bool PFOperatorMaterialStatic::Proceed(IObject* pCont,
PreciseTimeValue timeStart,
PreciseTimeValue& timeEnd,
Object* pSystem,
INode* pNode,
INode* actionNode,
IPFIntegrator* integrator)
{
if (pblock() == NULL) return false;
int assignID = pblock()->GetInt(kMaterialStatic_assignID, timeEnd);
if (assignID == 0) return true; // nothing to assign
int showInViewport = pblock()->GetInt(kMaterialStatic_showInViewport, timeEnd);
if (!showInViewport) { // check if the system is in render; if not then return
IPFSystem* iSystem = GetPFSystemInterface(pSystem);
if (iSystem == NULL) return false;
if (!iSystem->IsRenderState()) return true; // nothing to show in viewport
}
int type = pblock()->GetInt(kMaterialStatic_type, timeEnd);
// acquire absolutely necessary particle channels
IParticleChannelAmountR* chAmount = GetParticleChannelAmountRInterface(pCont);
if (chAmount == NULL) return false; // can't find number of particles in the container
int i, count = chAmount->Count();
if (count == 0) return true; // no particles to modify
IParticleChannelPTVR* chTime = GetParticleChannelTimeRInterface(pCont);
if (chTime == NULL) return false; // can't read timing for a particle
IParticleChannelNewR* chNew = GetParticleChannelNewRInterface(pCont);
if (chNew == NULL) return false; // can't find newly entered particles for duration calculation
IChannelContainer* chCont = GetChannelContainerInterface(pCont);
if (chCont == NULL) return false;
// ensure materialStatic index channel
IParticleChannelIntW* chMtlIDW = (IParticleChannelIntW*)chCont->EnsureInterface(PARTICLECHANNELMTLINDEXW_INTERFACE,
ParticleChannelInt_Class_ID,
true, PARTICLECHANNELMTLINDEXR_INTERFACE,
PARTICLECHANNELMTLINDEXW_INTERFACE, true);
if (chMtlIDW == NULL) return false; // can't modify MaterialStatic Index channel in the container
IParticleChannelIntR* chMtlIDR = GetParticleChannelMtlIndexRInterface(pCont);
RandGenerator* randGen = randLinker().GetRandGenerator(pCont);
int rateType = pblock()->GetInt(kMaterialStatic_rateType, timeEnd);
int numSubMtls = pblock()->GetInt(kMaterialStatic_numSubMtls, timeEnd);
if (numSubMtls < 1) numSubMtls = 1;
int cycleLoop = pblock()->GetInt(kMaterialStatic_loop, timeEnd);
float rateSec = pblock()->GetFloat(kMaterialStatic_ratePerSecond, timeEnd);
float ratePart = pblock()->GetFloat(kMaterialStatic_ratePerParticle, timeEnd);
int mtlID;
bool useRatePerSec = ((type != kMaterialStatic_type_id) && (rateType == kMaterialStatic_rateType_second));
bool useRatePerPart = ((type != kMaterialStatic_type_id) && (rateType == kMaterialStatic_rateType_particle));
bool initRands = false;
// recalc offset if necessary
if (_offsetTime(pCont) == TIME_NegInfinity) {
_offsetTime(pCont) = timeStart.TimeValue();
// find the earliest time of the coming particles
PreciseTimeValue minTime = chTime->GetValue(0);
for(i=1; i<count; i++)
if (minTime > chTime->GetValue(i))
minTime = chTime->GetValue(i);
if (useRatePerSec)
if (type == kMaterialStatic_type_cycle)
_cycleOffset(pCont) = float(PreciseTimeValue(_offsetTime(pCont)) - minTime)*rateSec/TIME_TICKSPERSEC;
initRands = true;
} else if (_offsetTime(pCont) != timeStart.TimeValue()) {
if (useRatePerSec) {
if (type == kMaterialStatic_type_cycle) {
float timeDelta = float(timeStart.TimeValue() - _offsetTime(pCont));
float addOffset = timeDelta*rateSec/TIME_TICKSPERSEC;
_cycleOffset(pCont) += addOffset;
if (_cycleOffset(pCont) >= numSubMtls) {
if (cycleLoop) _cycleOffset(pCont) -= numSubMtls*int(_cycleOffset(pCont)/numSubMtls);
else _cycleOffset(pCont) = numSubMtls - 1.0f;
}
}
}
_offsetTime(pCont) = timeStart.TimeValue();
initRands = true;
}
if (initRands && useRatePerSec && (type == kMaterialStatic_type_random)) {
int intervalDelta = int(timeEnd.TimeValue() - timeStart.TimeValue()) + 1;
_randMtlIndex(pCont).SetCount(intervalDelta);
float curOffset = _cycleOffset(pCont);
int curMtlID = int(curOffset);
_randMtlIndex(pCont)[0] = curMtlID;
for(int i=1; i<intervalDelta; i++) {
float addOffset = rateSec/TIME_TICKSPERSEC;
curOffset += addOffset;
if (int(curOffset) != curMtlID) {
curOffset = randGen->Rand0X(numSubMtls-1) + (curOffset - floor(curOffset));
curMtlID = int(curOffset);
}
_randMtlIndex(pCont)[i] = curMtlID;
_cycleOffset(pCont) = curOffset;
}
}
float curCycleOffset = _cycleOffset(pCont);
float ratePerPart = pblock()->GetFloat(kMaterialStatic_ratePerParticle, timeEnd);
for(i=0; i<count; i++) {
if (!chNew->IsNew(i)) continue; // the ID is already set
switch(type) {
case kMaterialStatic_type_id:
mtlID = GetPFInt(pblock(), kMaterialStatic_materialID, chTime->GetValue(i).TimeValue());
mtlID--;
break;
case kMaterialStatic_type_cycle:
if (rateType == kMaterialStatic_rateType_second) {
float timeDelta = float(chTime->GetValue(i) - timeStart);
float addOffset = timeDelta*rateSec/TIME_TICKSPERSEC;
mtlID = int(curCycleOffset + addOffset);
if (mtlID >= numSubMtls) {
if (cycleLoop) mtlID = mtlID%numSubMtls;
else mtlID = numSubMtls - 1;
}
} else { // per particle rate type
mtlID = int(curCycleOffset);
if (mtlID >= numSubMtls) {
if (cycleLoop) mtlID = mtlID%numSubMtls;
else mtlID = numSubMtls - 1;
}
if (ratePart > 0.0f) {
curCycleOffset += 1.0f/ratePart;
if (curCycleOffset >= numSubMtls) {
if (cycleLoop) curCycleOffset -= numSubMtls*int(curCycleOffset/numSubMtls);
else curCycleOffset = numSubMtls - 1.0f;
}
}
}
break;
case kMaterialStatic_type_random:
if (rateType == kMaterialStatic_rateType_second) {
int timeDelta = int( chTime->GetValue(i) - timeStart.TimeValue() );
mtlID = _randMtlIndex(pCont)[timeDelta];
} else { // per particle rate type
mtlID = int(curCycleOffset);
int oldMtlID = mtlID;
if (mtlID >= numSubMtls) {
if (cycleLoop) mtlID = mtlID%numSubMtls;
else mtlID = numSubMtls - 1;
}
if (ratePart > 0.0f) {
curCycleOffset += 1.0f/ratePart;
if (int(curCycleOffset) != oldMtlID)
curCycleOffset = randGen->Rand0X(numSubMtls-1) + (curCycleOffset - floor(curCycleOffset));
}
}
break;
default: DbgAssert(0);
}
if (mtlID < 0) mtlID = 0;
chMtlIDW->SetValue(i, mtlID);
}
if (useRatePerPart)
_cycleOffset(pCont) = curCycleOffset;
return true;
}
bool PFOperatorMaterialFrequency::Proceed(IObject* pCont,
PreciseTimeValue timeStart,
PreciseTimeValue& timeEnd,
Object* pSystem,
INode* pNode,
INode* actionNode,
IPFIntegrator* integrator)
{
if (pblock() == NULL) return false;
int assignID = pblock()->GetInt(kMaterialFrequency_assignID, timeEnd);
if (assignID == 0) return true; // nothing to assign
int showInViewport = pblock()->GetInt(kMaterialFrequency_showInViewport, timeEnd);
if (!showInViewport) { // check if the system is in render; if not then return
IPFSystem* iSystem = GetPFSystemInterface(pSystem);
if (iSystem == NULL) return false;
if (!iSystem->IsRenderState()) return true; // nothing to show in viewport
}
// acquire absolutely necessary particle channels
IParticleChannelAmountR* chAmount = GetParticleChannelAmountRInterface(pCont);
if (chAmount == NULL) return false; // can't find number of particles in the container
IParticleChannelPTVR* chTime = GetParticleChannelTimeRInterface(pCont);
if (chTime == NULL) return false; // can't read timing for a particle
IParticleChannelNewR* chNew = GetParticleChannelNewRInterface(pCont);
if (chNew == NULL) return false; // can't find newly entered particles for duration calculation
IChannelContainer* chCont = GetChannelContainerInterface(pCont);
if (chCont == NULL) return false;
// ensure material index channel
IParticleChannelIntW* chMtlIDW = (IParticleChannelIntW*)chCont->EnsureInterface(PARTICLECHANNELMTLINDEXW_INTERFACE,
ParticleChannelInt_Class_ID,
true, PARTICLECHANNELMTLINDEXR_INTERFACE,
PARTICLECHANNELMTLINDEXW_INTERFACE, true);
if (chMtlIDW == NULL) return false; // can't modify Material Index channel in the container
IParticleChannelIntR* chMtlIDR = GetParticleChannelMtlIndexRInterface(pCont);
RandGenerator* randGen = randLinker().GetRandGenerator(pCont);
int i, j, count = chAmount->Count();
int mtlID;
float idShare[10], slideShare[10];
int pblockIDShare[] = { kMaterialFrequency_id1, kMaterialFrequency_id2, kMaterialFrequency_id3, kMaterialFrequency_id4, kMaterialFrequency_id5, kMaterialFrequency_id6, kMaterialFrequency_id7, kMaterialFrequency_id8, kMaterialFrequency_id9, kMaterialFrequency_id10 };
for(i=0; i<count; i++) {
if (!chNew->IsNew(i)) continue; // the ID is already set
TimeValue curTime = chTime->GetValue(i).TimeValue();
float totalShare = 0.0f;
for(j=0; j<10; j++) {
totalShare += (idShare[j] = GetPFFloat(pblock(), pblockIDShare[j], curTime));
slideShare[j] = totalShare;
}
float randomShare = totalShare*randGen->Rand01();
for(j=0; j<10; j++) {
mtlID = j;
if (randomShare < slideShare[j]) break;
}
chMtlIDW->SetValue(i, mtlID);
}
return true;
}
bool AlembicPoints::Save(double time, bool bLastFrame)
{
ESS_PROFILE_FUNC();
// Note: Particles are always considered to be animated even though
// the node does not have the IsAnimated() flag.
// Extract our particle emitter at the given time
TimeValue ticks = GetTimeValueFromFrame(time);
Object *obj = mMaxNode->EvalWorldState(ticks).obj;
SaveMetaData(mMaxNode, this);
SimpleParticle* pSimpleParticle = (SimpleParticle*)obj->GetInterface(I_SIMPLEPARTICLEOBJ);
IPFSystem* ipfSystem = GetPFSystemInterface(obj);
IParticleObjectExt* particlesExt = GetParticleObjectExtInterface(obj);
#ifdef THINKING_PARTICLES
ParticleMat* pThinkingParticleMat = NULL;
TP_MasterSystemInterface* pTPMasterSystemInt = NULL;
if(obj->CanConvertToType(MATTERWAVES_CLASS_ID))
{
pThinkingParticleMat = reinterpret_cast<ParticleMat*>(obj->ConvertToType(ticks, MATTERWAVES_CLASS_ID));
pTPMasterSystemInt = reinterpret_cast<TP_MasterSystemInterface*>(obj->GetInterface(IID_TP_MASTERSYSTEM));
}
#endif
const bool bAutomaticInstancing = GetCurrentJob()->GetOption("automaticInstancing");
if(
#ifdef THINKING_PARTICLES
!pThinkingParticleMat &&
#endif
!particlesExt && !pSimpleParticle){
return false;
}
//We have to put the particle system into the renders state so that PFOperatorMaterialFrequency::Proceed will set the materialID channel
//Note: settting the render state to true breaks the shape node instancing export
bool bRenderStateForced = false;
if(bAutomaticInstancing && ipfSystem && !ipfSystem->IsRenderState()){
ipfSystem->SetRenderState(true);
bRenderStateForced = true;
}
int numParticles = 0;
#ifdef THINKING_PARTICLES
if(pThinkingParticleMat){
numParticles = pThinkingParticleMat->NumParticles();
}
else
#endif
if(particlesExt){
particlesExt->UpdateParticles(mMaxNode, ticks);
numParticles = particlesExt->NumParticles();
}
else if(pSimpleParticle){
pSimpleParticle->Update(ticks, mMaxNode);
numParticles = pSimpleParticle->parts.points.Count();
}
// Store positions, velocity, width/size, scale, id, bounding box
std::vector<Abc::V3f> positionVec;
std::vector<Abc::V3f> velocityVec;
std::vector<Abc::V3f> scaleVec;
std::vector<float> widthVec;
std::vector<float> ageVec;
std::vector<float> massVec;
std::vector<float> shapeTimeVec;
std::vector<Abc::uint64_t> idVec;
std::vector<Abc::uint16_t> shapeTypeVec;
std::vector<Abc::uint16_t> shapeInstanceIDVec;
std::vector<Abc::Quatf> orientationVec;
std::vector<Abc::Quatf> angularVelocityVec;
std::vector<Abc::C4f> colorVec;
positionVec.reserve(numParticles);
velocityVec.reserve(numParticles);
scaleVec.reserve(numParticles);
widthVec.reserve(numParticles);
ageVec.reserve(numParticles);
massVec.reserve(numParticles);
shapeTimeVec.reserve(numParticles);
idVec.reserve(numParticles);
shapeTypeVec.reserve(numParticles);
shapeInstanceIDVec.reserve(numParticles);
orientationVec.reserve(numParticles);
angularVelocityVec.reserve(numParticles);
colorVec.reserve(numParticles);
//std::vector<std::string> instanceNamesVec;
Abc::Box3d bbox;
bool constantPos = true;
bool constantVel = true;
bool constantScale = true;
bool constantWidth = true;
bool constantAge = true;
bool constantOrientation = true;
bool constantAngularVel = true;
bool constantColor = true;
if(bAutomaticInstancing){
SetMaxSceneTime(ticks);
}
//The MAX interfaces return everything in world coordinates,
//so we need to multiply the inverse the node world transform matrix
Matrix3 nodeWorldTM = mMaxNode->GetObjTMAfterWSM(ticks);
// Convert the max transform to alembic
Matrix3 alembicMatrix;
ConvertMaxMatrixToAlembicMatrix(nodeWorldTM, alembicMatrix);
Abc::M44d nodeWorldTrans( alembicMatrix.GetRow(0).x, alembicMatrix.GetRow(0).y, alembicMatrix.GetRow(0).z, 0,
alembicMatrix.GetRow(1).x, alembicMatrix.GetRow(1).y, alembicMatrix.GetRow(1).z, 0,
alembicMatrix.GetRow(2).x, alembicMatrix.GetRow(2).y, alembicMatrix.GetRow(2).z, 0,
alembicMatrix.GetRow(3).x, alembicMatrix.GetRow(3).y, alembicMatrix.GetRow(3).z, 1);
Abc::M44d nodeWorldTransInv = nodeWorldTrans.inverse();
//ESS_LOG_WARNING("tick: "<<ticks<<" numParticles: "<<numParticles<<"\n");
ExoNullView nullView;
particleGroupInterface groupInterface(particlesExt, obj, mMaxNode, &nullView);
{
ESS_PROFILE_SCOPE("AlembicPoints::SAVE - numParticlesLoop");
for (int i = 0; i < numParticles; ++i)
{
Abc::V3f pos(0.0);
Abc::V3f vel(0.0);
Abc::V3f scale(1.0);
Abc::C4f color(0.5, 0.5, 0.5, 1.0);
float age = 0;
Abc::uint64_t id = 0;
Abc::Quatd orientation(0.0, 0.0, 1.0, 0.0);
Abc::Quatd spin(0.0, 0.0, 1.0, 0.0);
// Particle size is a uniform scale multiplier in XSI. In Max, I need to learn where to get this
// For now, we'll just default to 1
float width = 1.0f;
ShapeType shapetype = ShapeType_Point;
float shapeInstanceTime = (float)time;
Abc::uint16_t shapeInstanceId = 0;
#ifdef THINKING_PARTICLES
if(pThinkingParticleMat){
if(pTPMasterSystemInt->IsAlive(i) == FALSE){
continue;
}
//TimeValue ageValue = particlesExt->GetParticleAgeByIndex(i);
TimeValue ageValue = pTPMasterSystemInt->Age(i);
if(ageValue == -1){
continue;
}
ESS_PROFILE_SCOPE("AlembicPoints::SAVE - numParticlesLoop - ThinkingParticles");
age = (float)GetSecondsFromTimeValue(ageValue);
//pos = ConvertMaxPointToAlembicPoint(*particlesExt->GetParticlePositionByIndex(i));
pos = ConvertMaxPointToAlembicPoint(pTPMasterSystemInt->Position(i));
//vel = ConvertMaxVectorToAlembicVector(*particlesExt->GetParticleSpeedByIndex(i) * TIME_TICKSPERSEC);
vel = ConvertMaxVectorToAlembicVector(pTPMasterSystemInt->Velocity(i) * TIME_TICKSPERSEC);
scale = ConvertMaxScaleToAlembicScale(pTPMasterSystemInt->Scale(i));
scale *= pTPMasterSystemInt->Size(i);
//ConvertMaxEulerXYZToAlembicQuat(*particlesExt->GetParticleOrientationByIndex(i), orientation);
Matrix3 alignmentMatMax = pTPMasterSystemInt->Alignment(i);
Abc::M44d alignmentMat;
ConvertMaxMatrixToAlembicMatrix(alignmentMatMax, alignmentMat);
/*alignmentMat = Abc::M44d( alignmentMatMax.GetRow(0).x, alignmentMatMax.GetRow(0).y, alignmentMatMax.GetRow(0).z, 0,
alignmentMatMax.GetRow(1).x, alignmentMatMax.GetRow(1).y, alignmentMatMax.GetRow(1).z, 0,
alignmentMatMax.GetRow(2).x, alignmentMatMax.GetRow(2).y, alignmentMatMax.GetRow(2).z, 0,
alignmentMatMax.GetRow(3).x, alignmentMatMax.GetRow(3).y, alignmentMatMax.GetRow(3).z, 1);*/
//orientation = ConvertMaxQuatToAlembicQuat(extracctuat(alignmentMat), true);
alignmentMat = alignmentMat * nodeWorldTransInv;
orientation = extractQuat(alignmentMat);
//ConvertMaxAngAxisToAlembicQuat(*particlesExt->GetParticleSpinByIndex(i), spin);
ConvertMaxAngAxisToAlembicQuat(pTPMasterSystemInt->Spin(i), spin);
id = particlesExt->GetParticleBornIndex(i);
//seems to always return 0
//int nPid = pThinkingParticleMat->ParticleID(i);
int nMatId = -1;
Matrix3 meshTM;
meshTM.IdentityMatrix();
BOOL bNeedDelete = FALSE;
BOOL bChanged = FALSE;
Mesh* pMesh = NULL;
{
ESS_PROFILE_SCOPE("AlembicPoints::SAVE - numParticlesLoop - ThinkingParticles - GetParticleRenderMesh");
pMesh = pThinkingParticleMat->GetParticleRenderMesh(ticks, mMaxNode, nullView, bNeedDelete, i, meshTM, bChanged);
}
if(pMesh){
ESS_PROFILE_SCOPE("AlembicPoints::SAVE - numParticlesLoop - ThinkingParticles - CacheShapeMesh");
meshInfo mi = CacheShapeMesh(pMesh, bNeedDelete, meshTM, nMatId, i, ticks, shapetype, shapeInstanceId, shapeInstanceTime);
Abc::V3d min = pos + mi.bbox.min;
Abc::V3d max = pos + mi.bbox.max;
bbox.extendBy(min);
bbox.extendBy(max);
}
else{
shapetype = ShapeType_Point;
}
}
else
#endif
if(particlesExt && ipfSystem){
TimeValue ageValue = particlesExt->GetParticleAgeByIndex(i);
if(ageValue == -1){
continue;
}
age = (float)GetSecondsFromTimeValue(ageValue);
pos = ConvertMaxPointToAlembicPoint(*particlesExt->GetParticlePositionByIndex(i));
vel = ConvertMaxVectorToAlembicVector(*particlesExt->GetParticleSpeedByIndex(i) * TIME_TICKSPERSEC);
scale = ConvertMaxScaleToAlembicScale(*particlesExt->GetParticleScaleXYZByIndex(i));
ConvertMaxEulerXYZToAlembicQuat(*particlesExt->GetParticleOrientationByIndex(i), orientation);
ConvertMaxAngAxisToAlembicQuat(*particlesExt->GetParticleSpinByIndex(i), spin);
//age = (float)GetSecondsFromTimeValue(particlesExt->GetParticleAgeByIndex(i));
id = particlesExt->GetParticleBornIndex(i);
if(bAutomaticInstancing){
int nMatId = -1;
if(ipfSystem){
if( groupInterface.setCurrentParticle(ticks, i) ){
nMatId = groupInterface.getCurrentMtlId();
}
else{
ESS_LOG_WARNING("Error: cound retrieve material ID for particle mesh "<<i);
}
}
Matrix3 meshTM;
meshTM.IdentityMatrix();
BOOL bNeedDelete = FALSE;
BOOL bChanged = FALSE;
Mesh* pMesh = pMesh = particlesExt->GetParticleShapeByIndex(i);
if(pMesh){
meshInfo mi = CacheShapeMesh(pMesh, bNeedDelete, meshTM, nMatId, i, ticks, shapetype, shapeInstanceId, shapeInstanceTime);
Abc::V3d min = pos + mi.bbox.min;
Abc::V3d max = pos + mi.bbox.max;
bbox.extendBy(min);
bbox.extendBy(max);
}
else{
shapetype = ShapeType_Point;
}
}
else{
GetShapeType(particlesExt, i, ticks, shapetype, shapeInstanceId, shapeInstanceTime);
}
color = GetColor(particlesExt, i, ticks);
}
else if(pSimpleParticle){
if( ! pSimpleParticle->parts.Alive( i ) ) {
continue;
}
pos = ConvertMaxPointToAlembicPoint(pSimpleParticle->ParticlePosition(ticks, i));
vel = ConvertMaxVectorToAlembicVector(pSimpleParticle->ParticleVelocity(ticks, i));
//simple particles have no scale?
//simple particles have no orientation?
age = (float)GetSecondsFromTimeValue( pSimpleParticle->ParticleAge(ticks, i) );
//simple particles have born index
width = pSimpleParticle->ParticleSize(ticks, i);
Abc::V3d min(pos.x - width/2, pos.y - width/2, pos.z - width/2);
Abc::V3d max(pos.x + width/2, pos.y + width/2, pos.z + width/2);
bbox.extendBy(min);
bbox.extendBy(max);
}
{
ESS_PROFILE_SCOPE("AlembicPoints::SAVE - numParticlesLoop - end loop save");
//move everything from world space to local space
pos = pos * nodeWorldTransInv;
Abc::V4f vel4(vel.x, vel.y, vel.z, 0.0);
vel4 = vel4 * nodeWorldTransInv;
vel.setValue(vel4.x, vel4.y, vel4.z);
//scale = scale * nodeWorldTransInv;
//orientation = Abc::extractQuat(orientation.toMatrix44() * nodeWorldTransInv);
//spin = Abc::extractQuat(spin.toMatrix44() * nodeWorldTransInv);
bbox.extendBy( pos );
positionVec.push_back( pos );
velocityVec.push_back( vel );
scaleVec.push_back( scale );
widthVec.push_back( width );
ageVec.push_back( age );
idVec.push_back( id );
orientationVec.push_back( orientation );
angularVelocityVec.push_back( spin );
shapeTypeVec.push_back( shapetype );
shapeInstanceIDVec.push_back( shapeInstanceId );
shapeTimeVec.push_back( shapeInstanceTime );
colorVec.push_back( color );
constantPos &= (pos == positionVec[0]);
constantVel &= (vel == velocityVec[0]);
constantScale &= (scale == scaleVec[0]);
constantWidth &= (width == widthVec[0]);
constantAge &= (age == ageVec[0]);
constantOrientation &= (orientation == orientationVec[0]);
constantAngularVel &= (spin == angularVelocityVec[0]);
constantColor &= (color == colorVec[0]);
// Set the archive bounding box
// Positions for particles are already cnsider to be in world space
if (mJob)
{
mJob->GetArchiveBBox().extendBy(pos);
}
}
}
}
// if (numParticles > 1)
// {
// ESS_PROFILE_SCOPE("AlembicPoints::Save - vectorResize");
// if (constantPos) { positionVec.resize(1); }
// if (constantVel) { velocityVec.resize(1); }
// if (constantScale) { scaleVec.resize(1); }
// if (constantWidth) { widthVec.resize(1); }
// if (constantAge) { ageVec.resize(1); }
// if (constantOrientation){ orientationVec.resize(1); }
// if (constantAngularVel) { angularVelocityVec.resize(1); }
//if (constantColor) { colorVec.resize(1); }
// }
{
ESS_PROFILE_SCOPE("AlembicPoints::Save - sample writing");
// Store the information into our properties and points schema
Abc::P3fArraySample positionSample( positionVec);
Abc::P3fArraySample velocitySample(velocityVec);
Abc::P3fArraySample scaleSample(scaleVec);
Abc::FloatArraySample widthSample(widthVec);
Abc::FloatArraySample ageSample(ageVec);
Abc::FloatArraySample massSample(massVec);
Abc::FloatArraySample shapeTimeSample(shapeTimeVec);
Abc::UInt64ArraySample idSample(idVec);
Abc::UInt16ArraySample shapeTypeSample(shapeTypeVec);
Abc::UInt16ArraySample shapeInstanceIDSample(shapeInstanceIDVec);
Abc::QuatfArraySample orientationSample(orientationVec);
Abc::QuatfArraySample angularVelocitySample(angularVelocityVec);
Abc::C4fArraySample colorSample(colorVec);
mScaleProperty.set(scaleSample);
mAgeProperty.set(ageSample);
mMassProperty.set(massSample);
mShapeTimeProperty.set(shapeTimeSample);
mShapeTypeProperty.set(shapeTypeSample);
mShapeInstanceIDProperty.set(shapeInstanceIDSample);
mOrientationProperty.set(orientationSample);
mAngularVelocityProperty.set(angularVelocitySample);
mColorProperty.set(colorSample);
mPointsSample.setPositions(positionSample);
mPointsSample.setVelocities(velocitySample);
mPointsSample.setWidths(AbcG::OFloatGeomParam::Sample(widthSample, AbcG::kVertexScope));
mPointsSample.setIds(idSample);
mPointsSample.setSelfBounds(bbox);
mPointsSchema.getChildBoundsProperty().set( bbox);
mPointsSchema.set(mPointsSample);
}
mNumSamples++;
//mInstanceNames.pop_back();
if(bAutomaticInstancing){
saveCurrentFrameMeshes();
}
if(bRenderStateForced){
ipfSystem->SetRenderState(false);
}
if(bLastFrame){
ESS_PROFILE_SCOPE("AlembicParticles::Save - save instance names property");
std::vector<std::string> instanceNames(mNumShapeMeshes);
for(faceVertexHashToShapeMap::iterator it = mShapeMeshCache.begin(); it != mShapeMeshCache.end(); it++){
std::stringstream pathStream;
pathStream << "/" << it->second.name<< "/" << it->second.name <<"Shape";
instanceNames[it->second.nMeshInstanceId] = pathStream.str();
}
//for some reason the .dims property is not written when there is exactly one entry if we don't push an empty string
//having an extra unreferenced entry seems to be harmless
instanceNames.push_back("");
mInstanceNamesProperty.set(Abc::StringArraySample(instanceNames));
}
return true;
}
//+>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>+
//| From IPFTest |
//+>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>+
bool PFTestSplitByAmount::Proceed(IObject* pCont,
PreciseTimeValue timeStart,
PreciseTimeValue& timeEnd,
Object* pSystem,
INode* pNode,
INode* actionNode,
IPFIntegrator* integrator,
BitArray& testResult,
Tab<float>& testTime)
{
int contIndex;
if (!hasParticleContainer(pCont, contIndex)) return false;
_lastUpdate(contIndex) = timeEnd.TimeValue();
bool exactStep = IsExactIntegrationStep(timeEnd, pSystem);
// update all other systems to the current time; everybody should be in sync
// for proper accumulation amounts
int i;
for(i=0; i<allParticleContainers().Count(); i++) {
if (allParticleContainer(i) == pCont) continue;
if (allSystemNode(i) == pNode) continue;
if (lastUpdate(i) == timeEnd.TimeValue()) continue;
TimeValue timeToUpdateTo = timeEnd.TimeValue();
allSystemNode(i)->NotifyDependents(FOREVER, PartID(&timeToUpdateTo), kPFMSG_UpdateToTime, NOTIFY_ALL, TRUE );
}
// get channel container interface
IChannelContainer* chCont;
chCont = GetChannelContainerInterface(pCont);
if (chCont == NULL) return false;
// acquire absolutely necessary particle channels
IParticleChannelAmountR* chAmount = GetParticleChannelAmountRInterface(pCont);
if (chAmount == NULL) return false; // can't find number of particles in the container
IParticleChannelNewR* chNew = GetParticleChannelNewRInterface(pCont);
if (chNew == NULL) return false; // can't find "new" property of particles in the container
// acquire TestSplitByAmount private particle channel; if not present then create it
IParticleChannelBoolW* chTestW = (IParticleChannelBoolW*)chCont->EnsureInterface(PARTICLECHANNELTESTSPLITBYAMOUNTW_INTERFACE,
ParticleChannelBool_Class_ID,
true, PARTICLECHANNELTESTSPLITBYAMOUNTR_INTERFACE,
PARTICLECHANNELTESTSPLITBYAMOUNTW_INTERFACE, false,
actionNode, (Object*)this);
IParticleChannelBoolR* chTestR = (IParticleChannelBoolR*)chCont->GetPrivateInterface(PARTICLECHANNELTESTSPLITBYAMOUNTR_INTERFACE, (Object*)this);
if ((chTestR == NULL) || (chTestW == NULL)) return false; // can't set test value for newly entered particles
int count = chAmount->Count();
// check if all particles are "old". If some particles are "new" then we
// have to calculate test values for those.
if (!chNew->IsAllOld())
{
RandGenerator* randGen = randLinker().GetRandGenerator(pCont);
if (randGen == NULL) return false;
int testType = pblock()->GetInt(kSplitByAmount_testType, timeStart);
float fraction = GetPFFloat(pblock(), kSplitByAmount_fraction, timeStart);
int everyN = GetPFInt(pblock(), kSplitByAmount_everyN, timeStart);
int firstN = pblock()->GetInt(kSplitByAmount_firstN, timeStart);
bool perSource = (pblock()->GetInt(kSplitByAmount_perSource, timeStart) != 0);
int curWentThru = perSource ? wentThruTotal(pNode) : wentThruTotal();
// number of "first N" particles is adjusted by multiplier coefficient
// of the master particle system. This is done to make "first N"
// parameter to be consistent to "total" number of particles acclaimed
// by a birth operator
IPFSystem* pfSys = PFSystemInterface(pSystem);
if (pfSys == NULL) return false; // no handle for PFSystem interface
firstN *= pfSys->GetMultiplier(timeStart);
for(i=0; i<count; i++) {
if (chNew->IsNew(i)) { // calculate test value only for new particles
bool sendOut = false;
switch(testType) {
case kSplitByAmount_testType_fraction:
sendOut = (randGen->Rand01() <= fraction);
break;
case kSplitByAmount_testType_everyN:
_wentThruAccum(contIndex) += 1;
if (wentThruAccum(contIndex) >= everyN) {
sendOut = true;
_wentThruAccum(contIndex) = 0;
}
break;
case kSplitByAmount_testType_firstN:
_wentThruTotal(contIndex) += 1;
if (curWentThru++ < firstN) sendOut = true;
break;
case kSplitByAmount_testType_afterFirstN:
_wentThruTotal(contIndex) += 1;
if (curWentThru++ >= firstN) sendOut = true;
break;
}
chTestW->SetValue(i, sendOut);
}
}
}
// check all particles by predefined test channel
testResult.SetSize(count);
testResult.ClearAll();
testTime.SetCount(count);
if (exactStep) {
for(i=0; i<count; i++)
{
if (chTestR->GetValue(i)) {
testResult.Set(i);
testTime[i] = 0.0f;
}
}
}
return true;
}
