mirror of
https://github.com/OPM/opm-simulators.git
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331 lines
11 KiB
C++
331 lines
11 KiB
C++
/*
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Copyright 2024 Equinor ASA
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This file is part of the Open Porous Media project (OPM).
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OPM is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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OPM is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with OPM. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <config.h>
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#define BOOST_TEST_MODULE PreconditionerTest
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#define BOOST_TEST_NO_MAIN
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#include <boost/test/unit_test.hpp>
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#include <opm/simulators/linalg/PreconditionerFactory.hpp>
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#include <opm/simulators/linalg/PropertyTree.hpp>
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#include <opm/simulators/linalg/getQuasiImpesWeights.hpp>
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#include <opm/simulators/linalg/WellOperators.hpp>
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#include <dune/common/parallel/mpihelper.hh>
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#include <dune/common/fmatrix.hh>
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#include <dune/common/unused.hh>
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#include <dune/common/parallel/indexset.hh>
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#include <dune/common/parallel/plocalindex.hh>
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#include <dune/common/parallel/communication.hh>
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#include <dune/istl/bcrsmatrix.hh>
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#include <dune/istl/owneroverlapcopy.hh>
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#include <dune/istl/schwarz.hh>
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class MPIError {
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public:
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/** @brief Constructor. */
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MPIError(std::string s, int e) : errorstring(s), errorcode(e){}
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/** @brief The error string. */
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std::string errorstring;
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/** @brief The mpi error code. */
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int errorcode;
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};
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void MPI_err_handler(MPI_Comm *, int *err_code, ...){
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char *err_string=new char[MPI_MAX_ERROR_STRING];
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int err_length;
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MPI_Error_string(*err_code, err_string, &err_length);
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std::string s(err_string, err_length);
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std::cerr << "An MPI Error ocurred:"<<std::endl<<s<<std::endl;
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delete[] err_string;
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throw MPIError(s, *err_code);
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}
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typedef Dune::OwnerOverlapCopyAttributeSet GridAttributes;
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typedef GridAttributes::AttributeSet GridFlag;
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typedef Dune::ParallelLocalIndex<GridFlag> LocalIndex;
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template<class M, class G, class L, int n>
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void setupPattern(int N, M& mat, Dune::ParallelIndexSet<G,L,n>& indices, int overlapStart, int overlapEnd,
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int start, int end);
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template<class M>
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void fillValues(int N, M& mat, int overlapStart, int overlapEnd, int start, int end);
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template<class M, class G, class L, class C, int n>
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M setupAnisotropic2d(int N, Dune::ParallelIndexSet<G,L,n>& indices,
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const C& p, int *nout, typename M::block_type::value_type eps=1.0);
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template<class M, class G, class L, int s>
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void setupPattern(int N, M& mat, Dune::ParallelIndexSet<G,L,s>& indices, int overlapStart, int overlapEnd,
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int start, int end)
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{
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int n = overlapEnd - overlapStart;
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typename M::CreateIterator iter = mat.createbegin();
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indices.beginResize();
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for(int j=0; j < N; j++)
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for(int i=overlapStart; i < overlapEnd; i++, ++iter) {
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int global = j*N+i;
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GridFlag flag = GridAttributes::owner;
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bool isPublic = false;
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if((i<start && i > 0) || (i>= end && i < N-1))
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flag=GridAttributes::copy;
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if(i<start+1 || i>= end-1) {
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isPublic = true;
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indices.add(global, LocalIndex(iter.index(), flag, isPublic));
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}
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iter.insert(iter.index());
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// i direction
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if(i > overlapStart )
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// We have a left neighbour
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iter.insert(iter.index()-1);
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if(i < overlapEnd-1)
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// We have a rigt neighbour
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iter.insert(iter.index()+1);
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// j direction
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// Overlap is a dirichlet border, discard neighbours
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if(flag != GridAttributes::copy) {
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if(j>0)
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// lower neighbour
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iter.insert(iter.index()-n);
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if(j<N-1)
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// upper neighbour
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iter.insert(iter.index()+n);
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}
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}
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indices.endResize();
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}
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template<class M, class T>
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void fillValues([[maybe_unused]] int N, M& mat, int overlapStart, int overlapEnd, int start, int end, T eps)
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{
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typedef typename M::block_type Block;
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Block dval(0), bone(0), bmone(0), beps(0);
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for(typename Block::RowIterator b = dval.begin(); b != dval.end(); ++b)
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b->operator[](b.index())=2.0+2.0*eps;
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for(typename Block::RowIterator b=bone.begin(); b != bone.end(); ++b)
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b->operator[](b.index())=1.0;
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for(typename Block::RowIterator b=bmone.begin(); b != bmone.end(); ++b)
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b->operator[](b.index())=-1.0;
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for(typename Block::RowIterator b=beps.begin(); b != beps.end(); ++b)
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b->operator[](b.index())=-eps;
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int n = overlapEnd-overlapStart;
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typedef typename M::ColIterator ColIterator;
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typedef typename M::RowIterator RowIterator;
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for (RowIterator i = mat.begin(); i != mat.end(); ++i) {
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// calculate coordinate
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int y = i.index() / n;
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int x = overlapStart + i.index() - y * n;
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ColIterator endi = (*i).end();
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if(x<start || x >= end) { // || x==0 || x==N-1 || y==0 || y==N-1){
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// overlap node is dirichlet border
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ColIterator j = (*i).begin();
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for(; j.index() < i.index(); ++j)
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*j=0;
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*j = bone;
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for(++j; j != endi; ++j)
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*j=0;
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}else{
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for(ColIterator j = (*i).begin(); j != endi; ++j)
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if(j.index() == i.index())
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*j=dval;
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else if(j.index()+1==i.index() || j.index()-1==i.index())
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*j=beps;
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else
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*j=bmone;
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}
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}
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}
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template<class V, class G, class L, int s>
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void setBoundary(V& lhs, V& rhs, const G& n, Dune::ParallelIndexSet<G,L,s>& indices)
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{
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typedef typename Dune::ParallelIndexSet<G,L,s>::const_iterator Iter;
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for(Iter i=indices.begin(); i != indices.end(); ++i) {
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G x = i->global()/n;
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G y = i->global()%n;
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if(x==0 || y ==0 || x==n-1 || y==n-1) {
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//double h = 1.0 / ((double) (n-1));
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lhs[i->local()]=rhs[i->local()]=0; //((double)x)*((double)y)*h*h;
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}
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}
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}
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template<class V, class G>
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void setBoundary(V& lhs, V& rhs, const G& N)
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{
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typedef typename V::block_type Block;
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typedef typename Block::value_type T;
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for(int j=0; j < N; ++j)
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for(int i=0; i < N; i++)
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if(i==0 || j ==0 || i==N-1 || j==N-1) {
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T h = 1.0 / ((double) (N-1));
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T x, y;
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if(i==N-1)
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x=1;
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else
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x = ((T) i)*h;
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if(j==N-1)
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y = 1;
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else
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y = ((T) j)*h;
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lhs[j*N+i]=rhs[j*N+i]=0; //x*y;
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}
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}
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template<class M, class G, class L, class C, int s>
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M setupAnisotropic2d(int N, Dune::ParallelIndexSet<G,L,s>& indices, const C& p, int *nout, typename M::block_type::value_type eps)
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{
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int procs=p.size(), rank=p.rank();
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typedef M BCRSMat;
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// calculate size of local matrix in the distributed direction
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int start, end, overlapStart, overlapEnd;
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int n = N/procs; // number of unknowns per process
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int bigger = N%procs; // number of process with n+1 unknows
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// Compute owner region
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if(rank<bigger) {
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start = rank*(n+1);
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end = start+(n+1);
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}else{
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start = bigger*(n+1) + (rank-bigger) * n;
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end = start+n;
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}
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// Compute overlap region
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if(start>0)
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overlapStart = start - 1;
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else
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overlapStart = start;
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if(end<N)
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overlapEnd = end + 1;
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else
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overlapEnd = end;
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int noKnown = overlapEnd-overlapStart;
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*nout = noKnown;
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BCRSMat mat(noKnown*N, noKnown*N, noKnown*N*5, BCRSMat::row_wise);
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setupPattern(N, mat, indices, overlapStart, overlapEnd, start, end);
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fillValues(N, mat, overlapStart, overlapEnd, start, end, eps);
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//Dune::printmatrix(std::cout,mat,"aniso 2d","row",9,1); //das hier auf zwei Prozessen ausgeben
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return mat;
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}
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int main(int argc, char** argv)
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{
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Dune::MPIHelper::instance(argc, argv);
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constexpr int BS=2, N=100;
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using MatrixBlock = Dune::FieldMatrix<double,BS,BS>;
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using BCRSMat = Dune::BCRSMatrix<MatrixBlock>;
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using VectorBlock = Dune::FieldVector<double,BS>;
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using Vector = Dune::BlockVector<VectorBlock>;
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using Communication = Dune::OwnerOverlapCopyCommunication<int>;
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using Operator = Dune::OverlappingSchwarzOperator<BCRSMat,Vector,Vector,Communication>;
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const auto& ccomm = Dune::MPIHelper::getCommunication();
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Communication comm(ccomm);
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int n=0;
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BCRSMat mat = setupAnisotropic2d<BCRSMat>(N, comm.indexSet(), comm.communicator(), &n, 1);
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comm.remoteIndices().template rebuild<false>();
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Vector b(mat.N()), x(mat.M());
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b=10;
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x=100;
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setBoundary(x, b, N, comm.indexSet());
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Operator op(mat, comm);
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Dune::OverlappingSchwarzScalarProduct<Vector,Communication> sp(comm);
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using namespace std::string_literals;
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Opm::PropertyTree prm;
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prm.put("type", "Jac"s);
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std::function<Vector()> weights = [&mat]() {
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return Opm::Amg::getQuasiImpesWeights<BCRSMat, Vector>(mat, 0, false);
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};
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auto fullPreconditioner = Opm::PreconditionerFactory<Operator, Communication>::create(op, prm, weights, comm);
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Dune::BiCGSTABSolver<Vector> amgBiCGSTAB(op, sp, *fullPreconditioner, 10e-8, 300, (ccomm.rank()==0) ? 2 : 0);
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using PreconditionerOperatorType = Opm::GhostLastMatrixAdapter<BCRSMat, Vector, Vector, Communication>;
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auto ghostOperator = std::make_unique<PreconditionerOperatorType>(mat, comm);
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auto ghostPreconditioner = Opm::PreconditionerFactory<PreconditionerOperatorType, Communication>::create(*ghostOperator, prm, weights, comm);
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Dune::BiCGSTABSolver<Vector> amgGhostBiCGSTAB(op, sp, *ghostPreconditioner, 10e-8, 300, (ccomm.rank()==0) ? 2 : 0);
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auto x2 = x;
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auto b2 = b;
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Dune::InverseOperatorResult r;
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Dune::Timer timerFull;
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amgBiCGSTAB.apply(x,b,r);
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auto timeFull = timerFull.elapsed();
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Dune::InverseOperatorResult r2;
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Dune::Timer timerGhost;
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amgGhostBiCGSTAB.apply(x2,b2,r2);
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auto timeGhost = timerGhost.elapsed();
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for (size_t i = 0; i < x.size(); i++)
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for (int j = 0; j < BS; j++)
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if (std::abs(x[i][j] - x2[i][j]) > 0.001)
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return 1;
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if (r.iterations != r2.iterations)
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return 1;
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if (ccomm.rank() == 0) {
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std::cout << "Full preconditioner took " << timeFull << std::endl;
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std::cout << "Ghost preconditioner took " << timeGhost << std::endl;
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}
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return 0;
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} |