libplb-dev 1.5~r1+repack1-2build2 / usr / include / palabos / multiGrid / gridRefinementDynamics.hh

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/* This file is part of the Palabos library.
 *
 * Copyright (C) 2011-2015 FlowKit Sarl
 * Route d'Oron 2
 * 1010 Lausanne, Switzerland
 * E-mail contact: contact@flowkit.com
 *
 * The most recent release of Palabos can be downloaded at 
 * <http://www.palabos.org/>
 *
 * The library Palabos is free software: you can redistribute it and/or
 * modify it under the terms of the GNU Affero General Public License as
 * published by the Free Software Foundation, either version 3 of the
 * License, or (at your option) any later version.
 *
 * The library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU Affero General Public License for more details.
 *
 * You should have received a copy of the GNU Affero General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

/* Main author: Daniel Lagrava
 **/

/** \file
 * Dynamics classes used to implement grid refinement -- generic implementation.
 */
#ifndef GRID_REFINEMENT_DYNAMICS_HH
#define GRID_REFINEMENT_DYNAMICS_HH

#include "multiGrid/gridRefinementDynamics.h"

namespace plb {

/* *************** Class FineGridBoundaryDynamics *************************** */

template<typename T, template<typename U> class Descriptor>
int FineGridBoundaryDynamics<T,Descriptor>::id =
    meta::registerGeneralDynamics<T,Descriptor,FineGridBoundaryDynamics<T,Descriptor> >("Boundary_FineGrid");

template<typename T, template<typename U> class Descriptor>
FineGridBoundaryDynamics<T,Descriptor>::FineGridBoundaryDynamics (
        Dynamics<T,Descriptor>* baseDynamics_,
        TimeCounter const& timeCounter_,
        plint numTimeSteps_,
        plint orderOfDecomposition_)
    : BoundaryCompositeDynamics<T,Descriptor>(baseDynamics_),
      timeCounter(timeCounter_),
      numTimeSteps(numTimeSteps_),
      orderOfDecomposition(orderOfDecomposition_),
      decomposedValuesT0(),
      decomposedValuesT1()
{ }

template<typename T, template<typename U> class Descriptor>
FineGridBoundaryDynamics<T,Descriptor>::FineGridBoundaryDynamics(HierarchicUnserializer& unserializer)
    : BoundaryCompositeDynamics<T,Descriptor>(0, false),
      timeCounter(defaultTimeCounter),
      numTimeSteps(0),
      orderOfDecomposition(0),
      decomposedValuesT0(),
      decomposedValuesT1()
{
    unserialize(unserializer);
}

template<typename T, template<typename U> class Descriptor>
void FineGridBoundaryDynamics<T,Descriptor>::serialize(HierarchicSerializer& serializer) const
{
    serializer.addValue(timeCounter);
    serializer.addValue(numTimeSteps);
    serializer.addValue(orderOfDecomposition);
    serializer.addValue(decomposedValuesT0.size());
    serializer.addValues(decomposedValuesT0);
    serializer.addValue(decomposedValuesT1.size());
    serializer.addValues(decomposedValuesT1);
    BoundaryCompositeDynamics<T,Descriptor>::serialize(serializer);
}

template<typename T, template<typename U> class Descriptor>
void FineGridBoundaryDynamics<T,Descriptor>::unserialize(HierarchicUnserializer& unserializer)
{
    unserializer.readValue(timeCounter);
    unserializer.readValue(numTimeSteps);
    unserializer.readValue(orderOfDecomposition);

    typename std::vector<T>::size_type t0Size, t1Size;
    unserializer.readValue(t0Size);
    decomposedValuesT0.resize(t0Size);
    unserializer.readValues(decomposedValuesT0);

    unserializer.readValue(t1Size);
    decomposedValuesT1.resize(t1Size);
    unserializer.readValues(decomposedValuesT1);

    BoundaryCompositeDynamics<T,Descriptor>::unserialize(unserializer);
}

template<typename T, template<typename U> class Descriptor>
FineGridBoundaryDynamics<T,Descriptor>*
    FineGridBoundaryDynamics<T,Descriptor>::clone() const
{
    return new FineGridBoundaryDynamics<T,Descriptor>(*this);
}

/** A FineGridBoundaryDynamics cannot be composed: the end-user needs
 *  access to the original object, to manipulate internal data, 
 *  the variables decomposedValuesT0 and decomposedValuesT1.
 */
template<typename T, template<typename U> class Descriptor>
bool FineGridBoundaryDynamics<T,Descriptor>::isComposeable() const
{
    return false;
}

template<typename T, template<typename U> class Descriptor>
int FineGridBoundaryDynamics<T,Descriptor>::getId() const {
    return id;
}

template<typename T, template<typename U> class Descriptor>
void FineGridBoundaryDynamics<T,Descriptor>::completePopulations(Cell<T,Descriptor>& cell) const
{
    // Get current iteration time from the lattice
    size_t relativeTime = timeCounter.getTime()%numTimeSteps;
    
    // At time t0, simply recompose the corresponding decomposed values ...
    if (relativeTime==0) {
        if ((plint)decomposedValuesT0.size() !=
                    cell.getDynamics().numDecomposedVariables(orderOfDecomposition)){
        }
        PLB_ASSERT( (plint)decomposedValuesT0.size() ==
                    cell.getDynamics().numDecomposedVariables(orderOfDecomposition) );
        cell.getDynamics().recompose(cell, decomposedValuesT0, orderOfDecomposition);
    }
    // ... and at all other times, interpolate value between t0 and t1
    else {
        PLB_ASSERT( (plint)decomposedValuesT0.size() ==
                    cell.getDynamics().numDecomposedVariables(orderOfDecomposition) );
        PLB_ASSERT( (plint)decomposedValuesT1.size() ==
                    cell.getDynamics().numDecomposedVariables(orderOfDecomposition) );
        T timeFraction = (T)relativeTime/(T)numTimeSteps;
        std::vector<T> decomposedValues(decomposedValuesT0.size());
        for (pluint iVal=0; iVal<decomposedValues.size(); ++iVal) {
            decomposedValues[iVal] =
                fd::linearInterpolate(decomposedValuesT0[iVal], decomposedValuesT1[iVal], timeFraction);
        }
        // recompose everything in the cell 
        cell.getDynamics().recompose(cell, decomposedValues, orderOfDecomposition);
    }
}

template<typename T, template<typename U> class Descriptor>
std::vector<T>& FineGridBoundaryDynamics<T,Descriptor>::getDecomposedValues(plint whichTime)
{
    PLB_PRECONDITION( whichTime==0 || whichTime==1);
    return whichTime==0 ? decomposedValuesT0 : decomposedValuesT1;
}

template<typename T, template<typename U> class Descriptor>


std::vector<T> const& FineGridBoundaryDynamics<T,Descriptor>::getDecomposedValues(plint whichTime) const
{
    PLB_PRECONDITION( whichTime==0 || whichTime==1);
    return whichTime==0 ? decomposedValuesT0 : decomposedValuesT1;
}

}  // namespace plb

#endif  // GRID_REFINEMENT_DYNAMICS_HH

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