Program Listing for File SimulationDataPCISPH.cpp
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#include "SimulationDataPCISPH.h"
#include "SPlisHSPlasH/SPHKernels.h"
#include "SPlisHSPlasH/Simulation.h"
#include <iostream>
#include "SPlisHSPlasH/TimeManager.h"
#include "Utilities/Logger.h"
using namespace SPH;
SimulationDataPCISPH::SimulationDataPCISPH()
{
}
SimulationDataPCISPH::~SimulationDataPCISPH(void)
{
cleanup();
}
void SimulationDataPCISPH::init()
{
Simulation *sim = Simulation::getCurrent();
const unsigned int nModels = sim->numberOfFluidModels();
m_predX.resize(nModels);
m_predV.resize(nModels);
m_densityAdv.resize(nModels);
m_pressure.resize(nModels);
m_pressureAccel.resize(nModels);
m_pcisph_factor.resize(nModels);
for (unsigned int i = 0; i < nModels; i++)
{
FluidModel *fm = sim->getFluidModel(i);
m_predX[i].resize(fm->numParticles(), Vector3r::Zero());
m_predV[i].resize(fm->numParticles(), Vector3r::Zero());
m_densityAdv[i].resize(fm->numParticles(), 0.0);
m_pressure[i].resize(fm->numParticles(), 0.0);
m_pressureAccel[i].resize(fm->numParticles(), Vector3r::Zero());
}
LOG_INFO << "Initialize PCISPH scaling factor";
for (unsigned int fluidModelIndex = 0; fluidModelIndex < nModels; fluidModelIndex++)
{
FluidModel *model = sim->getFluidModel(fluidModelIndex);
m_pcisph_factor[fluidModelIndex] = 0.0;
// Find prototype particle
// => particle with max. fluid neighbors
const Real density0 = model->getDensity0();
Vector3r sumGradW = Vector3r::Zero();
Real sumGradW2 = 0.0;
const Real supportRadius = sim->getSupportRadius();
const Real particleRadius = sim->getParticleRadius();
const Real diam = static_cast<Real>(2.0) * particleRadius;
const Vector3r xi(0,0,0);
// use a regular sampling around (0,0,0)
if (sim->is2DSimulation())
{
Vector3r xj = { -supportRadius, -supportRadius, 0.0 };
while (xj[0] <= supportRadius)
{
while (xj[1] <= supportRadius)
{
// check if xj is in the support of xi
if ((xi - xj).squaredNorm() < supportRadius*supportRadius)
{
const Vector3r gradW = sim->gradW(xi - xj);
sumGradW += gradW;
sumGradW2 += gradW.squaredNorm();
}
xj[1] += diam;
}
xj[0] += diam;
xj[1] = -supportRadius;
}
}
else
{
Vector3r xj = { -supportRadius, -supportRadius, -supportRadius };
while (xj[0] <= supportRadius)
{
while (xj[1] <= supportRadius)
{
while (xj[2] <= supportRadius)
{
// check if xj is in the support of xi
if ((xi - xj).squaredNorm() < supportRadius*supportRadius)
{
const Vector3r gradW = sim->gradW(xi - xj);
sumGradW += gradW;
sumGradW2 += gradW.squaredNorm();
}
xj[2] += diam;
}
xj[1] += diam;
xj[2] = -supportRadius;
}
xj[0] += diam;
xj[1] = -supportRadius;
xj[2] = -supportRadius;
}
}
const Real beta = static_cast<Real>(2.0) * model->getVolume(0)*model->getVolume(0);
m_pcisph_factor[fluidModelIndex] = static_cast<Real>(1.0) / (beta * (sumGradW.squaredNorm() + sumGradW2));
}
}
void SimulationDataPCISPH::cleanup()
{
m_predX.clear();
m_predV.clear();
m_densityAdv.clear();
m_pressure.clear();
m_pressureAccel.clear();
}
void SimulationDataPCISPH::reset()
{
}
void SimulationDataPCISPH::performNeighborhoodSearchSort()
{
Simulation *sim = Simulation::getCurrent();
const unsigned int nModels = sim->numberOfFluidModels();
for (unsigned int i = 0; i < nModels; i++)
{
FluidModel *fm = sim->getFluidModel(i);
const unsigned int numPart = fm->numActiveParticles();
if (numPart != 0)
{
auto const& d = sim->getNeighborhoodSearch()->point_set(fm->getPointSetIndex());
d.sort_field(&m_predX[i][0]);
d.sort_field(&m_predV[i][0]);
d.sort_field(&m_densityAdv[i][0]);
d.sort_field(&m_pressure[i][0]);
d.sort_field(&m_pressureAccel[i][0]);
}
}
}
void SimulationDataPCISPH::emittedParticles(FluidModel *model, const unsigned int startIndex)
{
// initialize values for new particles
const unsigned int fluidModelIndex = model->getPointSetIndex();
for (unsigned int j = startIndex; j < model->numActiveParticles(); j++)
{
m_predX[fluidModelIndex][j] = model->getPosition(j);
m_predV[fluidModelIndex][j] = model->getVelocity(j);
}
}