TFx *TExternalProgramFx::clone(bool recursive) const {
TExternalProgramFx *fx =
dynamic_cast<TExternalProgramFx *>(TExternFx::create(m_externFxName));
assert(fx);
// new TExternalProgramFx();
// fx->setExecutable(m_executablePath, m_args);
// copia della time region
fx->setActiveTimeRegion(getActiveTimeRegion());
// fx->m_imp->m_activeTimeRegion = m_imp->m_activeTimeRegion;
fx->getParams()->copy(getParams());
assert(getInputPortCount() == fx->getInputPortCount());
// std::map<std::string, Port>::const_iterator j;
// for(j=m_ports.begin(); j!=m_ports.end(); ++j)
// fx->addPort(j->first, j->second.m_ext, j->second.m_port != 0);
// copia ricorsiva sulle porte
if (recursive) {
for (int i = 0; i < getInputPortCount(); ++i) {
TFxPort *port = getInputPort(i);
if (port->getFx())
fx->connect(getInputPortName(i), port->getFx()->clone(true));
}
}
// std::map<std::string, TParamP>::const_iterator j;
// for(j=m_params.begin(); j!=m_params.end(); ++j)
// fx->addParam(j->first, j->second->clone());
return fx;
}
//!Build the scene fx for each node below the xsheet one.
//!Remember that left xsheet ports must not be expanded.
void MultimediaRenderer::Imp::scanSceneForLayers()
{
//Retrieve the terminal fxs (ie, fxs which are implicitly
//connected to the xsheet one)
TXsheet *xsh = m_scene->getXsheet();
TFxSet *fxs = xsh->getFxDag()->getTerminalFxs();
//Examine all of them and - eventually - expand left xsheet
//ports (ie fx nodes who allow implicit overlaying)
for (int i = 0; i < fxs->getFxCount(); ++i) {
TFx *fx = fxs->getFx(i);
TFxPort *leftXSheetPort;
retry:
if (!fx)
continue;
leftXSheetPort = fx->getXsheetPort();
if (!leftXSheetPort) {
m_fxsToRender.addFx(fx);
continue;
}
//If the leftXSheetPort is not connected, retry on port 0
if (leftXSheetPort->isConnected())
m_fxsToRender.addFx(fx);
else {
fx = fx->getInputPort(0)->getFx();
goto retry;
}
}
}
std::string Iwa_TiledParticlesFx::getAlias(double frame, const TRenderSettings &info) const
{
std::string alias = getFxType();
alias += "[";
// alias degli effetti connessi alle porte di input separati da virgole
// una porta non connessa da luogo a un alias vuoto (stringa vuota)
for (int i = 0; i < getInputPortCount(); ++i) {
TFxPort *port = getInputPort(i);
if (port->isConnected()) {
TRasterFxP ifx = port->getFx();
assert(ifx);
alias += ifx->getAlias(frame, info);
}
alias += ",";
}
std::string paramalias("");
for (int i = 0; i < getParams()->getParamCount(); ++i) {
TParam *param = getParams()->getParam(i);
paramalias += param->getName() + "=" + param->getValueAlias(frame, 3);
}
return alias + toString(frame) + "," + toString(getIdentifier()) + paramalias + "]";
}
std::string TGeometryFx::getAlias(double frame,
const TRenderSettings &info) const {
TGeometryFx *tthis = const_cast<TGeometryFx *>(this);
TAffine affine = tthis->getPlacement(frame);
std::string alias = getFxType();
alias += "[";
// alias degli effetti connessi alle porte di input separati da virgole
// una porta non connessa da luogo a un alias vuoto (stringa vuota)
for (int i = 0; i < getInputPortCount(); ++i) {
TFxPort *port = getInputPort(i);
if (port->isConnected()) {
TRasterFxP ifx = port->getFx();
assert(ifx);
alias += ifx->getAlias(frame, info);
}
alias += ",";
}
return alias +
(areAlmostEqual(affine.a11, 0) ? "0" : ::to_string(affine.a11, 5)) +
"," +
(areAlmostEqual(affine.a12, 0) ? "0" : ::to_string(affine.a12, 5)) +
"," +
(areAlmostEqual(affine.a13, 0) ? "0" : ::to_string(affine.a13, 5)) +
"," +
(areAlmostEqual(affine.a21, 0) ? "0" : ::to_string(affine.a21, 5)) +
"," +
(areAlmostEqual(affine.a22, 0) ? "0" : ::to_string(affine.a22, 5)) +
"," +
(areAlmostEqual(affine.a23, 0) ? "0" : ::to_string(affine.a23, 5)) +
"]";
}
string TMacroFx::getAlias(double frame, const TRenderSettings &info) const
{
string alias = getFxType();
alias += "[";
// alias degli effetti connessi alle porte di input separati da virgole
// una porta non connessa da luogo a un alias vuoto (stringa vuota)
int i;
for (i = 0; i < getInputPortCount(); i++) {
TFxPort *port = getInputPort(i);
if (port->isConnected()) {
TRasterFxP ifx = port->getFx();
assert(ifx);
alias += ifx->getAlias(frame, info);
}
alias += ",";
}
// alias dei valori dei parametri dell'effetto al frame dato
for (int j = 0; j < (int)m_fxs.size(); j++) {
alias += (j == 0) ? "(" : ",(";
for (i = 0; i < m_fxs[j]->getParams()->getParamCount(); i++) {
if (i > 0)
alias += ",";
TParam *param = m_fxs[j]->getParams()->getParam(i);
alias += param->getName() + "=" + param->getValueAlias(frame, 2);
}
alias += ")";
}
alias += "]";
return alias;
}
std::vector<const TFx *> calculateSortedFxs(TRasterFxP rootFx) {
std::map<const TFx *, std::set<const TFx *>> E; /* 辺の情報 */
std::set<const TFx *> Sources; /* 入次数0のノード群 */
std::queue<const TFx *> Q;
Q.push(rootFx.getPointer());
E[rootFx.getPointer()] = std::set<const TFx *>();
while (!Q.empty()) {
const TFx *vptr = Q.front();
Q.pop();
if (!vptr) {
continue;
}
/* 繋がっている入力ポートの先の Fx を訪問する
入力ポートが無ければ終了 */
int portCount = vptr->getInputPortCount();
if (portCount < 1) {
Sources.insert(vptr);
continue;
}
for (int i = 0; i < portCount; i++) {
TFxPort *port = vptr->getInputPort(i);
if (!port) {
continue;
}
TFxP u = port->getFx();
const TFx *uptr = u.getPointer();
if (E.count(uptr) == 0) {
E[uptr] = std::set<const TFx *>();
}
if (E[uptr].count(vptr) == 0) {
E[uptr].insert(vptr);
}
Q.push(uptr);
}
}
/* トポロジカルソート */
std::set<const TFx *> visited;
std::vector<const TFx *> L;
std::function<void(const TFx *)> visit = [&visit, &visited, &E,
&L](const TFx *fx) {
if (visited.count(fx)) return;
visited.insert(fx);
auto edge = E[fx];
for (auto i = edge.cbegin(); i != edge.cend(); i++) {
visit(*i);
}
L.insert(L.begin(), fx);
};
for (auto i = E.cbegin(); i != E.cend(); i++) {
visit(i->first);
}
return L;
}
void SwatchCacheManager::setFx(const TFxP &fx)
{
QMutexLocker locker(&m_mutex);
//Update the fxs id data
if (fx == TFxP()) {
//Clear if no fx is set
m_setFxId = 0;
m_childrenFxIds.clear();
} else {
m_setFxId = fx->getIdentifier();
m_childrenFxIds.clear();
assert(m_setFxId != 0);
TRasterFx *rfx = dynamic_cast<TRasterFx *>(fx.getPointer());
assert(rfx);
for (int i = 0; i < fx->getInputPortCount(); ++i) {
//Fxs not allowing cache on the input port are skipped
if (!rfx->allowUserCacheOnPort(i))
continue;
TFxPort *iport = fx->getInputPort(i);
if (iport && iport->isConnected()) {
TFx *child = iport->getFx();
//In the zerary case, extract the actual fx
TZeraryColumnFx *zcfx = dynamic_cast<TZeraryColumnFx *>(child);
if (zcfx)
child = zcfx->getZeraryFx();
assert(child && child->getIdentifier() != 0);
m_childrenFxIds.insert(child->getIdentifier());
}
}
}
//NOTE: Check if this should be avoided in some case...
//Release the locks and clear the resources
if (m_currEditedFxResult)
m_currEditedFxResult->releaseLock();
m_currEditedFxResult = TCacheResourceP();
std::set<TCacheResourceP>::iterator it;
for (it = m_swatchCacheContainer.begin(); it != m_swatchCacheContainer.end(); ++it)
(*it)->releaseLock();
m_swatchCacheContainer.clear();
#ifdef USE_SQLITE_HDPOOL
TCacheResourcePool::instance()->releaseReferences("S");
#else
for (it = m_genericCacheContainer.begin(); it != m_genericCacheContainer.end(); ++it)
(*it)->releaseLock();
m_genericCacheContainer.clear();
#endif
}
TFx *TMacroFx::clone(bool recursive) const
{
int n = m_fxs.size();
vector<TFxP> clones(n);
std::map<TFx *, int> table;
std::map<TFx *, int>::iterator it;
int i, rootIndex = -1;
// nodi
for (i = 0; i < n; ++i) {
TFx *fx = m_fxs[i].getPointer();
assert(fx);
clones[i] = fx->clone(false);
assert(table.count(fx) == 0);
table[fx] = i;
if (fx == m_root.getPointer())
rootIndex = i;
TFx *linkedFx = fx->getLinkedFx();
if (linkedFx && table.find(linkedFx) != table.end())
clones[i]->linkParams(clones[table[linkedFx]].getPointer());
}
assert(rootIndex >= 0);
// connessioni
for (i = 0; i < n; i++) {
TFx *fx = m_fxs[i].getPointer();
for (int j = 0; j < fx->getInputPortCount(); j++) {
TFxPort *port = fx->getInputPort(j);
TFx *inputFx = port->getFx();
if (!inputFx)
continue;
it = table.find(inputFx);
if (it == table.end()) {
// il j-esimo input di fx e' esterno alla macro
if (recursive)
clones[i]->connect(fx->getInputPortName(j), inputFx->clone(true));
} else {
// il j-esimo input di fx e' interno alla macro
clones[i]->connect(fx->getInputPortName(j), clones[it->second].getPointer());
}
}
}
//TFx *rootClone =
// const_cast<TMacroFx*>(this)->
// clone(m_root.getPointer(), recursive, visited, clones);
TMacroFx *clone = TMacroFx::create(clones);
clone->setName(getName());
clone->setFxId(getFxId());
//Copy the index of the passive cache manager.
clone->getAttributes()->passiveCacheDataIdx() = getAttributes()->passiveCacheDataIdx();
assert(clone->getRoot() == clones[rootIndex].getPointer());
return clone;
}
void TRasterFx::compute(TFlash &flash, int frame) {
for (int i = getInputPortCount() - 1; i >= 0; i--) {
TFxPort *port = getInputPort(i);
if (port->isConnected() && !port->isaControlPort()) {
flash.pushMatrix();
((TRasterFxP)(port->getFx()))->compute(flash, frame);
flash.popMatrix();
}
}
}
void MultimediaRenderer::Imp::addPostProcessingRecursive(TFxP fx, TFxP postProc)
{
if (!postProc)
return;
int i, count = postProc->getInputPortCount();
for (i = 0; i < count; ++i) {
TFxPort *port = postProc->getInputPort(i);
TFx *childFx = port->getFx();
if (dynamic_cast<TXsheetFx *>(childFx))
port->setFx(fx.getPointer());
else
addPostProcessingRecursive(fx, childFx);
}
}
void Iwa_TiledParticlesFx::doDryCompute(TRectD &rect, double frame, const TRenderSettings &info)
{
Iwa_ParticlesManager *pc = Iwa_ParticlesManager::instance();
unsigned long fxId = getIdentifier();
int inputPortCount = getInputPortCount();
int i,
j,
curr_frame = frame, /*- 現在のフレーム -*/
startframe = startpos_val->getValue(); /*- Particesの開始フレーム -*/
TRenderSettings infoOnInput(info);
infoOnInput.m_affine = TAffine(); // Using the standard reference - indep. from cameras.
infoOnInput.m_bpp = 64; // Control ports rendered at 32 bit - since not visible.
for (i = startframe - 1; i <= curr_frame; ++i) {
double frame = tmax(0, i);
for (j = 0; j < inputPortCount; ++j) {
TFxPort *port = getInputPort(j);
std::string tmpName = getInputPortName(j);
if (port->isConnected()) {
TRasterFxP fx = port->getFx();
// Now, consider that source ports work different than control ones
QString portName = QString::fromStdString(tmpName);
if (portName.startsWith("C")) {
// Control ports are calculated from start to current frame, since
// particle mechanics at current frame is influenced by previous ones
// (and therefore by all previous control images).
TRectD bbox;
fx->getBBox(frame, bbox, infoOnInput);
if (bbox == TConsts::infiniteRectD)
bbox = info.m_affine.inv() * rect;
fx->dryCompute(bbox, frame, infoOnInput);
} else if (portName.startsWith("T")) {
// Particles handle source ports caching procedures on its own.
}
}
}
}
}
DeleteFxsUndo(const QList<TFx *> &fxs) {
TApp *app = TApp::instance();
FxDag *fxDag = app->getCurrentXsheet()->getXsheet()->getFxDag();
for (int i = 0; i < (int)fxs.size(); i++) {
TFx *fx = fxs[i];
TZeraryColumnFx *zfx = dynamic_cast<TZeraryColumnFx *>(fx);
if (zfx) fx = zfx->getZeraryFx();
Node node;
node.m_fx = fx;
node.m_xsheetConnected = fxDag->getTerminalFxs()->containsFx(fx);
int j;
for (j = 0; j < fx->getInputPortCount(); j++) {
TFxP inputFx(fx->getInputPort(j)->getFx());
int i;
if (inputFx &&
!fxDag->getTerminalFxs()->containsFx(inputFx.getPointer())) {
for (i = 0; i < (int)m_inputConnectedToXsheet.size(); i++)
if (m_inputConnectedToXsheet[i].getPointer() ==
inputFx.getPointer())
break;
if (i == (int)m_inputConnectedToXsheet.size())
m_inputConnectedToXsheet.push_back(inputFx);
}
node.m_inputLinks.push_back(inputFx);
}
for (j = 0; j < fx->getOutputConnectionCount(); j++) {
TFxPort *port = fx->getOutputConnection(j);
TFx *outFx = port->getOwnerFx();
if (outFx) {
int k;
for (k = 0; k < outFx->getInputPortCount(); k++)
if (outFx->getInputPort(k)->getFx() == fx) break;
if (k < outFx->getInputPortCount())
node.m_outputLinks.push_back(std::make_pair(k, TFxP(outFx)));
}
}
m_fxs.push_back(node);
}
}
bool TMacroFx::isaLeaf(TFx *fx) const
{
int count = fx->getInputPortCount();
if (count == 0)
return true;
for (int i = 0; i < count; ++i) {
TFxPort *port = fx->getInputPort(i);
TFx *inputFx = port->getFx();
if (inputFx) {
if (std::find_if(m_fxs.begin(), m_fxs.end(), MatchesFx(inputFx)) == m_fxs.end()) {
// il nodo di input non appartiene al macroFx
return true;
}
} else {
// la porta di input non e' connessa
return true;
}
}
// tutte le porte di input sono connesse verso nodi appartenenti al macroFx
return false;
}
Link FxSelection::getBoundingFxs(SchematicPort *inputPort,
SchematicPort *outputPort) {
Link boundingFxs;
FxSchematicNode *inputNode =
dynamic_cast<FxSchematicNode *>(outputPort->getNode());
FxSchematicNode *outputNode =
dynamic_cast<FxSchematicNode *>(inputPort->getNode());
FxGroupNode *groupNode = dynamic_cast<FxGroupNode *>(inputNode);
if (!inputNode || !outputNode ||
(groupNode && groupNode->getOutputConnectionsCount() != 1))
return boundingFxs;
if (dynamic_cast<TXsheetFx *>(outputNode->getFx())) {
if (!groupNode)
boundingFxs.m_inputFx = inputNode->getFx();
else {
TFxSet *terminals =
m_xshHandle->getXsheet()->getFxDag()->getTerminalFxs();
QList<TFxP> roots = groupNode->getRootFxs();
int i;
for (i = 0; i < roots.size(); i++)
if (terminals->containsFx(roots[i].getPointer())) {
boundingFxs.m_inputFx = roots[i];
break;
}
}
boundingFxs.m_outputFx = outputNode->getFx();
return boundingFxs;
}
if (outputNode->isA(eGroupedFx)) {
// devo prima trovare l'effetto interno al gruppo al quale inputNode e'
// linkato.
FxGroupNode *groupNode = dynamic_cast<FxGroupNode *>(outputNode);
assert(groupNode);
QList<TFx *> fxs;
TFx *inputFx = inputNode->getFx();
int i;
for (i = 0; i < inputFx->getOutputConnectionCount(); i++) {
TFx *outputFx = inputFx->getOutputConnection(i)->getOwnerFx();
if (!outputFx) continue;
if (groupNode->contains(outputFx)) fxs.push_back(outputFx);
}
if (fxs.size() != 1) // un nodo esterno al gruppo puo' essere linkato a
// piu' nodi interni al gruppo
return boundingFxs;
TFx *outputFx = fxs[0];
// ho tovato l'effetto, ora devo trovare l'indice della porta a cui e'
// linkato l'effetto in input
for (i = 0; i < outputFx->getInputPortCount(); i++) {
TFxPort *inputPort = outputFx->getInputPort(i);
TFx *fx = inputPort->getFx();
if (fx == inputFx) break;
}
if (i >= outputFx->getInputPortCount()) return boundingFxs;
boundingFxs.m_inputFx = inputFx;
boundingFxs.m_outputFx = outputFx;
boundingFxs.m_index = i;
return boundingFxs;
} else {
bool found = false;
int i, index = -1;
for (i = 0; i < outputNode->getInputPortCount() && !found; i++) {
FxSchematicPort *inputAppPort = outputNode->getInputPort(i);
int j;
for (j = 0; j < inputAppPort->getLinkCount(); j++) {
FxSchematicNode *outputAppNode =
dynamic_cast<FxSchematicNode *>(inputAppPort->getLinkedNode(j));
if (!outputAppNode) continue;
FxSchematicPort *outputAppPort = outputAppNode->getOutputPort();
if (inputAppPort == inputPort && outputPort == outputAppPort) {
found = true;
index = i;
break;
}
}
}
if (index == -1) return boundingFxs;
TFx *inputFx = inputNode->getFx();
TFx *outputFx = outputNode->getFx();
boundingFxs.m_inputFx = inputFx;
boundingFxs.m_outputFx = outputFx;
boundingFxs.m_index = index;
return boundingFxs;
}
}
bool TMacroFx::analyze(const vector<TFxP> &fxs,
TFxP &root,
vector<TFxP> &roots,
vector<TFxP> &leafs)
{
if (fxs.size() == 1)
return false;
else {
leafs.clear();
roots.clear();
std::vector<TFxP>::const_iterator it = fxs.begin();
for (; it != fxs.end(); ++it) {
TFxP fx = *it;
int inputInternalConnection = 0;
int inputExternalConnection = 0;
int outputInternalConnection = 0;
int outputExternalConnection = 0;
int i;
// calcola se ci sono connessioni in input dall'esterno
// verso l'interno e/o internamente a orderedFxs
int inputPortCount = fx->getInputPortCount();
for (i = 0; i < inputPortCount; ++i) {
TFxPort *inputPort = fx->getInputPort(i);
TFx *inputPortFx = inputPort->getFx();
if (inputPortFx) {
if (std::find_if(fxs.begin(), fxs.end(), MatchesFx(inputPortFx)) != fxs.end())
++inputInternalConnection;
else
++inputExternalConnection;
}
}
// calcola se ci sono connessioni in output dall'interno
// verso l'esterno e/o internamente a orderedFxs
int outputPortCount = fx->getOutputConnectionCount();
for (i = 0; i < outputPortCount; ++i) {
TFxPort *outputPort = fx->getOutputConnection(i);
TFx *outputFx = outputPort->getOwnerFx();
if (outputFx) {
if (std::find_if(fxs.begin(), fxs.end(), MatchesFx(outputFx)) != fxs.end())
++outputInternalConnection;
else
++outputExternalConnection;
}
}
// se fx e' una radice
if ((outputExternalConnection > 0) ||
(outputExternalConnection == 0 && outputInternalConnection == 0)) {
root = fx;
roots.push_back(fx);
}
// se fx e' una foglia
if (inputExternalConnection > 0 || fx->getInputPortCount() == 0 ||
(inputExternalConnection == 0 && inputInternalConnection < fx->getInputPortCount())) {
leafs.push_back(fx);
}
}
if (roots.size() != 1)
return false;
else {
if (leafs.size() == 0)
return false;
}
return true;
}
}
TMacroFx *TMacroFx::create(const vector<TFxP> &fxs)
{
std::vector<TFxP> leafs;
std::vector<TFxP> roots;
TFxP root = 0;
vector<TFxP> orederedFxs = sortFxs(fxs);
// verifica che gli effetti selezionati siano idonei ad essere raccolti
// in una macro. Ci deve essere un solo nodo terminale
// (roots.size()==1, roots[0] == root) e uno o piu' nodi di ingresso
// (assert leafs.size()>0)
if (!analyze(orederedFxs, root, roots, leafs))
return 0;
// -----------------------------
TMacroFx *macroFx = new TMacroFx;
// tutti i nodi vengono spostati (e non copiati) nella macro stessa
std::vector<TFxP>::const_iterator it = orederedFxs.begin();
for (; it != orederedFxs.end(); ++it)
macroFx->m_fxs.push_back(*it);
// i nodi di ingresso vengono messi in collegamento con le
// porte di ingresso della macro
for (int i = 0; i < (int)leafs.size(); i++) {
TFxP fx = leafs[i];
int k = 0;
int count = fx->getInputPortCount();
for (; k < count; k++) {
TFxPort *port = fx->getInputPort(k);
string portName = fx->getInputPortName(k);
string fxId = toString(fx->getFxId());
portName += "_" + toString(macroFx->getInputPortCount()) + "_" + fxId;
TFx *portFx = port->getFx();
if (portFx) {
// se la porta k-esima del nodo di ingresso i-esimo e' collegata
// ad un effetto, la porta viene inserita solo se l'effetto non fa
// gia' parte della macro
if (std::find_if(orederedFxs.begin(), orederedFxs.end(), MatchesFx(portFx)) == orederedFxs.end())
macroFx->addInputPort(portName, *port);
} else
macroFx->addInputPort(portName, *port);
}
}
// le porte di uscita di root diventano le porte di uscita della macro
int count = root->getOutputConnectionCount();
int k = count - 1;
for (; k >= 0; --k) {
TFxPort *port = root->getOutputConnection(k);
port->setFx(macroFx);
}
macroFx->setRoot(root.getPointer());
// tutti i parametri delle funzioni figlie diventano parametri della macro
collectParams(macroFx);
return macroFx;
}
