KstDataObjectPtr KstCPlugin::makeDuplicate(KstDataObjectDataObjectMap& duplicatedMap) {
KstCPluginPtr plugin = new KstCPlugin;
// use same inputs
for (KstVectorMap::ConstIterator iter = _inputVectors.begin(); iter != _inputVectors.end(); ++iter) {
plugin->inputVectors().insert(iter.key(), iter.data());
}
for (KstScalarMap::ConstIterator iter = _inputScalars.begin(); iter != _inputScalars.end(); ++iter) {
plugin->inputScalars().insert(iter.key(), iter.data());
}
for (KstStringMap::ConstIterator iter = _inputStrings.begin(); iter != _inputStrings.end(); ++iter) {
plugin->inputStrings().insert(iter.key(), iter.data());
}
// create new outputs
for (KstVectorMap::ConstIterator iter = outputVectors().begin(); iter != outputVectors().end(); ++iter) {
KstWriteLocker blockVectorUpdates(&KST::vectorList.lock());
KstVectorPtr v = new KstVector(KstObjectTag(iter.data()->tag().tag() + "'", iter.data()->tag().context()), 0, plugin.data()); // FIXME: unique tag generation
plugin->outputVectors().insert(iter.key(), v);
}
for (KstScalarMap::ConstIterator iter = outputScalars().begin(); iter != outputScalars().end(); ++iter) {
KstScalarPtr s = new KstScalar(KstObjectTag(iter.data()->tag().tag() + "'", iter.data()->tag().context()), plugin.data()); // FIXME: unique tag generation
plugin->outputScalars().insert(iter.key(), s);
}
for (KstStringMap::ConstIterator iter = outputStrings().begin(); iter != outputStrings().end(); ++iter) {
KstStringPtr s = new KstString(KstObjectTag(iter.data()->tag().tag() + "'", iter.data()->tag().context()), plugin.data()); // FIXME: unique tag generation
plugin->outputStrings().insert(iter.key(), s);
}
// set the same plugin
plugin->setPlugin(_plugin);
plugin->setTagName(KstObjectTag(tag().tag() + "'", tag().context())); // FIXME: unique tag generation method
duplicatedMap.insert(this, KstDataObjectPtr(plugin));
return KstDataObjectPtr(plugin);
}
bool KstEquation::uses(KstObjectPtr p) const {
// check VectorsUsed in addition to _input*'s
if (KstVectorPtr vect = kst_cast<KstVector>(p)) {
for (KstVectorMap::ConstIterator j = VectorsUsed.begin(); j != VectorsUsed.end(); ++j) {
if (j.data() == vect) {
return true;
}
}
} else if (KstDataObjectPtr obj = kst_cast<KstDataObject>(p) ) {
// check all connections from this expression to p
for (KstVectorMap::Iterator j = obj->outputVectors().begin(); j != obj->outputVectors().end(); ++j) {
for (KstVectorMap::ConstIterator k = VectorsUsed.begin(); k != VectorsUsed.end(); ++k) {
if (j.data() == k.data()) {
return true;
}
}
}
}
return KstDataObject::uses(p);
}
KstDataObjectPtr KstPlugin::makeDuplicate(KstDataObjectDataObjectMap& duplicatedMap) {
KstPluginPtr plugin = new KstPlugin;
// use same inputs
for (KstVectorMap::ConstIterator iter = _inputVectors.begin(); iter != _inputVectors.end(); ++iter) {
plugin->inputVectors().insert(iter.key(), iter.data());
}
for (KstScalarMap::ConstIterator iter = _inputScalars.begin(); iter != _inputScalars.end(); ++iter) {
plugin->inputScalars().insert(iter.key(), iter.data());
}
for (KstStringMap::ConstIterator iter = _inputStrings.begin(); iter != _inputStrings.end(); ++iter) {
plugin->inputStrings().insert(iter.key(), iter.data());
}
// create new outputs
for (KstVectorMap::ConstIterator iter = outputVectors().begin(); iter != outputVectors().end(); ++iter) {
KstVectorPtr v = new KstVector(iter.data()->tagName() + "'", 0, plugin.data());
plugin->outputVectors().insert(iter.key(), v);
KST::addVectorToList(v);
}
for (KstScalarMap::ConstIterator iter = outputScalars().begin(); iter != outputScalars().end(); ++iter) {
KstScalarPtr s = new KstScalar(iter.data()->tagName() + "'", plugin.data());
plugin->outputScalars().insert(iter.key(), s);
}
for (KstStringMap::ConstIterator iter = outputStrings().begin(); iter != outputStrings().end(); ++iter) {
KstStringPtr s = new KstString(iter.data()->tagName() + "'", plugin.data());
plugin->outputStrings().insert(iter.key(), s);
}
// set the same plugin
plugin->setPlugin(_plugin);
plugin->setTagName(tagName() + "'");
duplicatedMap.insert(this, KstDataObjectPtr(plugin));
return KstDataObjectPtr(plugin);
}
void EventMonitorEntry::replaceDependency(KstDataObjectPtr oldObject, KstDataObjectPtr newObject) {
QString newExp = _event;
// replace all occurences of outputVectors, outputScalars from oldObject
for (KstVectorMap::ConstIterator j = oldObject->outputVectors().begin(); j != oldObject->outputVectors().end(); ++j) {
const QString oldTag = j.value()->tagName();
const QString newTag = newObject->outputVectors()[j.key()]->tagName();
newExp = newExp.replace("[" + oldTag + "]", "[" + newTag + "]");
}
for (KstScalarMap::ConstIterator j = oldObject->outputScalars().begin(); j != oldObject->outputScalars().end(); ++j) {
const QString oldTag = j.value()->tagName();
const QString newTag = newObject->outputScalars()[j.key()]->tagName();
newExp = newExp.replace("[" + oldTag + "]", "[" + newTag + "]");
}
// and dependencies on vector stats
for (KstVectorMap::ConstIterator j = oldObject->outputVectors().begin(); j != oldObject->outputVectors().end(); ++j) {
const QHash<QString, KstScalar*>& scalarMap(newObject->outputVectors()[j.key()]->scalars());
QHashIterator<QString, KstScalar*> scalarDictIter(j.value()->scalars());
while (scalarDictIter.hasNext()) {
const QString oldTag = scalarDictIter.next().value()->tagName();
const QString newTag = scalarMap[scalarDictIter.key()]->tagName();
newExp = newExp.replace("[" + oldTag + "]", "[" + newTag + "]");
}
}
// and dependencies on matrix stats
for (KstMatrixMap::ConstIterator j = oldObject->outputMatrices().begin(); j != oldObject->outputMatrices().end(); ++j) {
const QHash<QString, KstScalar*>& scalarMap(newObject->outputMatrices()[j.key()]->scalars());
QHashIterator<QString, KstScalar*> scalarDictIter(j.value()->scalars());
while (scalarDictIter.hasNext()) {
const QString oldTag = scalarDictIter.next().value()->tagName();
const QString newTag = scalarMap[scalarDictIter.key()]->tagName();
newExp = newExp.replace("[" + oldTag + "]", "[" + newTag + "]");
}
}
setEvent(newExp);
setDirty();
// events have no _inputVectors
}
bool KstEquation::FillY(bool force) {
int v_shift=0, v_new;
int i0=0;
int ns;
writeLockInputsAndOutputs();
// determine value of Interp
if (_doInterp) {
ns = (*_xInVector)->length();
for (KstVectorMap::ConstIterator i = VectorsUsed.begin(); i != VectorsUsed.end(); ++i) {
if (i.data()->length() > ns) {
ns = i.data()->length();
}
}
} else {
ns = (*_xInVector)->length();
}
if (_ns != (*_xInVector)->length() || ns != (*_xInVector)->length() ||
(*_xInVector)->numShift() != (*_xInVector)->numNew()) {
_ns = ns;
KstVectorPtr xv = *_xOutVector;
KstVectorPtr yv = *_yOutVector;
if (!xv->resize(_ns)) {
// FIXME: handle error?
unlockInputsAndOutputs();
return false;
}
if (!yv->resize(_ns)) {
// FIXME: handle error?
unlockInputsAndOutputs();
return false;
}
yv->zero();
i0 = 0; // other vectors may have diffent lengths, so start over
v_shift = _ns;
} else {
// calculate shift and new samples
// only do shift optimization if all used vectors are same size and shift
v_shift = (*_xInVector)->numShift();
v_new = (*_xInVector)->numNew();
for (KstVectorMap::ConstIterator i = VectorsUsed.begin(); i != VectorsUsed.end(); ++i) {
if (v_shift != i.data()->numShift()) {
v_shift = _ns;
}
if (v_new != i.data()->numNew()) {
v_shift = _ns;
}
if (_ns != i.data()->length()) {
v_shift = _ns;
}
}
if (v_shift > _ns/2 || force) {
i0 = 0;
v_shift = _ns;
} else {
KstVectorPtr xv = *_xOutVector;
KstVectorPtr yv = *_yOutVector;
for (int i = v_shift; i < _ns; i++) {
yv->value()[i - v_shift] = yv->value()[i];
xv->value()[i - v_shift] = xv->value()[i];
}
i0 = _ns - v_shift;
}
}
_numShifted = (*_yOutVector)->numShift() + v_shift;
if (_numShifted > _ns) {
_numShifted = _ns;
}
_numNew = _ns - i0 + (*_yOutVector)->numNew();
if (_numNew > _ns) {
_numNew = _ns;
}
(*_xOutVector)->setNewAndShift(_numNew, _numShifted);
(*_yOutVector)->setNewAndShift(_numNew, _numShifted);
double *rawxv = (*_xOutVector)->value();
double *rawyv = (*_yOutVector)->value();
KstVectorPtr iv = (*_xInVector);
Equation::Context ctx;
ctx.sampleCount = _ns;
ctx.xVector = iv;
if (!_pe) {
if (_equation.isEmpty()) {
unlockInputsAndOutputs();
return true;
}
QMutexLocker ml(&Equation::mutex());
yy_scan_string(_equation.latin1());
int rc = yyparse();
_pe = static_cast<Equation::Node*>(ParsedEquation);
if (_pe && rc == 0) {
Equation::FoldVisitor vis(&ctx, &_pe);
KstStringMap sm;
_pe->collectObjects(VectorsUsed, ScalarsUsed, sm);
ParsedEquation = 0L;
} else {
delete (Equation::Node*)ParsedEquation;
ParsedEquation = 0L;
_pe = 0L;
unlockInputsAndOutputs();
return false;
}
}
for (ctx.i = i0; ctx.i < _ns; ++ctx.i) {
rawxv[ctx.i] = iv->value(ctx.i);
ctx.x = iv->interpolate(ctx.i, _ns);
rawyv[ctx.i] = _pe->value(&ctx);
}
if (!(*_xOutVector)->resize(iv->length())) {
// FIXME: handle error?
unlockInputsAndOutputs();
return false;
}
unlockInputsAndOutputs();
return true;
}
KstObject::UpdateType EventMonitorEntry::update(int updateCounter) {
Q_ASSERT(myLockStatus() == KstRWLock::WRITELOCKED);
bool force = dirty();
setDirty(false);
if (KstObject::checkUpdateCounter(updateCounter) && !force) {
return lastUpdateResult();
}
writeLockInputsAndOutputs();
if (!_pExpression) {
reparse();
}
KstVectorPtr xv = *_xVector;
KstVectorPtr yv = *_yVector;
int ns = 1;
for (KstVectorMap::ConstIterator i = _vectorsUsed.begin(); i != _vectorsUsed.end(); ++i) {
ns = qMax(ns, i.value()->length());
}
double *rawValuesX = 0L;
double *rawValuesY = 0L;
if (xv && yv) {
if (xv->resize(ns)) {
rawValuesX = xv->value();
}
if (yv->resize(ns)) {
rawValuesY = yv->value();
}
}
Equation::Context ctx;
ctx.sampleCount = ns;
ctx.x = 0.0;
if (needToEvaluate()) {
if (_pExpression) {
for (ctx.i = _numDone; ctx.i < ns; ++ctx.i) {
const double value = _pExpression->value(&ctx);
if (value != 0.0) { // The expression evaluates to true
log(ctx.i);
if (rawValuesX && rawValuesY) {
rawValuesX[ctx.i] = ctx.i;
rawValuesY[ctx.i] = 1.0;
}
} else {
if (rawValuesX && rawValuesY) {
rawValuesX[ctx.i] = ctx.i;
rawValuesY[ctx.i] = 0.0;
}
}
}
_numDone = ns;
logImmediately();
}
} else {
_numDone = ns;
}
if (xv) {
xv->setDirty();
xv->update(updateCounter);
}
if (yv) {
yv->setDirty();
yv->update(updateCounter);
}
unlockInputsAndOutputs();
return setLastUpdateResult(NO_CHANGE);
}
