent->part();
if (_curPart != part)
{
_curPart = part;
_curPartId = _curPart->sn();
curPartChanged();
}
}
emit selectionChanged(x, event, part);
if (_curPart == 0)
{
_curPart = (MidiPart*) (editor->parts()->begin()->second);
if(_curPart)
{
editor->setCurCanvasPart(_curPart);
}
}
updateCItemsZValues();
redraw();
}/*}}}*/
ThreadPoolTaskExecutor::EventList ThreadPoolTaskExecutor::makeSingletonEventList() {
EventList result;
result.emplace_front(EventState::make());
result.front()->iter = result.begin();
return result;
}
void Audio::initDevices()
{
//
// mark all used ports
//
bool activePorts[MIDI_PORTS];
for (int i = 0; i < MIDI_PORTS; ++i)
activePorts[i] = false;
MidiTrackList* tracks = song->midis();
for (iMidiTrack it = tracks->begin(); it != tracks->end(); ++it)
{
MidiTrack* track = *it;
activePorts[track->outPort()] = true;
}
if (song->click())
activePorts[clickPort] = true;
//
// test for explicit instrument initialization
//
for (int i = 0; i < MIDI_PORTS; ++i)
{
if (!activePorts[i])
continue;
MidiPort* port = &midiPorts[i];
MidiInstrument* instr = port->instrument();
MidiDevice* md = port->device();
if (instr && md)
{
EventList* events = instr->midiInit();
if (events->empty())
continue;
for (iEvent ie = events->begin(); ie != events->end(); ++ie)
{
MidiPlayEvent ev(0, i, 0, ie->second);
md->putEvent(ev);
}
activePorts[i] = false; // no standard initialization
}
}
//
// damit Midi-Devices, die mehrere Ports besitzen, wie z.B.
// das Korg NS5R, nicht mehrmals zwischen GM und XG/GS hin und
// hergeschaltet werden, wird zunïÿýhst auf allen Ports GM
// initialisiert, und dann erst XG/GS
//
// Standard initialization...
for (int i = 0; i < MIDI_PORTS; ++i)
{
if (!activePorts[i])
continue;
MidiPort* port = &midiPorts[i];
switch (song->mtype())
{
case MT_GS:
case MT_UNKNOWN:
break;
case MT_GM:
case MT_XG:
port->sendGmOn();
break;
}
}
for (int i = 0; i < MIDI_PORTS; ++i)
{
if (!activePorts[i])
continue;
MidiPort* port = &midiPorts[i];
switch (song->mtype())
{
case MT_UNKNOWN:
break;
case MT_GM:
port->sendGmInitValues();
break;
case MT_GS:
port->sendGsOn();
port->sendGsInitValues();
break;
case MT_XG:
port->sendXgOn();
port->sendXgInitValues();
break;
}
}
}
AgentList Induction::beatInduction(const AgentParameters ¶ms,
const EventList &events)
{
int i, j, b, bestCount;
bool submult;
int intervals = 0; // number of interval clusters
std::vector<int> bestn; // count of high-scoring clusters
bestn.resize(topN);
double ratio, err;
int degree;
int maxClusterCount = (int) ceil((maxIOI - minIOI) / clusterWidth);
std::vector<double> clusterMean;
clusterMean.resize(maxClusterCount);
std::vector<int> clusterSize;
clusterSize.resize(maxClusterCount);
std::vector<int> clusterScore;
clusterScore.resize(maxClusterCount);
EventList::const_iterator ptr1, ptr2;
Event e1, e2;
ptr1 = events.begin();
while (ptr1 != events.end()) {
e1 = *ptr1;
++ptr1;
ptr2 = events.begin();
e2 = *ptr2;
++ptr2;
while (e2 != e1 && ptr2 != events.end()) {
e2 = *ptr2;
++ptr2;
}
while (ptr2 != events.end()) {
e2 = *ptr2;
++ptr2;
double ioi = e2.time - e1.time;
if (ioi < minIOI) // skip short intervals
continue;
if (ioi > maxIOI) // ioi too long
break;
for (b = 0; b < intervals; b++) // assign to nearest cluster
if (std::fabs(clusterMean[b] - ioi) < clusterWidth) {
if ((b < intervals - 1) && (std::fabs(clusterMean[b + 1] - ioi)
< std::fabs(clusterMean[b] - ioi))) {
b++; // next cluster is closer
}
clusterMean[b] = (clusterMean[b] * clusterSize[b] + ioi)
/ (clusterSize[b] + 1);
clusterSize[b]++;
break;
}
if (b == intervals) { // no suitable cluster; create new one
if (intervals == maxClusterCount) {
// System.err.println("Warning: Too many clusters");
continue; // ignore this IOI
}
intervals++;
for ( ; (b > 0) && (clusterMean[b - 1] > ioi); b--) {
clusterMean[b] = clusterMean[b - 1];
clusterSize[b] = clusterSize[b - 1];
}
clusterMean[b] = ioi;
clusterSize[b] = 1;
}
}
}
for (b = 0; b < intervals; b++) // merge similar intervals
// TODO: they are now in order, so don't need the 2nd loop
// TODO: check BOTH sides before averaging or upper gps don't work
for (i = b + 1; i < intervals; i++)
if (std::fabs(clusterMean[b] - clusterMean[i]) < clusterWidth) {
clusterMean[b] = (clusterMean[b] * clusterSize[b] +
clusterMean[i] * clusterSize[i]) /
(clusterSize[b] + clusterSize[i]);
clusterSize[b] = clusterSize[b] + clusterSize[i];
--intervals;
for (j = i + 1; j <= intervals; j++) {
clusterMean[j - 1] = clusterMean[j];
clusterSize[j - 1] = clusterSize[j];
}
}
if (intervals == 0)
return AgentList();
for (b = 0; b < intervals; b++)
clusterScore[b] = 10 * clusterSize[b];
bestn[0] = 0;
bestCount = 1;
for (b = 0; b < intervals; b++) {
for (i = 0; i <= bestCount; i++) {
if (i < topN && (i == bestCount || clusterScore[b] > clusterScore[bestn[i]])) {
if (bestCount < topN)
bestCount++;
for (j = bestCount - 1; j > i; j--)
bestn[j] = bestn[j - 1];
bestn[i] = b;
break;
}
}
}
for (b = 0; b < intervals; b++) { // score intervals
for (i = b + 1; i < intervals; i++) {
ratio = clusterMean[b] / clusterMean[i];
submult = ratio < 1;
if (submult)
degree = (int) nearbyint(1 / ratio);
else
degree = (int) nearbyint(ratio);
if ((degree >= 2) && (degree <= 8)) {
if (submult)
err = std::fabs(clusterMean[b] * degree - clusterMean[i]);
else
err = std::fabs(clusterMean[b] - clusterMean[i] * degree);
if (err < (submult ? clusterWidth : clusterWidth * degree)) {
if (degree >= 5)
degree = 1;
else
degree = 6 - degree;
clusterScore[b] += degree * clusterSize[i];
clusterScore[i] += degree * clusterSize[b];
}
}
}
}
AgentList a;
for (int index = 0; index < bestCount; index++) {
b = bestn[index];
// Adjust it, using the size of super- and sub-intervals
double newSum = clusterMean[b] * clusterScore[b];
int newCount = clusterSize[b];
int newWeight = clusterScore[b];
for (i = 0; i < intervals; i++) {
if (i == b)
continue;
ratio = clusterMean[b] / clusterMean[i];
if (ratio < 1) {
degree = (int) nearbyint(1 / ratio);
if ((degree >= 2) && (degree <= 8)) {
err = std::fabs(clusterMean[b] * degree - clusterMean[i]);
if (err < clusterWidth) {
newSum += clusterMean[i] / degree * clusterScore[i];
newCount += clusterSize[i];
newWeight += clusterScore[i];
}
}
}
else {
degree = (int) nearbyint(ratio);
if ((degree >= 2) && (degree <= 8)) {
err = std::fabs(clusterMean[b] - degree * clusterMean[i]);
if (err < clusterWidth * degree) {
newSum += clusterMean[i] * degree * clusterScore[i];
newCount += clusterSize[i];
newWeight += clusterScore[i];
}
}
}
}
double beat = newSum / newWeight;
// Scale within range ... hope the grouping isn't ternary :(
while (beat < minIBI) // Maximum speed
beat *= 2.0;
while (beat > maxIBI) // Minimum speed
beat /= 2.0;
if (beat >= minIBI) {
a.push_back(new Agent(params, beat));
}
}
return a;
}
void Audio::preloadControllers()/*{{{*/
{
midiBusy = true;
MidiTrackList* tracks = song->midis();
for (iMidiTrack it = tracks->begin(); it != tracks->end(); ++it)
{
MidiTrack* track = *it;
//activePorts[track->outPort()] = true;
QList<ProcessList*> pcevents;
int port = track->outPort();
int channel = track->outChannel();
int defaultPort = port;
MidiDevice* md = midiPorts[port].device();
if (!md)
{
continue;
}
MPEventList* playEvents = md->playEvents();
playEvents->erase(playEvents->begin(), playEvents->end());
PartList* pl = track->parts();
for (iPart p = pl->begin(); p != pl->end(); ++p)
{
MidiPart* part = (MidiPart*) (p->second);
EventList* events = part->events();
unsigned partTick = part->tick();
//unsigned partLen = part->lenTick();
int delay = track->delay;
unsigned offset = delay + partTick;
for (iEvent ie = events->begin(); ie != events->end(); ++ie)
{
Event ev = ie->second;
port = defaultPort;
unsigned tick = ev.tick() + offset;
//unsigned frame = tempomap.tick2frame(tick) + frameOffset;
switch (ev.dataA())
{
case CTRL_PROGRAM:
{
ProcessList *pl = new ProcessList;
pl->port = port;
pl->channel = channel;
pl->dataB = ev.dataB();
bool addEvent = true;
for(int i = 0; i < pcevents.size(); ++i)
{
ProcessList* ipl = pcevents.at(i);
if(ipl->port == pl->port && ipl->channel == pl->channel && ipl->dataB == pl->dataB)
{
addEvent = false;
break;
}
}
if(addEvent)
{
printf("Audio::preloadControllers() Loading event @ tick: %d - on channel: %d - on port: %d - dataA: %d - dataB: %d\n",
tick, channel, port, ev.dataA(), ev.dataB());
pcevents.append(pl);
playEvents->add(MidiPlayEvent(tick, port, channel, ev));
}
}
break;
default:
break;
}
}
}
md->setNextPlayEvent(playEvents->begin());
}
midiBusy = false;
}/*}}}*/
void buildMidiEventList(EventList* del, const MPEventList* el, MidiTrack* track,
int div, bool addSysexMeta, bool doLoops)
{
int hbank = 0xff;
int lbank = 0xff;
int rpnh = -1;
int rpnl = -1;
int datah = 0;
int datal = 0;
int dataType = 0; // 0 : disabled, 0x20000 : rpn, 0x30000 : nrpn
EventList mel;
for (iMPEvent i = el->begin(); i != el->end(); ++i)
{
MidiPlayEvent ev = *i;
if (!addSysexMeta && (ev.type() == ME_SYSEX || ev.type() == ME_META))
continue;
if (!(ev.type() == ME_SYSEX || ev.type() == ME_META
|| ((ev.channel() == track->outChannel()) && (ev.port() == track->outPort()))))
continue;
unsigned tick = ev.time();
// Added by Tim. p3.3.8
// Added by T356.
if (doLoops)
{
if (tick >= song->lPos().tick() && tick < song->rPos().tick())
{
int loopn = ev.loopNum();
int loopc = audio->loopCount();
int cmode = song->cycleMode(); // CYCLE_NORMAL, CYCLE_MIX, CYCLE_REPLACE
// If we want REPLACE and the event was recorded in a previous loop,
// just ignore it. This will effectively ignore ALL previous loop events inside
// the left and right markers, regardless of where recording was started or stopped.
// We want to keep any loop 0 note-offs from notes which crossed over the left marker.
// To avoid more searching here, just keep ALL note-offs from loop 0, and let code below
// sort out and keep which ones had note-ons.
if (!(ev.isNoteOff() && loopn == 0))
{
if (cmode == Song::CYCLE_REPLACE && loopn < loopc)
{
// Added by Tim. p3.3.8
//printf("buildMidiEventList: CYCLE_REPLACE t:%d type:%d A:%d B:%d ln:%d lc:%d\n", tick, ev.type(), ev.dataA(), ev.dataB(), loopn, loopc);
continue;
}
// If we want NORMAL, same as REPLACE except keep all events from the previous loop
// from rec stop position to right marker (and beyond).
if (cmode == Song::CYCLE_NORMAL)
{
// Not sure of accuracy here. Adjust? Adjusted when used elsewhere?
unsigned endRec = audio->getEndRecordPos().tick();
if ((tick < endRec && loopn < loopc) || (tick >= endRec && loopn < (loopc - 1)))
{
// Added by Tim. p3.3.8
//printf("buildMidiEventList: CYCLE_NORMAL t:%d type:%d A:%d B:%d ln:%d lc:%d\n", tick, ev.type(), ev.dataA(), ev.dataB(), loopn, loopc);
continue;
}
}
}
}
}
Event e;
switch (ev.type())
{
case ME_NOTEON:
e.setType(Note);
if (track->type() == Track::DRUM)
{
int instr = drumInmap[ev.dataA()];
e.setPitch(instr);
}
else
{
e.setPitch(ev.dataA());
}
e.setVelo(ev.dataB());
e.setLenTick(0);
break;
case ME_NOTEOFF:
e.setType(Note);
if (track->type() == Track::DRUM)
{
int instr = drumInmap[ev.dataA()];
e.setPitch(instr);
}
else
e.setPitch(ev.dataA());
e.setVelo(0);
e.setVeloOff(ev.dataB());
e.setLenTick(0);
break;
case ME_POLYAFTER:
e.setType(PAfter);
e.setA(ev.dataA());
e.setB(ev.dataB());
break;
case ME_CONTROLLER:
{
int val = ev.dataB();
switch (ev.dataA())
{
case CTRL_HBANK:
hbank = val;
break;
case CTRL_LBANK:
lbank = val;
break;
case CTRL_HDATA:
datah = val;
// check if a CTRL_LDATA follows
// e.g. wie have a 14 bit controller:
{
iMPEvent ii = i;
++ii;
bool found = false;
for (; ii != el->end(); ++ii)
{
MidiPlayEvent ev = *ii;
if (ev.type() == ME_CONTROLLER)
{
if (ev.dataA() == CTRL_LDATA)
{
// handle later
found = true;
}
break;
}
}
if (!found)
{
if (rpnh == -1 || rpnl == -1)
{
printf("parameter number not defined, data 0x%x\n", datah);
}
else
{
int ctrl = dataType | (rpnh << 8) | rpnl;
e.setType(Controller);
e.setA(ctrl);
e.setB(datah);
}
}
}
break;
case CTRL_LDATA:
datal = val;
if (rpnh == -1 || rpnl == -1)
{
printf("parameter number not defined, data 0x%x 0x%x, tick %d, channel %d\n",
datah, datal, tick, track->outChannel());
break;
}
// assume that the sequence is always
// CTRL_HDATA - CTRL_LDATA
// eg. that LDATA is always send last
e.setType(Controller);
// 14 Bit RPN/NRPN
e.setA((dataType + 0x30000) | (rpnh << 8) | rpnl);
e.setB((datah << 7) | datal);
break;
case CTRL_HNRPN:
rpnh = val;
dataType = 0x30000;
break;
case CTRL_LNRPN:
rpnl = val;
dataType = 0x30000;
break;
case CTRL_HRPN:
rpnh = val;
dataType = 0x20000;
break;
case CTRL_LRPN:
rpnl = val;
dataType = 0x20000;
break;
default:
e.setType(Controller);
int ctl = ev.dataA();
e.setA(ctl);
if (track->type() == Track::DRUM)
{
// Is it a drum controller event, according to the track port's instrument?
MidiController *mc = midiPorts[track->outPort()].drumController(ctl);
if (mc)
// Store an index into the drum map.
e.setA((ctl & ~0xff) | drumInmap[ctl & 0x7f]);
}
e.setB(val);
break;
}
}
break;
case ME_PROGRAM:
e.setType(Controller);
e.setA(CTRL_PROGRAM);
e.setB((hbank << 16) | (lbank << 8) | ev.dataA());
break;
case ME_AFTERTOUCH:
e.setType(CAfter);
e.setA(ev.dataA());
break;
case ME_PITCHBEND:
e.setType(Controller);
e.setA(CTRL_PITCH);
e.setB(ev.dataA());
break;
case ME_SYSEX:
e.setType(Sysex);
e.setData(ev.data(), ev.len());
break;
case ME_META:
{
const unsigned char* data = ev.data();
switch (ev.dataA())
{
case 0x01: // Text
if (track->comment().isEmpty())
track->setComment(QString((const char*) data));
else
track->setComment(track->comment() + "\n" + QString((const char*) data));
break;
case 0x03: // Sequence-/TrackName
track->setName(QString((char*) data));
break;
case 0x6: // Marker
{
unsigned ltick = CALC_TICK(tick); //(tick * config.division + div/2) / div;
song->addMarker(QString((const char*) (data)), ltick, false);
}
break;
case 0x5: // Lyrics
case 0x8: // text
case 0x9:
case 0xa:
break;
case 0x0f: // Track Comment
track->setComment(QString((char*) data));
break;
case 0x51: // Tempo
{
unsigned tempo = data[2] + (data[1] << 8) + (data[0] << 16);
unsigned ltick = CALC_TICK(tick); // (unsigned(tick) * unsigned(config.division) + unsigned(div/2)) / unsigned(div);
// After ca 10 mins 32 bits will not be enough... This expression has to be changed/factorized or so in some "sane" way...
tempomap.addTempo(ltick, tempo);
}
break;
case 0x58: // Time Signature
{
int timesig_z = data[0];
int n = data[1];
int timesig_n = 1;
for (int i = 0; i < n; i++)
timesig_n *= 2;
int ltick = CALC_TICK(tick); //(tick * config.division + div/2) / div;
///sigmap.add(ltick, timesig_z, timesig_n);
AL::sigmap.add(ltick, AL::TimeSignature(timesig_z, timesig_n));
}
break;
case 0x59: // Key Signature
// track->scale.set(data[0]);
// track->scale.setMajorMinor(data[1]);
break;
default:
printf("unknown Meta 0x%x %d\n", ev.dataA(), ev.dataA());
}
}
break;
} // switch(ev.type()
if (!e.empty())
{
e.setTick(tick);
// Added by Tim. p3.3.8
//printf("buildMidiEventList: mel adding t:%d type:%d A:%d B:%d C:%d\n", tick, e.type(), e.dataA(), e.dataB(), e.dataC());
mel.add(e);
}
} // i != el->end()
//---------------------------------------------------
// resolve NoteOff events
//---------------------------------------------------
// for (iEvent i = mel.begin(); i != mel.end(); ++i) {
// Event event = i->second;
// if (event.isNote())
// event.setLenTick(0);
// }
// Added by Tim. p3.3.8
// The loop is a safe way to delete while iterating.
bool loop;
do
{
loop = false;
for (iEvent i = mel.begin(); i != mel.end(); ++i)
{
Event ev = i->second;
if (ev.isNote())
{
if (ev.isNoteOff())
{
iEvent k;
bool found = false;
for (k = i; k != mel.end(); ++k)
{
Event event = k->second;
if (event.tick() > ev.tick())
break;
if (event.isNoteOff(ev))
{
ev.setLenTick(1);
ev.setVelo(event.velo());
ev.setVeloOff(0);
// Added by Tim. p3.3.8
//printf("buildMidiEventList: found note off: event t:%d len:%d type:%d A:%d B:%d C:%d ev t:%d len:%d type:%d A:%d B:%d C:%d\n", event.tick(), event.lenTick(), event.type(), event.dataA(), event.dataB(), event.dataC(), ev.tick(), ev.lenTick(), ev.type(), ev.dataA(), ev.dataB(), ev.dataC());
found = true;
break;
}
}
if (!found)
{
printf("NOTE OFF without Note ON tick %d type %d %d %d\n",
ev.tick(), ev.type(), ev.pitch(), ev.velo());
}
else
{
mel.erase(k);
// Changed by Tim. p3.3.8
//continue;
loop = true;
break;
}
}
// Added by Tim. p3.3.8
// If the event length is not zero, it means the event and its
// note on/off have already been taken care of. So ignore it.
if (ev.lenTick() != 0)
{
continue;
}
iEvent k;
for (k = mel.lower_bound(ev.tick()); k != mel.end(); ++k)
{
Event event = k->second;
if (ev.isNoteOff(event))
{
int t = k->first - i->first;
if (t <= 0)
{
if (debugMsg)
{
printf("Note len is (%d-%d)=%d, set to 1\n",
k->first, i->first, k->first - i->first);
ev.dump();
event.dump();
}
t = 1;
}
ev.setLenTick(t);
ev.setVeloOff(event.veloOff());
// Added by Tim. p3.3.8
//printf("buildMidiEventList: set len and velOff: event t:%d len:%d type:%d A:%d B:%d C:%d ev t:%d len:%d type:%d A:%d B:%d C:%d\n", event.tick(), event.lenTick(), event.type(), event.dataA(), event.dataB(), event.dataC(), ev.tick(), ev.lenTick(), ev.type(), ev.dataA(), ev.dataB(), ev.dataC());
break;
}
}
if (k == mel.end())
{
printf("-no note-off! %d pitch %d velo %d\n",
ev.tick(), ev.pitch(), ev.velo());
//
// switch off at end of measure
//
int endTick = song->roundUpBar(ev.tick() + 1);
ev.setLenTick(endTick - ev.tick());
}
else
{
mel.erase(k);
// Added by Tim. p3.3.8
loop = true;
break;
}
}
}
} while (loop);
// DEBUG: any note offs left?
// Removed by Tim. p3.3.8
//for (iEvent i = mel.begin(); i != mel.end(); ++i) {
// Event ev = i->second;
// if (ev.isNoteOff()) {
// printf("+extra note-off! %d pitch %d velo %d\n",
// i->first, ev.pitch(), ev.velo());
// ev.dump();
// }
// }
for (iEvent i = mel.begin(); i != mel.end(); ++i)
{
Event ev = i->second;
if (ev.isNoteOff())
{
printf("+extra note-off! %d pitch %d velo %d\n",
i->first, ev.pitch(), ev.velo());
// ev.dump();
continue;
}
int tick = CALC_TICK(ev.tick()); //(ev.tick() * config.division + div/2) / div;
if (ev.isNote())
{
int lenTick = CALC_TICK(ev.lenTick()); //(ev.lenTick() * config.division + div/2) / div;
ev.setLenTick(lenTick);
}
ev.setTick(tick);
del->add(ev);
}
}
void Track::splitPart(Part* part, int tickpos, Part*& p1, Part*& p2)
{
int l1 = 0; // len of first new part (ticks or samples)
int l2 = 0; // len of second new part
int samplepos = tempomap.tick2frame(tickpos);
switch (type())
{
case WAVE:
l1 = samplepos - part->frame();
l2 = part->lenFrame() - l1;
break;
case MIDI:
case DRUM:
l1 = tickpos - part->tick();
l2 = part->lenTick() - l1;
break;
default:
return;
}
if (l1 <= 0 || l2 <= 0)
return;
p1 = newPart(part); // new left part
p2 = newPart(part); // new right part
// Added by Tim. p3.3.6
//printf("Track::splitPart part ev %p sz:%d ref:%d p1 %p sz:%d ref:%d p2 %p sz:%d ref:%d\n", part->events(), part->events()->size(), part->events()->arefCount(), p1->events(), p1->events()->size(), p1->events()->arefCount(), p2->events(), p2->events()->size(), p2->events()->arefCount());
switch (type())
{
case WAVE:
p1->setLenFrame(l1);
p2->setFrame(samplepos);
p2->setLenFrame(l2);
break;
case MIDI:
case DRUM:
p1->setLenTick(l1);
p2->setTick(tickpos);
p2->setLenTick(l2);
break;
default:
break;
}
p2->setSn(p2->newSn());
EventList* se = part->events();
EventList* de1 = p1->events();
EventList* de2 = p2->events();
if (type() == WAVE)
{
int ps = part->frame();
int d1p1 = p1->frame();
int d2p1 = p1->endFrame();
int d1p2 = p2->frame();
int d2p2 = p2->endFrame();
for (iEvent ie = se->begin(); ie != se->end(); ++ie)
{
Event event = ie->second;
int s1 = event.frame() + ps;
int s2 = event.endFrame() + ps;
if ((s2 > d1p1) && (s1 < d2p1))
{
Event si = event.mid(d1p1 - ps, d2p1 - ps);
de1->add(si);
}
if ((s2 > d1p2) && (s1 < d2p2))
{
Event si = event.mid(d1p2 - ps, d2p2 - ps);
de2->add(si);
}
}
}
else
{
for (iEvent ie = se->begin(); ie != se->end(); ++ie)
{
Event event = ie->second.clone();
int t = event.tick();
if (t >= l1)
{
event.move(-l1);
de2->add(event);
}
else
de1->add(event);
}
}
}
void Song::cmdResizePart(Track* track, Part* oPart, unsigned int len)
{
switch (track->type())
{
case Track::WAVE:
{
WavePart* nPart = new WavePart(*(WavePart*) oPart);
EventList* el = nPart->events();
unsigned new_partlength = tempomap.deltaTick2frame(oPart->tick(), oPart->tick() + len);
//printf("new partlength in frames: %d\n", new_partlength);
// If new nr of frames is less than previous what can happen is:
// - 0 or more events are beginning after the new final position. Those are removed from the part
// - The last event begins before new final position and ends after it. If so, it will be resized to end at new part length
if (new_partlength < oPart->lenFrame())
{
startUndo();
for (iEvent i = el->begin(); i != el->end(); i++)
{
Event e = i->second;
unsigned event_startframe = e.frame();
unsigned event_endframe = event_startframe + e.lenFrame();
//printf("Event frame=%d, length=%d\n", event_startframe, event_length);
if (event_endframe < new_partlength)
continue;
if (event_startframe > new_partlength)
{ // If event start was after the new length, remove it from part
// Indicate no undo, and do not do port controller values and clone parts.
//audio->msgDeleteEvent(e, nPart, false);
audio->msgDeleteEvent(e, nPart, false, false, false);
continue;
}
if (event_endframe > new_partlength)
{ // If this event starts before new length and ends after, shrink it
Event newEvent = e.clone();
newEvent.setLenFrame(new_partlength - event_startframe);
// Indicate no undo, and do not do port controller values and clone parts.
//audio->msgChangeEvent(e, newEvent, nPart, false);
audio->msgChangeEvent(e, newEvent, nPart, false, false, false);
}
}
nPart->setLenFrame(new_partlength);
// Indicate no undo, and do not do port controller values and clone parts.
//audio->msgChangePart(oPart, nPart, false);
audio->msgChangePart(oPart, nPart, false, false, false);
endUndo(SC_PART_MODIFIED);
}
// If the part is expanded there can be no additional events beginning after the previous final position
// since those are removed if the part has been shrunk at some time (see above)
// The only thing we need to check is the final event: If it has data after the previous final position,
// we'll expand that event
else
{
if (!el->empty())
{
iEvent i = el->end();
i--;
Event last = i->second;
unsigned last_start = last.frame();
SndFileR file = last.sndFile();
if (file.isNull())
return;
unsigned clipframes = (file.samples() - last.spos()); // / file.channels();
Event newEvent = last.clone();
//printf("SndFileR samples=%d channels=%d event samplepos=%d clipframes=%d\n", file.samples(), file.channels(), last.spos(), clipframes);
unsigned new_eventlength = new_partlength - last_start;
if (new_eventlength > clipframes) // Shrink event length if new partlength exceeds last clip
new_eventlength = clipframes;
newEvent.setLenFrame(new_eventlength);
startUndo();
// Indicate no undo, and do not do port controller values and clone parts.
//audio->msgChangeEvent(last, newEvent, nPart, false);
audio->msgChangeEvent(last, newEvent, nPart, false, false, false);
}
else
{
startUndo();
}
nPart->setLenFrame(new_partlength);
// Indicate no undo, and do not do port controller values and clone parts.
//audio->msgChangePart(oPart, nPart, false);
audio->msgChangePart(oPart, nPart, false, false, false);
endUndo(SC_PART_MODIFIED);
}
}
break;
case Track::MIDI:
case Track::DRUM:
{
startUndo();
MidiPart* nPart = new MidiPart(*(MidiPart*) oPart);
nPart->setLenTick(len);
// Indicate no undo, and do port controller values but not clone parts.
audio->msgChangePart(oPart, nPart, false, true, false);
// cut Events in nPart
// Changed by T356. Don't delete events if this is a clone part.
// The other clones might be longer than this one and need these events.
if (nPart->cevents()->arefCount() <= 1)
{
if (oPart->lenTick() > len)
{
EventList* el = nPart->events();
iEvent ie = el->lower_bound(len);
for (; ie != el->end();)
{
iEvent i = ie;
++ie;
// Indicate no undo, and do port controller values and clone parts.
audio->msgDeleteEvent(i->second, nPart, false, true, true);
}
}
}
/*
// cut Events in nPart
// Changed by T356. Don't delete events if this is a clone part.
// The other clones might be longer than this one and need these events.
if(oPart->cevents()->arefCount() <= 1)
{
if (oPart->lenTick() > len) {
EventList* el = nPart->events();
iEvent ie = el->lower_bound(len);
for (; ie != el->end();) {
iEvent i = ie;
++ie;
// Indicate no undo, and do not do port controller values and clone parts.
//audio->msgDeleteEvent(i->second, nPart, false);
audio->msgDeleteEvent(i->second, nPart, false, false, false);
}
}
}
// Indicate no undo, and do port controller values but not clone parts.
//audio->msgChangePart(oPart, nPart, false);
audio->msgChangePart(oPart, nPart, false, true, false);
*/
endUndo(SC_PART_MODIFIED);
break;
}
default:
break;
}
}
PyObject* getParts(PyObject*, PyObject* args)
{
TrackList* tracks = song->tracks();
const char* trackname;
if (!PyArg_ParseTuple(args, "s", &trackname))
{
return NULL;
}
PyObject* pyparts = Py_BuildValue("[]");
for (ciTrack t = tracks->begin(); t != tracks->end(); ++t)
{
Track* track = *t;
if (track->name() != trackname)
continue;
PartList* parts = track->parts();
for (ciPart p = parts->begin(); p != parts->end(); p++)
{
Part* part = p->second;
MidiPart* mpart = (MidiPart*) part;
PyObject* pypart = PyDict_New();
int tick = mpart->tick();
int lentick = mpart->lenTick();
int serialnr = mpart->sn();
PyObject* pstrtick = Py_BuildValue("s", "tick");
PyObject* pitick = Py_BuildValue("i", tick);
PyObject* pstrid = Py_BuildValue("s", "id");
PyObject* pstrserial = Py_BuildValue("i", serialnr);
PyObject* pstrlen = Py_BuildValue("s", "len");
PyObject* pstrtick2 = Py_BuildValue("i", lentick);
PyDict_SetItem(pypart, pstrtick, pitick);
PyDict_SetItem(pypart, pstrid, pstrserial);
PyDict_SetItem(pypart, pstrlen, pstrtick2);
Py_DECREF(pstrtick);
Py_DECREF(pitick);
Py_DECREF(pstrid);
Py_DECREF(pstrserial);
Py_DECREF(pstrlen);
Py_DECREF(pstrtick2);
// Pack midi events into list before wrapping it all up
EventList* events = mpart->events();
PyObject* pyevents = Py_BuildValue("[]");
for (ciEvent e = events->begin(); e != events->end(); e++)
{
PyObject* pyevent = PyDict_New(); // The event structure - a dictionary with keys 'type','tick','data'
const Event& event = e->second;
unsigned tick = e->first;
PyObject* eventdata = Py_BuildValue("[i,i,i]", event.dataA(), event.dataB(), event.dataC());
PyObject* pstrdata = Py_BuildValue("s", "data");
pstrtick = Py_BuildValue("s", "tick");
PyObject* pitickval = Py_BuildValue("i", tick);
PyDict_SetItem(pyevent, pstrdata, eventdata);
PyDict_SetItem(pyevent, pstrtick, pitickval);
Py_DECREF(eventdata);
Py_DECREF(pstrdata);
Py_DECREF(pstrtick);
Py_DECREF(pitickval);
switch (event.type())
{
case Note:
{
PyObject* pstrtype = Py_BuildValue("s", "type");
PyObject* pstrnote = Py_BuildValue("s", "note");
PyObject* pstrlen = Py_BuildValue("s", "len");
PyObject* pilentick = Py_BuildValue("i", event.lenTick());
PyDict_SetItem(pyevent, pstrtype, pstrnote);
PyDict_SetItem(pyevent, pstrlen, pilentick);
Py_DECREF(pstrtype);
Py_DECREF(pstrnote);
Py_DECREF(pstrlen);
Py_DECREF(pilentick);
break;
}
case Controller:
{
PyObject* pstrtype = Py_BuildValue("s", "type");
PyObject* pstrctrl = Py_BuildValue("s", "ctrl");
PyDict_SetItem(pyevent, pstrtype, pstrctrl);
Py_DECREF(pstrtype);
Py_DECREF(pstrctrl);
break;
}
default:
printf("Event type not supported yet: %d\n", event.type());
break;
}
PyList_Append(pyevents, pyevent);
Py_DECREF(pyevent);
}
Py_DECREF(pyevents);
// Add the event list to the pypart dictionary
PyObject* pystrevents = Py_BuildValue("s", "events");
PyDict_SetItem(pypart, pystrevents, pyevents);
Py_DECREF(pystrevents);
PyList_Append(pyparts, pypart);
Py_DECREF(pypart);
}
return pyparts;
}
return NULL;
}
QMimeData* EventCanvas::getTextDrag()
{
//---------------------------------------------------
// generate event list from selected events
//---------------------------------------------------
EventList el;
unsigned startTick = MAXINT;
for (iCItem i = _items.begin(); i != _items.end(); ++i)
{
if (!i->second->isSelected())
continue;
///NEvent* ne = (NEvent*)(i->second);
CItem* ne = i->second;
Event e = ne->event();
if (startTick == MAXINT)
startTick = e.tick();
el.add(e);
}
//---------------------------------------------------
// write events as XML into tmp file
//---------------------------------------------------
FILE* tmp = tmpfile();
if (tmp == 0)
{
fprintf(stderr, "EventCanvas::getTextDrag() fopen failed: %s\n",
strerror(errno));
return 0;
}
Xml xml(tmp);
int level = 0;
xml.tag(level++, "eventlist");
for (ciEvent e = el.begin(); e != el.end(); ++e)
e->second.write(level, xml, -startTick);
xml.etag(--level, "eventlist");
//---------------------------------------------------
// read tmp file into drag Object
//---------------------------------------------------
fflush(tmp);
struct stat f_stat;
if (fstat(fileno(tmp), &f_stat) == -1)
{
fprintf(stderr, "PianorollCanvas::copy() fstat failes:<%s>\n",
strerror(errno));
fclose(tmp);
return 0;
}
int n = f_stat.st_size;
char* fbuf = (char*) mmap(0, n + 1, PROT_READ | PROT_WRITE,
MAP_PRIVATE, fileno(tmp), 0);
fbuf[n] = 0;
QByteArray data(fbuf);
QMimeData* md = new QMimeData();
//QDrag* drag = new QDrag(parent);
md->setData("text/x-los-eventlist", data);
//drag->setMimeData(md);
munmap(fbuf, n);
fclose(tmp);
//return drag;
return md;
}
void LOS::processTrack(MidiTrack* track)
{
EventList* tevents = track->events();
if (tevents->empty())
return;
//---------------------------------------------------
// Identify Parts
// The MIDI tracks are broken up into parts
// A new Part will be located based on track.
// Events will be aligned on new track
//---------------------------------------------------
PartList* pl = track->parts();
int lastTick = 0;
for (iEvent i = tevents->begin(); i != tevents->end(); ++i)
{
Event event = i->second;
int epos = event.tick() + event.lenTick();
if (epos > lastTick)
lastTick = epos;
}
QString partname = track->name();
int len = song->roundUpBar(lastTick + 1);
// p3.3.27
if (config.importMidiSplitParts)
{
int bar2, beat;
unsigned tick;
sigmap.tickValues(len, &bar2, &beat, &tick);
int lastOff = 0;
int st = -1; // start tick current part
int x1 = 0; // start tick current measure
int x2 = 0; // end tick current measure
for (int bar = 0; bar < bar2; ++bar, x1 = x2)
{
///x2 = sigmap.bar2tick(bar+1, 0, 0);
x2 = sigmap.bar2tick(bar + 1, 0, 0);
if (lastOff > x2)
{
// this measure is busy!
continue;
}
iEvent i1 = tevents->lower_bound(x1);
iEvent i2 = tevents->lower_bound(x2);
if (i1 == i2)
{ // empty?
if (st != -1)
{
MidiPart* part = new MidiPart(track);
part->setTick(st);
part->setLenTick(x1 - st);
// printf("new part %d len: %d\n", st, x1-st);
part->setName(partname);
pl->add(part);
st = -1;
}
}
else
{
if (st == -1)
st = x1; // begin new part
//HACK:
//lastOff:
for (iEvent i = i1; i != i2; ++i)
{
Event event = i->second;
if (event.type() == Note)
{
int off = event.tick() + event.lenTick();
if (off > lastOff)
lastOff = off;
}
}
}
}
if (st != -1)
{
MidiPart* part = new MidiPart(track);
part->setTick(st);
// printf("new part %d len: %d\n", st, x2-st);
part->setLenTick(x2 - st);
part->setName(partname);
pl->add(part);
}
}
else
{
// Just one long part...
MidiPart* part = new MidiPart(track);
//part->setTick(st);
part->setTick(0);
part->setLenTick(len);
part->setName(partname);
pl->add(part);
}
//-------------------------------------------------------------
// assign events to parts
//-------------------------------------------------------------
for (iPart p = pl->begin(); p != pl->end(); ++p)
{
MidiPart* part = (MidiPart*) (p->second);
int stick = part->tick();
int etick = part->tick() + part->lenTick();
iEvent r1 = tevents->lower_bound(stick);
iEvent r2 = tevents->lower_bound(etick);
int startTick = part->tick();
EventList* el = part->events();
for (iEvent i = r1; i != r2; ++i)
{
Event ev = i->second;
int ntick = ev.tick() - startTick;
ev.setTick(ntick);
el->add(ev);
}
tevents->erase(r1, r2);
}
if (tevents->size())
printf("-----------events left: %zd\n", tevents->size());
for (iEvent i = tevents->begin(); i != tevents->end(); ++i)
{
printf("%d===\n", i->first);
i->second.dump();
}
// all events should be processed:
assert(tevents->empty());
}
void EventCanvas::pasteAt(const QString& pt, int pos)
{
QByteArray ba = pt.toLatin1();
const char* p = ba.constData();
Xml xml(p);
for (;;)
{
Xml::Token token = xml.parse();
const QString& tag = xml.s1();
switch (token)
{
case Xml::Error:
case Xml::End:
return;
case Xml::TagStart:
if (tag == "eventlist")
{
song->startUndo();
EventList* el = new EventList();
el->read(xml, "eventlist");
int modified = SC_EVENT_INSERTED;
for (iEvent i = el->begin(); i != el->end(); ++i)
{
Event e = i->second;
int tick = e.tick() + pos - _curPart->tick();
if (tick < 0)
{
printf("ERROR: trying to add event before current part!\n");
song->endUndo(SC_EVENT_INSERTED);
delete el;
return;
}
e.setTick(tick);
int diff = e.endTick() - _curPart->lenTick();
if (diff > 0)
{// too short part? extend it
Part* newPart = _curPart->clone();
newPart->setLenTick(newPart->lenTick() + diff);
// Indicate no undo, and do port controller values but not clone parts.
audio->msgChangePart(_curPart, newPart, false, true, false);
modified = modified | SC_PART_MODIFIED;
_curPart = newPart; // reassign
}
// Indicate no undo, and do not do port controller values and clone parts.
audio->msgAddEvent(e, _curPart, false, false, false);
}
song->endUndo(modified);
delete el;
return;
}
else
xml.unknown("pasteAt");
break;
case Xml::Attribut:
case Xml::TagEnd:
default:
break;
}
}
}
bool LOS::importMidi(const QString name, bool merge)/*{{{*/
{
bool popenFlag;
FILE* fp = fileOpen(this, name, QString(".mid"), "r", popenFlag);
if (fp == 0)
return true;
MidiFile mf(fp);
bool rv = mf.read();
popenFlag ? pclose(fp) : fclose(fp);
if (rv)
{
QString s(tr("reading midifile\n "));
s += name;
s += tr("\nfailed: ");
s += mf.error();
QMessageBox::critical(this, QString("LOS"), s);
return rv;
}
//
// evaluate song Type (GM, XG, GS, unknown)
//
MType t = song->midiType();
if (!merge)
{
t = mf.mtype();
song->setMType(t);
}
MidiInstrument* instr = 0;
for (iMidiInstrument i = midiInstruments.begin(); i != midiInstruments.end(); ++i)
{
MidiInstrument* mi = *i;
if ((mi->iname() == "GM" && ((t == MT_UNKNOWN) || (t == MIDI_TYPE_GM)))
|| ((mi->iname() == "GS") && (t == MT_GS))
|| ((mi->iname() == "XG") && (t == MT_XG)))
{
instr = mi;
break;
}
}
if (instr == 0)
{
// the standard instrument files (GM, GS, XG) must be present
printf("no instrument, type %d\n", t);
return true;
//abort();
}
MidiFileTrackList* etl = mf.trackList();
int division = mf.division();
//
// create MidiTrack and copy events to ->events()
// - combine note on/off events
// - calculate tick value for internal resolution
//
for (iMidiFileTrack t = etl->begin(); t != etl->end(); ++t)
{
MPEventList* el = &((*t)->events);
if (el->empty())
continue;
//
// if we split the track, SYSEX and META events go into
// the first target track
bool first = true;
// somewhat silly and slooow:
for (int port = 0; port < kMaxMidiPorts; ++port)
{
for (int channel = 0; channel < kMaxMidiChannels; ++channel)
{
//
// check if there are any events for port/channel in track:
//
iMPEvent i;
for (i = el->begin(); i != el->end(); ++i)
{
MidiPlayEvent ev = *i;
if (ev.type() != ME_SYSEX && ev.type() != ME_META
&& ev.channel() == channel && ev.port() == port)
break;
}
if (i == el->end())
continue;
MidiTrack* track = new MidiTrack();
if ((*t)->isDrumTrack)
{
track->setType(Track::DRUM);
}
track->setOutChannel(channel);
track->setOutPort(port);
MidiPort* mport = &midiPorts[track->outPort()];
// this overwrites any instrument set for this port:
mport->setInstrument(instr);
EventList* mel = track->events();
//buildMidiEventList(mel, el, track, division, first);
// Don't do loops.
buildMidiEventList(mel, el, track, division, first, false);
first = false;
// Hmm. buildMidiEventList already takes care of this.
// But it seems to work. How? Must test.
if (channel == 9 && song->midiType() != MT_UNKNOWN)
{
track->setType(Track::DRUM);
//
// remap drum pitch with drumInmap
//
EventList* tevents = track->events();
for (iEvent i = tevents->begin(); i != tevents->end(); ++i)
{
Event ev = i->second;
if (ev.isNote())
{
int pitch = drumInmap[ev.pitch()];
ev.setPitch(pitch);
}
else
if (ev.type() == Controller)
{
int ctl = ev.dataA();
MidiController *mc = mport->drumController(ctl);
if (mc)
ev.setA((ctl & ~0xff) | drumInmap[ctl & 0x7f]);
}
}
}
processTrack(track);
song->insertTrack(track, -1);
}
}
if (first)
{
//
// track does only contain non-channel messages
// (SYSEX or META)
//
MidiTrack* track = new MidiTrack();
track->setOutChannel(0);
track->setOutPort(0);
EventList* mel = track->events();
//buildMidiEventList(mel, el, track, division, true);
// Do SysexMeta. Don't do loops.
buildMidiEventList(mel, el, track, division, true, false);
processTrack(track);
song->insertTrack(track, -1);
}
}
if (!merge)
{
TrackList* tl = song->tracks();
if (!tl->empty())
{
Track* track = tl->front();
track->setSelected(true);
}
song->initLen();
int z, n;
///sigmap.timesig(0, z, n);
sigmap.timesig(0, z, n);
int tempo = tempomap.tempo(0);
transport->setTimesig(z, n);
transport->setTempo(tempo);
bool masterF = !tempomap.empty();
song->setMasterFlag(masterF);
transport->setMasterFlag(masterF);
song->updatePos();
composer->reset();
///composer->setMode(int(song->midiType())); // p4.0.7 Tim
}
else
{
song->initLen();
}
return false;
}/*}}}*/
void CSystemEvents::ExecuteEvents()
{
EventList Events;
{
CGuard Guard(m_CS);
m_bDoSomething = false;
if (m_Events.size() == 0)
{
return;
}
Events = m_Events;
m_Events.clear();
}
bool bPause = false, bLoadedSave = false;
for (EventList::const_iterator iter = Events.begin(); !bLoadedSave && iter != Events.end(); iter++ )
{
switch (*iter)
{
case SysEvent_CloseCPU:
m_System->m_EndEmulation = true;
break;
case SysEvent_ResetCPU_Soft:
m_System->GameReset();
break;
case SysEvent_ResetCPU_SoftDone:
m_System->Reset(true,false);
break;
case SysEvent_ResetCPU_Hard:
m_System->Reset(true,true);
break;
case SysEvent_Profile_GenerateLogs:
m_System->m_Profile.GenerateLog();
break;
case SysEvent_Profile_StartStop:
case SysEvent_Profile_ResetLogs:
m_System->m_Profile.ResetCounters();
break;
case SysEvent_ExecuteInterrupt:
g_Reg->DoIntrException(false);
break;
case SysEvent_Interrupt_SP:
g_Reg->MI_INTR_REG |= MI_INTR_SP;
g_Reg->DoIntrException(false);
break;
case SysEvent_Interrupt_SI:
g_Reg->MI_INTR_REG |= MI_INTR_SI;
g_Reg->DoIntrException(false);
break;
case SysEvent_Interrupt_AI:
g_Reg->MI_INTR_REG |= MI_INTR_AI;
g_Reg->DoIntrException(false);
break;
case SysEvent_Interrupt_VI:
g_Reg->MI_INTR_REG |= MI_INTR_VI;
g_Reg->DoIntrException(false);
break;
case SysEvent_Interrupt_PI:
g_Reg->MI_INTR_REG |= MI_INTR_PI;
g_Reg->DoIntrException(false);
break;
case SysEvent_Interrupt_DP:
g_Reg->MI_INTR_REG |= MI_INTR_DP;
g_Reg->DoIntrException(false);
break;
case SysEvent_SaveMachineState:
if (!m_System->SaveState())
{
m_Events.push_back(SysEvent_SaveMachineState);
m_bDoSomething = true;
}
break;
case SysEvent_LoadMachineState:
if (m_System->LoadState())
{
bLoadedSave = true;
}
break;
case SysEvent_ChangePlugins:
ChangePluginFunc();
break;
case SysEvent_ChangingFullScreen:
Notify().ChangeFullScreen();
break;
case SysEvent_GSButtonPressed:
if (m_System->m_Cheats.CheatsSlectionChanged())
{
m_System->m_Cheats.LoadCheats(false, m_Plugins);
}
m_System->m_Cheats.ApplyGSButton(g_MMU);
break;
case SysEvent_PauseCPU_FromMenu:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_FromMenu);
bPause = true;
}
break;
case SysEvent_PauseCPU_AppLostFocus:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_AppLostFocus);
bPause = true;
}
break;
case SysEvent_PauseCPU_AppLostActive:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_AppLostActive);
bPause = true;
}
break;
case SysEvent_PauseCPU_SaveGame:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_SaveGame);
bPause = true;
}
break;
case SysEvent_PauseCPU_LoadGame:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_LoadGame);
bPause = true;
}
break;
case SysEvent_PauseCPU_DumpMemory:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_DumpMemory);
bPause = true;
}
break;
case SysEvent_PauseCPU_SearchMemory:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_SearchMemory);
bPause = true;
}
break;
case SysEvent_PauseCPU_Settings:
if (!g_Settings->LoadBool(GameRunning_CPU_Paused))
{
g_Settings->SaveBool(GameRunning_CPU_Paused,true);
g_Settings->SaveDword(GameRunning_CPU_PausedType, PauseType_Settings);
bPause = true;
}
break;
default:
g_Notify->BreakPoint(__FILEW__,__LINE__);
break;
}
}
if (bPause)
{
m_System->Pause();
}
}
void ListEdit::songChanged(int type)
{
if (type == 0)
return;
if (type & (SC_PART_REMOVED | SC_PART_MODIFIED
| SC_PART_INSERTED | SC_EVENT_REMOVED | SC_EVENT_MODIFIED
| SC_EVENT_INSERTED | SC_SELECTION))
{
if (type & (SC_PART_REMOVED | SC_PART_INSERTED))
genPartlist();
// close window if editor has no parts anymore
if (parts()->empty())
{
close();
return;
}
liste->setSortingEnabled(false);
if (type == SC_SELECTION)
{
bool update = false;
QTreeWidgetItem* ci = 0;
liste->blockSignals(true);
for (int row = 0; row < liste->topLevelItemCount(); ++row)
{
QTreeWidgetItem* i = liste->topLevelItem(row);
if (i->isSelected() ^ ((EventListItem*) i)->event.selected())
{
i->setSelected(((EventListItem*) i)->event.selected());
if (i->isSelected())
ci = i;
update = true;
}
}
if (update)
{
if (ci)
{
liste->setCurrentItem(ci);
liste->scrollToItem(ci, QAbstractItemView::EnsureVisible);
}
//liste->update();
}
liste->blockSignals(false);
}
else
{
curPart = 0;
curTrack = 0;
liste->clear();
for (iPart p = parts()->begin(); p != parts()->end(); ++p)
{
MidiPart* part = (MidiPart*) (p->second);
if (part->sn() == curPartId)
curPart = part;
EventList* el = part->events();
for (iEvent i = el->begin(); i != el->end(); ++i)
{
EventListItem* item = new EventListItem(liste, i->second, part);
for (int col = 0; col < liste->columnCount(); ++col)
item->setText(col, item->text(col));
item->setSelected(i->second.selected());
if (item->event.tick() == (unsigned) selectedTick)
{ //prevent compiler warning: comparison of signed/unsigned)
liste->setCurrentItem(item);
item->setSelected(true);
liste->scrollToItem(item, QAbstractItemView::EnsureVisible);
}
}
}
}
// p3.3.34
//if (curPart == 0)
// curPart = (MidiPart*)(parts()->begin()->second);
//curTrack = curPart->track();
if (!curPart)
{
if (!parts()->empty())
{
curPart = (MidiPart*) (parts()->begin()->second);
if (curPart)
curTrack = curPart->track();
else
curPart = 0;
}
}
}
liste->setSortingEnabled(true);
}
