testAdaptiveChebSymFMM.cpp 8.84 KB
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// ===================================================================================
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// Copyright ScalFmm 2016 INRIA, Olivier Coulaud, Bérenger Bramas,
// Matthias Messner olivier.coulaud@inria.fr, berenger.bramas@inria.fr
// This software is a computer program whose purpose is to compute the
// FMM.
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//
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// This software is governed by the CeCILL-C and LGPL licenses and
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// abiding by the rules of distribution of free software.
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// An extension to the license is given to allow static linking of scalfmm
// inside a proprietary application (no matter its license).
// See the main license file for more details.
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//
// This program 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
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// GNU General Public and CeCILL-C Licenses for more details.
// "http://www.cecill.info".
// "http://www.gnu.org/licenses".
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// ===================================================================================

// ==== CMAKE =====
// @FUSE_BLAS
// ================
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// Keep in private GIT
// @SCALFMM_PRIVATE
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#include <iostream>
#include <cstdio>

#include "Utils/FParameters.hpp"
#include "Utils/FTic.hpp"

#include "Containers/FOctree.hpp"
#include "Components/FSimpleLeaf.hpp"

#include "Utils/FPoint.hpp"

#include "Files/FFmaGenericLoader.hpp"
#include "Files/FRandomLoader.hpp"

#include "Components/FBasicKernels.hpp"
#include "Components/FSimpleIndexedLeaf.hpp"
#include "Kernels/P2P/FP2PParticleContainerIndexed.hpp"

#include "Kernels/Interpolation/FInterpMatrixKernel.hpp"
#include "Kernels/Chebyshev/FChebCell.hpp"

#include "Adaptive/FAdaptiveCell.hpp"
#include "Adaptive/FAdaptiveKernelWrapper.hpp"
#include "Adaptive/FAbstractAdaptiveKernel.hpp"
#include "Adaptive/FAdaptChebSymKernel.hpp"

#include "Kernels/Interpolation/FInterpMatrixKernel.hpp"
#include "Kernels/Chebyshev/FChebCell.hpp"
#include "Adaptive/FAdaptTools.hpp"

#include "Adaptive/FAdaptivePrintKernel.hpp"

#include "Core/FFmmAlgorithm.hpp"
#include "Utils/FParameterNames.hpp"

/** This program show an example of use of the fmm basic algo
 * it also check that each particles is impacted each other particles
 */


// Simply create particles and try the kernels
int main(int argc, char ** argv){
    //
    const FParameterNames LocalOptionMinMultipoleThreshod {{"-sM"}," s_min^M threshold for Multipole (l+1)^2 for Spherical harmonic."};
    const FParameterNames LocalOptionMinLocalThreshod {{"-SL"}," s_min^L threshold for Local  (l+1)^2 for Spherical harmonics."};

    FHelpDescribeAndExit(argc, argv,
            "Test Adaptive kernel and compare it with the direct computation.",
            FParameterDefinitions::OctreeHeight,FParameterDefinitions::NbThreads,
            FParameterDefinitions::OctreeSubHeight, FParameterDefinitions::InputFile,
            LocalOptionMinMultipoleThreshod,LocalOptionMinLocalThreshod);

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    typedef double FReal;
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    const unsigned int P = 5 ;
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    typedef FChebCell<FReal,P>                                        CellClass;
    typedef FP2PParticleContainerIndexed<FReal>            ContainerClass;
    typedef FSimpleLeaf<FReal, ContainerClass>    LeafClass;
    typedef FInterpMatrixKernelR<FReal>                               MatrixKernelClass;
    typedef FAdaptiveChebSymKernel<FReal,CellClass,ContainerClass,MatrixKernelClass,P> KernelClass;
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    typedef FAdaptiveCell< CellClass, ContainerClass >                                        CellWrapperClass;
    typedef FAdaptiveKernelWrapper< KernelClass, CellClass, ContainerClass >   KernelWrapperClass;
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    typedef FOctree<FReal, CellWrapperClass, ContainerClass , LeafClass >                  OctreeClass;
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    typedef FFmmAlgorithm<OctreeClass, CellWrapperClass, ContainerClass, KernelWrapperClass, LeafClass >     FmmClass;

    FTic counter;

    //////////////////////////////////////////////////////////////////////////////////
    const int sminM    = FParameters::getValue(argc,argv,LocalOptionMinMultipoleThreshod.options, P*P*P);
    const int sminL     = FParameters::getValue(argc,argv,LocalOptionMinLocalThreshod.options, P*P*P);
    const std::string fileName(FParameters::getStr(argc,argv,FParameterDefinitions::InputFile.options,   "../Data/noDistprolate50.out.fma"));
    const unsigned int TreeHeight      = FParameters::getValue(argc, argv, FParameterDefinitions::OctreeHeight.options, 3);
    const unsigned int SubTreeHeight = FParameters::getValue(argc, argv, FParameterDefinitions::OctreeSubHeight.options, 2);

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    FFmaGenericLoader<FReal> loader(fileName);
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    const FSize NbPart = loader.getNumberOfParticles() ;
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    //////////////////////////////////////////////////////////////////////////////////

    OctreeClass tree(TreeHeight, SubTreeHeight, loader.getBoxWidth(), loader.getCenterOfBox());

    //////////////////////////////////////////////////////////////////////////////////

    std::cout << "Creating & Inserting " << NbPart << " particles ..." << std::endl;
    std::cout << "\tHeight : " << TreeHeight << " \t sub-height : " << SubTreeHeight << std::endl;
    std::cout << "         criteria SM:  "<< sminM     <<std::endl
              << "         criteria SL:  "<< sminL     <<std::endl <<std::endl;

    counter.tic();

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    FmaRWParticle<FReal, 8,8>* const particles = new FmaRWParticle<FReal, 8,8>[NbPart];
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    loader.fillParticle(particles,NbPart);

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    for(FSize idxPart = 0 ; idxPart < NbPart; ++idxPart){
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        const FPoint<FReal> PP(particles[idxPart].getPosition() ) ;
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        tree.insert(PP, idxPart, particles[idxPart].getPhysicalValue());
    }

    counter.tac();
    std::cout << "Done  " << "(@Creating and Inserting Particles = " << counter.elapsed() << " s)." << std::endl;

    //////////////////////////////////////////////////////////////////////////////////
    //////////////////////////////////////////////////////////////////////////////////

    std::cout << "Working on particles ..." << std::endl;

    counter.tic();

    const MatrixKernelClass MatrixKernel;
    KernelWrapperClass kernels(TreeHeight, loader.getBoxWidth(), loader.getCenterOfBox(),&MatrixKernel,sminM,sminL);            // FTestKernels FBasicKernels
    FmmClass algo(&tree,&kernels);  //FFmmAlgorithm FFmmAlgorithmThread
    algo.execute();

    counter.tac();
    std::cout << "Done  " << "(@Algorithm = " << counter.elapsed() << " s)." << std::endl;

    /////////////////////////////////////////////////////////////////////////////////////////////////
    // Compute direct energy
    /////////////////////////////////////////////////////////////////////////////////////////////////
    FReal energyD = 0.0 ;
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    for(FSize idx = 0 ; idx < loader.getNumberOfParticles()  ; ++idx){
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        energyD +=  particles[idx].getPotential()*particles[idx].getPhysicalValue() ;
    }

    /////////////////////////////////////////////////////////////////////////////////////////////////
    // Compare
    /////////////////////////////////////////////////////////////////////////////////////////////////
    {
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        FMath::FAccurater<FReal> potentialDiff;
        FMath::FAccurater<FReal> fx, fy, fz;
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        FReal energy= 0.0;
        { // Check that each particle has been summed with all other

            //    std::cout << "indexPartOrig || DIRECT V fx || FMM V fx" << std::endl;

            tree.forEachCellLeaf([&](CellWrapperClass* cell, LeafClass* leaf){
                const FReal*const potentials        = leaf->getTargets()->getPotentials();
                const FReal*const physicalValues = leaf->getTargets()->getPhysicalValues();
                const FReal*const forcesX            = leaf->getTargets()->getForcesX();
                const FReal*const forcesY            = leaf->getTargets()->getForcesY();
                const FReal*const forcesZ            = leaf->getTargets()->getForcesZ();
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                const FSize nbParticlesInLeaf           = leaf->getTargets()->getNbParticles();
                const FVector<FSize>& indexes = leaf->getTargets()->getIndexes();
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                for(FSize idxPart = 0 ; idxPart < nbParticlesInLeaf ; ++idxPart){
                    const FSize indexPartOrig = indexes[idxPart];
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                    potentialDiff.add(particles[indexPartOrig].getPotential(),potentials[idxPart]);
                    fx.add(particles[indexPartOrig].getForces()[0],forcesX[idxPart]);
                    fy.add(particles[indexPartOrig].getForces()[1],forcesY[idxPart]);
                    fz.add(particles[indexPartOrig].getForces()[2],forcesZ[idxPart]);
                    energy   += potentials[idxPart]*physicalValues[idxPart];

                }
            });
        }

        // Print for information
        std::cout << "Energy [relative L2 error] "  << FMath::Abs(energy-energyD) /energyD << std::endl;
        std::cout << "Potential " << potentialDiff << std::endl;
        std::cout << "Fx " << fx << std::endl;
        std::cout << "Fy " << fy << std::endl;
        std::cout << "Fz " << fz << std::endl;
    }

    delete[] particles;

    return 0;
}