/usr/include/trilinos/MueLu_RefMaxwell_def.hpp is in libtrilinos-muelu-dev 12.10.1-3.
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//
// ***********************************************************************
//
// MueLu: A package for multigrid based preconditioning
// Copyright 2012 Sandia Corporation
//
// Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation,
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//
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// 3. Neither the name of the Corporation nor the names of the
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY SANDIA CORPORATION "AS IS" AND ANY
// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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// Questions? Contact
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// @HEADER
#ifndef MUELU_REFMAXWELL_DEF_HPP
#define MUELU_REFMAXWELL_DEF_HPP
#include "MueLu_ConfigDefs.hpp"
#include "Xpetra_MatrixMatrix.hpp"
#if defined(HAVE_MUELU_TPETRA) && defined(HAVE_MUELU_IFPACK2)
#include "MueLu_RefMaxwell_decl.hpp"
#include "MueLu_Utilities.hpp"
#include "MueLu_Monitor.hpp"
#include "MueLu_MLParameterListInterpreter.hpp"
#include "MueLu_ParameterListInterpreter.hpp"
#include "MueLu_HierarchyManager.hpp"
namespace MueLu {
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
Teuchos::RCP<const Tpetra::Map<LocalOrdinal,GlobalOrdinal,Node> > RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::getDomainMap() const {
return Xpetra::toTpetraNonZero(SM_Matrix_->getDomainMap());
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
Teuchos::RCP<const Tpetra::Map<LocalOrdinal,GlobalOrdinal,Node> > RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::getRangeMap() const {
return Xpetra::toTpetraNonZero(SM_Matrix_->getRangeMap());
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::setParameters(Teuchos::ParameterList& list) {
disable_addon_ = list.get("refmaxwell: disable add-on",true);
mode_ = list.get("refmaxwell: mode","additive");
if(list.isSublist("refmaxwell: 11list"))
precList11_ = list.sublist("refmaxwell: 11list");
if(list.isSublist("refmaxwell: 22list"))
precList22_ = list.sublist("refmaxwell: 22list");
std::string ref("smoother:");
std::string replace("coarse:");
for(Teuchos::ParameterList::ConstIterator i=list.begin(); i !=list.end(); i++) {
const std::string & pname = list.name(i);
if(pname.find(ref)!=std::string::npos) {
smootherList_.setEntry(pname,list.entry(i));
std::string coarsename(pname);
coarsename.replace((size_t)0,(size_t)ref.length(),replace);
}
}
if(list.isSublist("smoother: params")) {
smootherList_.set("coarse: params",list.sublist("smoother: params"));
}
smootherList_.set("max levels",1);
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::compute() {
Teuchos::FancyOStream out(Teuchos::rcpFromRef(std::cout));
out.setOutputToRootOnly(0);
out.setShowProcRank(true);
// clean rows associated with boundary conditions
findDirichletRows(SM_Matrix_,BCrows_);
findDirichletCols(D0_Matrix_,BCrows_,BCcols_);
D0_Matrix_->resumeFill();
Apply_BCsToMatrixRows(D0_Matrix_,BCrows_);
Apply_BCsToMatrixCols(D0_Matrix_,BCcols_);
D0_Matrix_->fillComplete(D0_Matrix_->getDomainMap(),D0_Matrix_->getRangeMap());
//D0_Matrix_->describe(out,Teuchos::VERB_EXTREME);
// Form TMT_Matrix
Teuchos::RCP<XMat> C1 = MatrixFactory::Build(SM_Matrix_->getRowMap(),0);
TMT_Matrix_=MatrixFactory::Build(D0_Matrix_->getDomainMap(),0);
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*SM_Matrix_,false,*D0_Matrix_,false,*C1,true,true);
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*D0_Matrix_,true,*C1,false,*TMT_Matrix_,true,true);
TMT_Matrix_->resumeFill();
Remove_Zeroed_Rows(TMT_Matrix_,1.0e-16);
TMT_Matrix_->SetFixedBlockSize(1);
//TMT_Matrix_->describe(out,Teuchos::VERB_EXTREME);
// build nullspace if necessary
if(Nullspace_ != Teuchos::null) {
// no need to do anything - nullspace is built
}
else if(Nullspace_ == Teuchos::null && Coords_ != Teuchos::null) {
Nullspace_ = MultiVectorFactory::Build(SM_Matrix_->getRowMap(),Coords_->getNumVectors());
D0_Matrix_->apply(*Coords_,*Nullspace_);
}
else {
std::cerr << "MueLu::RefMaxwell::compute(): either the nullspace or the nodal coordinates must be provided." << std::endl;
}
// build special prolongator for (1,1)-block
if(P11_==Teuchos::null) {
buildProlongator();
}
// build coarse grid operator for (1,1)-block
formCoarseMatrix();
// build fine grid operator for (2,2)-block, D0* M1 D0
Teuchos::RCP<XMat> C = MatrixFactory::Build(M1_Matrix_->getRowMap(),0);
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*M1_Matrix_,false,*D0_Matrix_,false,*C,true,true);
A22_=MatrixFactory::Build(D0_Matrix_->getDomainMap(),0);
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*D0_Matrix_,true,*C,false,*A22_,true,true);
A22_->resumeFill();
Remove_Zeroed_Rows(A22_,1.0e-16);
A22_->SetFixedBlockSize(1);
// Use HierarchyManagers to build 11 & 22 Hierarchies
typedef MueLu::HierarchyManager<SC,LO,GO,NO> HierarchyManager;
RCP<HierarchyManager> Manager11, Manager22, ManagerSmoother;
std::string syntaxStr = "parameterlist: syntax";
if (parameterList_.isParameter(syntaxStr) && parameterList_.get<std::string>(syntaxStr) == "ml") {
parameterList_.remove(syntaxStr);
Manager11 = rcp(new MLParameterListInterpreter<SC,LO,GO,NO>(precList11_));
Manager22 = rcp(new MLParameterListInterpreter<SC,LO,GO,NO>(precList22_));
ManagerSmoother = rcp(new MLParameterListInterpreter<SC,LO,GO,NO>(smootherList_));
} else {
Manager11 = rcp(new ParameterListInterpreter <SC,LO,GO,NO>(precList11_,A11_->getDomainMap()->getComm()));
Manager22 = rcp(new ParameterListInterpreter <SC,LO,GO,NO>(precList22_,A22_->getDomainMap()->getComm()));
ManagerSmoother = rcp(new ParameterListInterpreter<SC,LO,GO,NO>(smootherList_,SM_Matrix_->getDomainMap()->getComm()));
}
Hierarchy11_=Manager11->CreateHierarchy();
Hierarchy11_->setlib(Xpetra::UseTpetra);
Hierarchy11_->GetLevel(0)->Set("A", A11_);
Manager11->SetupHierarchy(*Hierarchy11_);
Hierarchy22_=Manager22->CreateHierarchy();
Hierarchy22_->setlib(Xpetra::UseTpetra);
Hierarchy22_->GetLevel(0)->Set("A", A22_);
Manager22->SetupHierarchy(*Hierarchy22_);
// build ifpack2 preconditioners for pre and post smoothing
HierarchySmoother_=ManagerSmoother->CreateHierarchy();
HierarchySmoother_->setlib(Xpetra::UseTpetra);
HierarchySmoother_->GetLevel(0)->Set("A", SM_Matrix_);
ManagerSmoother->SetupHierarchy(*HierarchySmoother_);
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::buildProlongator() {
Teuchos::FancyOStream out(Teuchos::rcpFromRef(std::cout));
out.setOutputToRootOnly(0);
out.setShowProcRank(true);
// build prolongator: algorithm 1 in the reference paper
// First, aggregate nodal matrix by creating a 2-level hierarchy
Teuchos::RCP<Hierarchy> auxHierarchy
= Teuchos::rcp( new Hierarchy(TMT_Matrix_) );
Teuchos::RCP<FactoryManager> auxManager
= Teuchos::rcp( new FactoryManager );
Teuchos::RCP<TentativePFactory> TentPfact
= Teuchos::rcp( new TentativePFactory );
Teuchos::RCP<SaPFactory> Pfact
= Teuchos::rcp( new SaPFactory );
Teuchos::RCP<UncoupledAggregationFactory> Aggfact
= Teuchos::rcp( new UncoupledAggregationFactory() );
Teuchos::ParameterList params;
params.set("sa: damping factor",0.0);
Pfact -> SetParameterList(params);
auxManager -> SetFactory("P", Pfact);
auxManager -> SetFactory("Ptent", TentPfact);
auxManager -> SetFactory("Aggregates", Aggfact);
auxManager -> SetFactory("Smoother", Teuchos::null);
auxManager -> SetFactory("CoarseSolver", Teuchos::null);
auxHierarchy -> Keep("P", Pfact.get());
auxHierarchy -> SetMaxCoarseSize(1);
auxHierarchy -> Setup(*auxManager, 0, 2);
// pull out tentative P
Teuchos::RCP<Level> Level1 = auxHierarchy -> GetLevel(1);
Teuchos::RCP<XMat> P = Level1 -> Get< Teuchos::RCP<XMat> >("P",Pfact.get());
// make weighting matrix
Teuchos::RCP<XMat> D0_Matrix_Abs=MatrixFactory2::BuildCopy(D0_Matrix_);
D0_Matrix_Abs -> resumeFill();
D0_Matrix_Abs -> setAllToScalar((Scalar)0.5);
Apply_BCsToMatrixRows(D0_Matrix_Abs,BCrows_);
Apply_BCsToMatrixCols(D0_Matrix_Abs,BCcols_);
D0_Matrix_Abs -> fillComplete(D0_Matrix_->getDomainMap(),D0_Matrix_->getRangeMap());
Teuchos::RCP<XMat> Ptent = MatrixFactory::Build(D0_Matrix_Abs->getRowMap(),0);
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*D0_Matrix_Abs,false,*P,false,*Ptent,true,true);
// put in entries to P11
size_t dim = Nullspace_->getNumVectors();
size_t numLocalRows = SM_Matrix_->getNodeNumRows();
Teuchos::RCP<XMap> BlockColMap
= Xpetra::MapFactory<LocalOrdinal,GlobalOrdinal,Node>::Build(Ptent->getColMap(),dim);
P11_ = Teuchos::rcp(new XCrsWrap(Ptent->getRowMap(),BlockColMap,0,Xpetra::StaticProfile));
std::vector< Teuchos::ArrayRCP<const Scalar> > nullspace(dim);
for(size_t i=0; i<dim; i++) {
Teuchos::ArrayRCP<const Scalar> datavec = Nullspace_->getData(i);
nullspace[i]=datavec;
}
size_t nnz=0;
std::vector<size_t> rowPtrs;
std::vector<LocalOrdinal> blockCols;
std::vector<Scalar> blockVals;
for(size_t i=0; i<numLocalRows; i++) {
rowPtrs.push_back(nnz);
Teuchos::ArrayView<const LocalOrdinal> localCols;
Teuchos::ArrayView<const Scalar> localVals;
Ptent->getLocalRowView(i,localCols,localVals);
size_t numCols = localCols.size();
for(size_t j=0; j<numCols; j++) {
for(size_t k=0; k<dim; k++) {
blockCols.push_back(localCols[j]*dim+k);
blockVals.push_back(localVals[j]*nullspace[k][i]);
nnz++;
}
}
}
rowPtrs.push_back(nnz);
ArrayRCP<size_t> rcpRowPtr;
ArrayRCP<LocalOrdinal> rcpColumns;
ArrayRCP<Scalar> rcpValues;
RCP<XCRS> TP11 = rcp_dynamic_cast<XCrsWrap>(P11_)->getCrsMatrix();
TP11->allocateAllValues(nnz, rcpRowPtr, rcpColumns, rcpValues);
ArrayView<size_t> rows = rcpRowPtr();
ArrayView<LocalOrdinal> columns = rcpColumns();
ArrayView<Scalar> values = rcpValues();
for (size_t ii = 0; ii < rowPtrs.size(); ii++) rows[ii] = rowPtrs[ii];
for (size_t ii = 0; ii < blockCols.size(); ii++) columns[ii] = blockCols[ii];
for (size_t ii = 0; ii < blockVals.size(); ii++) values[ii] = blockVals[ii];
TP11->setAllValues(rcpRowPtr, rcpColumns, rcpValues);
Teuchos::RCP<XMap> blockCoarseMap
= Xpetra::MapFactory<LocalOrdinal,GlobalOrdinal,Node>::Build(Ptent->getDomainMap(),dim);
TP11->expertStaticFillComplete(blockCoarseMap,SM_Matrix_->getDomainMap());
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::formCoarseMatrix() {
// coarse matrix for P11* (M1 + D1* M2 D1) P11
Teuchos::RCP<XMat> C = MatrixFactory::Build(SM_Matrix_->getRowMap(),0);
Teuchos::RCP<XMat> Matrix1 = MatrixFactory::Build(P11_->getDomainMap(),0);
// construct (M1 + D1* M2 D1) P11
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*SM_Matrix_,false,*P11_,false,*C,true,true);
// construct P11* (M1 + D1* M2 D1) P11
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*P11_,true,*C,false,*Matrix1,true,true);
if(disable_addon_==true) {
// if add-on is not chosen
A11_=Matrix1;
}
else {
// catch a failure
TEUCHOS_TEST_FOR_EXCEPTION(M0inv_Matrix_==Teuchos::null,std::invalid_argument,
"MueLu::RefMaxwell::formCoarseMatrix(): Inverse of "
"lumped mass matrix required for add-on (i.e. M0inv_Matrix is null)");
// coarse matrix for add-on, i.e P11* (M1 D0 M0inv D0* M1) P11
Teuchos::RCP<XMat> Zaux = MatrixFactory::Build(M1_Matrix_->getRowMap(),0);
Teuchos::RCP<XMat> Z = MatrixFactory::Build(D0_Matrix_->getDomainMap(),0);
Teuchos::RCP<XMat> C2 = MatrixFactory::Build(M0inv_Matrix_->getRowMap(),0);
// construct M1 P11
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*M1_Matrix_,false,*P11_,false,*Zaux,true,true);
// construct Z = D0* M1 P11
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*D0_Matrix_,true,*Zaux,false,*Z,true,true);
// construct M0inv Z
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*M0inv_Matrix_,false,*Z,false,*C2,true,true);
// construct Z* M0inv Z
Teuchos::RCP<XMat> Matrix2 = MatrixFactory::Build(Z->getDomainMap(),0);
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::Multiply(*Z,true,*C2,false,*Matrix2,true,true);
// add matrices together
RCP<Teuchos::FancyOStream> out = Teuchos::fancyOStream(Teuchos::rcpFromRef(std::cout));
Xpetra::MatrixMatrix<Scalar,LocalOrdinal,GlobalOrdinal,Node>::TwoMatrixAdd(*Matrix1,false,(Scalar)1.0,*Matrix2,false,(Scalar)1.0,A11_,*out);
A11_->fillComplete();
}
// set fixed block size for vector nodal matrix
size_t dim = Nullspace_->getNumVectors();
A11_->SetFixedBlockSize(dim);
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::resetMatrix(Teuchos::RCP<TCRS> SM_Matrix_new) {
// convert Tpetra matrices to Xpetra
Teuchos::RCP<XCRS> SM_tmp = Teuchos::rcp( new XTCRS(SM_Matrix_new) );
SM_Matrix_ = Teuchos::rcp( new XCrsWrap(SM_tmp) );
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::applyInverseAdditive(const XTMV& RHS, XTMV& X) const {
// compute residuals
RCP<XMV> residual = Utilities::Residual(*SM_Matrix_, X, RHS);
RCP<XMV> P11res = MultiVectorFactory::Build(P11_->getDomainMap(),X.getNumVectors());
RCP<XMV> P11x = MultiVectorFactory::Build(P11_->getDomainMap(),X.getNumVectors());
RCP<XMV> D0res = MultiVectorFactory::Build(D0_Matrix_->getDomainMap(),X.getNumVectors());
RCP<XMV> D0x = MultiVectorFactory::Build(D0_Matrix_->getDomainMap(),X.getNumVectors());
P11_->apply(*residual,*P11res,Teuchos::TRANS);
D0_Matrix_->apply(*residual,*D0res,Teuchos::TRANS);
// block diagonal preconditioner on 2x2 (V-cycle for diagonal blocks)
Hierarchy11_->Iterate(*P11res, *P11x, 1, true);
Hierarchy22_->Iterate(*D0res, *D0x, 1, true);
// update current solution
P11_->apply(*P11x,*residual,Teuchos::NO_TRANS);
D0_Matrix_->apply(*D0x,*residual,Teuchos::NO_TRANS,(Scalar)1.0,(Scalar)1.0);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::applyInverse121(const XTMV& RHS, XTMV& X) const {
RCP<XMV> P11res = MultiVectorFactory::Build(P11_->getDomainMap(),X.getNumVectors());
RCP<XMV> P11x = MultiVectorFactory::Build(P11_->getDomainMap(),X.getNumVectors());
RCP<XMV> D0res = MultiVectorFactory::Build(D0_Matrix_->getDomainMap(),X.getNumVectors());
RCP<XMV> D0x = MultiVectorFactory::Build(D0_Matrix_->getDomainMap(),X.getNumVectors());
// precondition (1,1)-block
RCP<XMV> residual = Utilities::Residual(*SM_Matrix_, X, RHS);
P11_->apply(*residual,*P11res,Teuchos::TRANS);
Hierarchy11_->Iterate(*P11res, *P11x, 1, true);
P11_->apply(*P11x,*residual,Teuchos::NO_TRANS);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
// precondition (2,2)-block
residual = Utilities::Residual(*SM_Matrix_, X, RHS);
D0_Matrix_->apply(*residual,*D0res,Teuchos::TRANS);
Hierarchy22_->Iterate(*D0res, *D0x, 1, true);
D0_Matrix_->apply(*D0x,*residual,Teuchos::NO_TRANS);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
// precondition (1,1)-block
residual = Utilities::Residual(*SM_Matrix_, X, RHS);
P11_->apply(*residual,*P11res,Teuchos::TRANS);
Hierarchy11_->Iterate(*P11res, *P11x, 1, true);
P11_->apply(*P11x,*residual,Teuchos::NO_TRANS);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::applyInverse212(const XTMV& RHS, XTMV& X) const {
RCP<XMV> P11res = MultiVectorFactory::Build(P11_->getDomainMap(),X.getNumVectors());
RCP<XMV> P11x = MultiVectorFactory::Build(P11_->getDomainMap(),X.getNumVectors());
RCP<XMV> D0res = MultiVectorFactory::Build(D0_Matrix_->getDomainMap(),X.getNumVectors());
RCP<XMV> D0x = MultiVectorFactory::Build(D0_Matrix_->getDomainMap(),X.getNumVectors());
// precondition (2,2)-block
RCP<XMV> residual = Utilities::Residual(*SM_Matrix_, X, RHS);
D0_Matrix_->apply(*residual,*D0res,Teuchos::TRANS);
Hierarchy22_->Iterate(*D0res, *D0x, 1, true);
D0_Matrix_->apply(*D0x,*residual,Teuchos::NO_TRANS);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
// precondition (1,1)-block
residual = Utilities::Residual(*SM_Matrix_, X, RHS);
P11_->apply(*residual,*P11res,Teuchos::TRANS);
Hierarchy11_->Iterate(*P11res, *P11x, 1, true);
P11_->apply(*P11x,*residual,Teuchos::NO_TRANS);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
// precondition (2,2)-block
residual = Utilities::Residual(*SM_Matrix_, X, RHS);
D0_Matrix_->apply(*residual,*D0res,Teuchos::TRANS);
Hierarchy22_->Iterate(*D0res, *D0x, 1, true);
D0_Matrix_->apply(*D0x,*residual,Teuchos::NO_TRANS);
X.update((Scalar) 1.0, *residual, (Scalar) 1.0);
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::apply(const Tpetra::MultiVector<Scalar,LocalOrdinal,GlobalOrdinal,Node>& X,
Tpetra::MultiVector<Scalar,LocalOrdinal,GlobalOrdinal,Node>& Y,
Teuchos::ETransp mode, Scalar alpha, Scalar beta) const {
try {
TMV& temp_x = const_cast<TMV &>(X);
const XTMV tX(rcpFromRef(temp_x));
XTMV tY(rcpFromRef(Y));
tY.putScalar(Teuchos::ScalarTraits<Scalar>::zero());
// apply pre-smoothing
HierarchySmoother_->Iterate(tX,tY,1);
// do solve for the 2x2 block system
if(mode_=="additive")
applyInverseAdditive(tX,tY);
else if(mode_=="121")
applyInverse121(tX,tY);
else if(mode_=="212")
applyInverse212(tX,tY);
else
applyInverseAdditive(tX,tY);
// apply post-smoothing
HierarchySmoother_->Iterate(tX,tY,1);
} catch (std::exception& e) {
//FIXME add message and rethrow
std::cerr << "Caught an exception in MueLu::RefMaxwell::ApplyInverse():" << std::endl
<< e.what() << std::endl;
}
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
bool RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::hasTransposeApply() const {
return false;
}
template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
void RefMaxwell<Scalar,LocalOrdinal,GlobalOrdinal,Node>::
initialize(const Teuchos::RCP<TCRS> & D0_Matrix,
const Teuchos::RCP<TCRS> & M0inv_Matrix,
const Teuchos::RCP<TCRS> & M1_Matrix,
const Teuchos::RCP<TMV> & Nullspace,
const Teuchos::RCP<TMV> & Coords,
Teuchos::ParameterList& List)
{
// some pre-conditions
TEUCHOS_ASSERT(D0_Matrix!=Teuchos::null);
TEUCHOS_ASSERT(M1_Matrix!=Teuchos::null);
Hierarchy11_ = Teuchos::null;
Hierarchy22_ = Teuchos::null;
HierarchySmoother_ = Teuchos::null;
parameterList_ = List;
disable_addon_ = false;
mode_ = "additive";
// set parameters
setParameters(List);
// convert Tpetra matrices to Xpetra
Teuchos::RCP<XCRS> D0_tmp = Teuchos::rcp( new XTCRS(D0_Matrix) );
D0_Matrix_ = Teuchos::rcp( new XCrsWrap(D0_tmp) );
if(M0inv_Matrix != Teuchos::null) {
Teuchos::RCP<XCRS> M0inv_tmp = Teuchos::rcp( new XTCRS(M0inv_Matrix) );
M0inv_Matrix_ = Teuchos::rcp( new XCrsWrap(M0inv_tmp) );
}
Teuchos::RCP<XCRS> M1_tmp = Teuchos::rcp( new XTCRS(M1_Matrix) );
M1_Matrix_ = Teuchos::rcp( new XCrsWrap(M1_tmp) );
// convert Tpetra MultiVector to Xpetra
if(Coords != Teuchos::null)
Coords_ = Xpetra::toXpetra(Coords);
if(Nullspace != Teuchos::null)
Nullspace_ = Xpetra::toXpetra(Nullspace);
}
} // namespace
#endif //ifdef HAVE_MUELU_TPETRA
#define MUELU_REFMAXWELL_SHORT
#endif //ifdef MUELU_REFMAXWELL_DEF_HPP
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