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465 lines
14 KiB
C++
465 lines
14 KiB
C++
#include "particle.hpp"
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#include <limits>
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#include <osg/MatrixTransform>
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#include <osg/Geometry>
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#include <components/nif/controlled.hpp>
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#include <components/nif/nifkey.hpp>
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#include <components/nif/data.hpp>
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#include "userdata.hpp"
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namespace NifOsg
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{
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ParticleSystem::ParticleSystem()
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: osgParticle::ParticleSystem()
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, mQuota(std::numeric_limits<int>::max())
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{
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}
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ParticleSystem::ParticleSystem(const ParticleSystem ©, const osg::CopyOp ©op)
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: osgParticle::ParticleSystem(copy, copyop)
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, mQuota(copy.mQuota)
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{
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// For some reason the osgParticle constructor doesn't copy the particles
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for (int i=0;i<copy.numParticles()-copy.numDeadParticles();++i)
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createParticle(copy.getParticle(i));
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}
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void ParticleSystem::setQuota(int quota)
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{
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mQuota = quota;
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}
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osgParticle::Particle* ParticleSystem::createParticle(const osgParticle::Particle *ptemplate)
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{
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if (numParticles()-numDeadParticles() < mQuota)
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return osgParticle::ParticleSystem::createParticle(ptemplate);
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return NULL;
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}
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void InverseWorldMatrix::operator()(osg::Node *node, osg::NodeVisitor *nv)
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{
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if (nv && nv->getVisitorType() == osg::NodeVisitor::UPDATE_VISITOR)
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{
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osg::NodePath path = nv->getNodePath();
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path.pop_back();
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osg::MatrixTransform* trans = static_cast<osg::MatrixTransform*>(node);
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osg::Matrix mat = osg::computeLocalToWorld( path );
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mat.orthoNormalize(mat); // don't undo the scale
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mat.invert(mat);
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trans->setMatrix(mat);
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}
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traverse(node,nv);
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}
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ParticleShooter::ParticleShooter(float minSpeed, float maxSpeed, float horizontalDir, float horizontalAngle, float verticalDir, float verticalAngle, float lifetime, float lifetimeRandom)
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: mMinSpeed(minSpeed), mMaxSpeed(maxSpeed), mHorizontalDir(horizontalDir)
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, mHorizontalAngle(horizontalAngle), mVerticalDir(verticalDir), mVerticalAngle(verticalAngle)
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, mLifetime(lifetime), mLifetimeRandom(lifetimeRandom)
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{
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}
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ParticleShooter::ParticleShooter()
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: mMinSpeed(0.f), mMaxSpeed(0.f), mHorizontalDir(0.f)
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, mHorizontalAngle(0.f), mVerticalDir(0.f), mVerticalAngle(0.f)
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, mLifetime(0.f), mLifetimeRandom(0.f)
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{
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}
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ParticleShooter::ParticleShooter(const ParticleShooter ©, const osg::CopyOp ©op)
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: osgParticle::Shooter(copy, copyop)
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{
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*this = copy;
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}
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void ParticleShooter::shoot(osgParticle::Particle *particle) const
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{
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float hdir = mHorizontalDir + mHorizontalAngle * (2.f * (std::rand() / static_cast<double>(RAND_MAX)) - 1.f);
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float vdir = mVerticalDir + mVerticalAngle * (2.f * (std::rand() / static_cast<double>(RAND_MAX)) - 1.f);
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osg::Vec3f dir = (osg::Quat(vdir, osg::Vec3f(0,1,0)) * osg::Quat(hdir, osg::Vec3f(0,0,1)))
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* osg::Vec3f(0,0,1);
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float vel = mMinSpeed + (mMaxSpeed - mMinSpeed) * std::rand() / static_cast<float>(RAND_MAX);
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particle->setVelocity(dir * vel);
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// Not supposed to set this here, but there doesn't seem to be a better way of doing it
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particle->setLifeTime(mLifetime + mLifetimeRandom * std::rand() / static_cast<float>(RAND_MAX));
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}
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GrowFadeAffector::GrowFadeAffector(float growTime, float fadeTime)
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: mGrowTime(growTime)
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, mFadeTime(fadeTime)
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, mCachedDefaultSize(0.f)
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{
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}
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GrowFadeAffector::GrowFadeAffector()
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: mGrowTime(0.f)
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, mFadeTime(0.f)
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, mCachedDefaultSize(0.f)
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{
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}
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GrowFadeAffector::GrowFadeAffector(const GrowFadeAffector& copy, const osg::CopyOp& copyop)
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: osgParticle::Operator(copy, copyop)
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{
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*this = copy;
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}
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void GrowFadeAffector::beginOperate(osgParticle::Program *program)
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{
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mCachedDefaultSize = program->getParticleSystem()->getDefaultParticleTemplate().getSizeRange().minimum;
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}
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void GrowFadeAffector::operate(osgParticle::Particle* particle, double /* dt */)
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{
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float size = mCachedDefaultSize;
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if (particle->getAge() < mGrowTime && mGrowTime != 0.f)
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size *= particle->getAge() / mGrowTime;
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if (particle->getLifeTime() - particle->getAge() < mFadeTime && mFadeTime != 0.f)
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size *= (particle->getLifeTime() - particle->getAge()) / mFadeTime;
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particle->setSizeRange(osgParticle::rangef(size, size));
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}
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ParticleColorAffector::ParticleColorAffector(const Nif::NiColorData *clrdata)
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: mData(clrdata->mKeyMap, osg::Vec4f(1,1,1,1))
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{
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}
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ParticleColorAffector::ParticleColorAffector()
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{
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}
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ParticleColorAffector::ParticleColorAffector(const ParticleColorAffector ©, const osg::CopyOp ©op)
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: osgParticle::Operator(copy, copyop)
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{
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*this = copy;
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}
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void ParticleColorAffector::operate(osgParticle::Particle* particle, double /* dt */)
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{
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float time = static_cast<float>(particle->getAge()/particle->getLifeTime());
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osg::Vec4f color = mData.interpKey(time);
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particle->setColorRange(osgParticle::rangev4(color, color));
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}
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GravityAffector::GravityAffector(const Nif::NiGravity *gravity)
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: mForce(gravity->mForce)
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, mType(static_cast<ForceType>(gravity->mType))
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, mPosition(gravity->mPosition)
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, mDirection(gravity->mDirection)
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, mDecay(gravity->mDecay)
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{
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}
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GravityAffector::GravityAffector()
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: mForce(0), mType(Type_Wind), mDecay(0.f)
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{
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}
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GravityAffector::GravityAffector(const GravityAffector ©, const osg::CopyOp ©op)
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: osgParticle::Operator(copy, copyop)
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{
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*this = copy;
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}
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void GravityAffector::beginOperate(osgParticle::Program* program)
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{
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bool absolute = (program->getReferenceFrame() == osgParticle::ParticleProcessor::ABSOLUTE_RF);
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if (mType == Type_Point || mDecay != 0.f) // we don't need the position for Wind gravity, except if decay is being applied
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mCachedWorldPosition = absolute ? program->transformLocalToWorld(mPosition) : mPosition;
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mCachedWorldDirection = absolute ? program->rotateLocalToWorld(mDirection) : mDirection;
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mCachedWorldDirection.normalize();
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}
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void GravityAffector::operate(osgParticle::Particle *particle, double dt)
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{
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const float magic = 1.6f;
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switch (mType)
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{
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case Type_Wind:
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{
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float decayFactor = 1.f;
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if (mDecay != 0.f)
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{
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osg::Plane gravityPlane(mCachedWorldDirection, mCachedWorldPosition);
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float distance = std::abs(gravityPlane.distance(particle->getPosition()));
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decayFactor = std::exp(-1.f * mDecay * distance);
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}
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particle->addVelocity(mCachedWorldDirection * mForce * dt * decayFactor * magic);
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break;
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}
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case Type_Point:
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{
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osg::Vec3f diff = mCachedWorldPosition - particle->getPosition();
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float decayFactor = 1.f;
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if (mDecay != 0.f)
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decayFactor = std::exp(-1.f * mDecay * diff.length());
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diff.normalize();
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particle->addVelocity(diff * mForce * dt * decayFactor * magic);
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break;
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}
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}
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}
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Emitter::Emitter()
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: osgParticle::Emitter()
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{
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}
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Emitter::Emitter(const Emitter ©, const osg::CopyOp ©op)
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: osgParticle::Emitter(copy, copyop)
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, mTargets(copy.mTargets)
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, mPlacer(copy.mPlacer)
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, mShooter(copy.mShooter)
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// need a deep copy because the remainder is stored in the object
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, mCounter(osg::clone(copy.mCounter.get(), osg::CopyOp::DEEP_COPY_ALL))
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{
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}
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Emitter::Emitter(const std::vector<int> &targets)
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: mTargets(targets)
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{
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}
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void Emitter::setShooter(osgParticle::Shooter *shooter)
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{
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mShooter = shooter;
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}
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void Emitter::setPlacer(osgParticle::Placer *placer)
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{
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mPlacer = placer;
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}
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void Emitter::setCounter(osgParticle::Counter *counter)
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{
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mCounter = counter;
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}
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void Emitter::emitParticles(double dt)
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{
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int n = mCounter->numParticlesToCreate(dt);
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if (n == 0)
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return;
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osg::Matrix worldToPs;
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// maybe this could be optimized by halting at the lowest common ancestor of the particle and emitter nodes
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osg::NodePathList partsysNodePaths = getParticleSystem()->getParentalNodePaths();
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if (!partsysNodePaths.empty())
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{
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osg::Matrix psToWorld = osg::computeLocalToWorld(partsysNodePaths[0]);
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worldToPs = osg::Matrix::inverse(psToWorld);
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}
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const osg::Matrix& ltw = getLocalToWorldMatrix();
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osg::Matrix emitterToPs = ltw * worldToPs;
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if (!mTargets.empty())
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{
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int randomRecIndex = mTargets[(std::rand() / (static_cast<double>(RAND_MAX)+1.0)) * mTargets.size()];
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// we could use a map here for faster lookup
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FindGroupByRecIndex visitor(randomRecIndex);
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getParent(0)->accept(visitor);
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if (!visitor.mFound)
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{
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std::cerr << "Error: Can't find emitter node" << randomRecIndex << std::endl;
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return;
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}
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osg::NodePath path = visitor.mFoundPath;
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path.erase(path.begin());
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emitterToPs = osg::computeLocalToWorld(path) * emitterToPs;
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}
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emitterToPs.orthoNormalize(emitterToPs);
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for (int i=0; i<n; ++i)
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{
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osgParticle::Particle* P = getParticleSystem()->createParticle(0);
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if (P)
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{
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mPlacer->place(P);
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mShooter->shoot(P);
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P->transformPositionVelocity(emitterToPs);
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}
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}
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}
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FindGroupByRecIndex::FindGroupByRecIndex(int recIndex)
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: osg::NodeVisitor(TRAVERSE_ALL_CHILDREN)
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, mFound(NULL)
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, mRecIndex(recIndex)
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{
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}
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void FindGroupByRecIndex::apply(osg::Node &node)
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{
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applyNode(node);
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}
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void FindGroupByRecIndex::apply(osg::MatrixTransform &node)
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{
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applyNode(node);
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}
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void FindGroupByRecIndex::apply(osg::Geometry &node)
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{
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applyNode(node);
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}
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void FindGroupByRecIndex::applyNode(osg::Node &searchNode)
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{
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if (searchNode.getUserDataContainer() && searchNode.getUserDataContainer()->getNumUserObjects())
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{
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NodeUserData* holder = dynamic_cast<NodeUserData*>(searchNode.getUserDataContainer()->getUserObject(0));
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if (holder && holder->mIndex == mRecIndex)
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{
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osg::Group* group = searchNode.asGroup();
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if (!group)
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group = searchNode.getParent(0);
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mFound = group;
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mFoundPath = getNodePath();
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return;
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}
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}
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traverse(searchNode);
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}
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PlanarCollider::PlanarCollider(const Nif::NiPlanarCollider *collider)
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: mBounceFactor(collider->mBounceFactor)
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, mPlane(-collider->mPlaneNormal, collider->mPlaneDistance)
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{
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}
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PlanarCollider::PlanarCollider()
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: mBounceFactor(0.f)
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{
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}
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PlanarCollider::PlanarCollider(const PlanarCollider ©, const osg::CopyOp ©op)
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: osgParticle::Operator(copy, copyop)
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, mBounceFactor(copy.mBounceFactor)
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, mPlane(copy.mPlane)
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, mPlaneInParticleSpace(copy.mPlaneInParticleSpace)
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{
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}
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void PlanarCollider::beginOperate(osgParticle::Program *program)
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{
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mPlaneInParticleSpace = mPlane;
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if (program->getReferenceFrame() == osgParticle::ParticleProcessor::ABSOLUTE_RF)
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mPlaneInParticleSpace.transform(program->getLocalToWorldMatrix());
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}
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void PlanarCollider::operate(osgParticle::Particle *particle, double dt)
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{
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float dotproduct = particle->getVelocity() * mPlaneInParticleSpace.getNormal();
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if (dotproduct > 0)
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{
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osg::BoundingSphere bs(particle->getPosition(), 0.f);
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if (mPlaneInParticleSpace.intersect(bs) == 1)
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{
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osg::Vec3 reflectedVelocity = particle->getVelocity() - mPlaneInParticleSpace.getNormal() * (2 * dotproduct);
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reflectedVelocity *= mBounceFactor;
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particle->setVelocity(reflectedVelocity);
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}
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}
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}
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SphericalCollider::SphericalCollider(const Nif::NiSphericalCollider* collider)
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: mBounceFactor(collider->mBounceFactor),
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mSphere(collider->mCenter, collider->mRadius)
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{
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}
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SphericalCollider::SphericalCollider()
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: mBounceFactor(1.0f)
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{
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}
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SphericalCollider::SphericalCollider(const SphericalCollider& copy, const osg::CopyOp& copyop)
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: osgParticle::Operator(copy, copyop)
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, mBounceFactor(copy.mBounceFactor)
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, mSphere(copy.mSphere)
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, mSphereInParticleSpace(copy.mSphereInParticleSpace)
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{
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}
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void SphericalCollider::beginOperate(osgParticle::Program* program)
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{
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mSphereInParticleSpace = mSphere;
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if (program->getReferenceFrame() == osgParticle::ParticleProcessor::ABSOLUTE_RF)
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mSphereInParticleSpace.center() = program->transformLocalToWorld(mSphereInParticleSpace.center());
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}
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void SphericalCollider::operate(osgParticle::Particle* particle, double dt)
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{
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osg::Vec3f cent = (particle->getPosition() - mSphereInParticleSpace.center()); // vector from sphere center to particle
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bool insideSphere = cent.length2() <= mSphereInParticleSpace.radius2();
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if (insideSphere
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|| (cent * particle->getVelocity() < 0.0f)) // if outside, make sure the particle is flying towards the sphere
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{
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// Collision test (finding point of contact) is performed by solving a quadratic equation:
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// ||vec(cent) + vec(vel)*k|| = R /^2
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// k^2 + 2*k*(vec(cent)*vec(vel))/||vec(vel)||^2 + (||vec(cent)||^2 - R^2)/||vec(vel)||^2 = 0
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float b = -(cent * particle->getVelocity()) / particle->getVelocity().length2();
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osg::Vec3f u = cent + particle->getVelocity() * b;
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if (insideSphere
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|| (u.length2() < mSphereInParticleSpace.radius2()))
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{
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float d = (mSphereInParticleSpace.radius2() - u.length2()) / particle->getVelocity().length2();
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float k = insideSphere ? (std::sqrt(d) + b) : (b - std::sqrt(d));
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if (k < dt)
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{
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// collision detected; reflect off the tangent plane
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osg::Vec3f contact = particle->getPosition() + particle->getVelocity() * k;
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osg::Vec3 normal = (contact - mSphereInParticleSpace.center());
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normal.normalize();
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float dotproduct = particle->getVelocity() * normal;
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osg::Vec3 reflectedVelocity = particle->getVelocity() - normal * (2 * dotproduct);
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reflectedVelocity *= mBounceFactor;
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particle->setVelocity(reflectedVelocity);
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}
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}
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}
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}
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}
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