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#include "Ifpack_ConfigDefs.h"

#include "Ifpack_SingletonFilter.h"

#include "Epetra_ConfigDefs.h"

#include "Epetra_RowMatrix.h"

#include "Epetra_Comm.h"

#include "Epetra_Map.h"

#include "Epetra_MultiVector.h"

#include "Epetra_Vector.h"

#include "Epetra_Import.h"


//==============================================================================


Ifpack_SingletonFilter::Ifpack_SingletonFilter(const Teuchos::RefCountPtr<Epetra_RowMatrix>& Matrix) :

  A_(Matrix),

  NumSingletons_(0),

  NumRows_(0),

  NumRowsA_(0),

  MaxNumEntries_(0),

  MaxNumEntriesA_(0),

  NumNonzeros_(0)

{

  using std::cerr;

  using std::endl;


  // use this filter only on serial matrices

  if (A_->Comm().NumProc() != 1) {

    cerr << "Ifpack_SingletonFilter can be used with Comm().NumProc() == 1" << endl;

    cerr << "only. This class is a tool for Ifpack_AdditiveSchwarz," << endl;

    cerr << "and it is not meant to be used otherwise." << endl;

    exit(EXIT_FAILURE);

  }


  if ((A_->NumMyRows() != A_->NumGlobalRows64()) ||

     (A_->NumMyRows() != A_->NumMyCols()))

    IFPACK_CHK_ERRV(-1);


  NumRowsA_ = (A_->NumMyRows());

  MaxNumEntriesA_ = A_->MaxNumEntries();


  Indices_.resize(MaxNumEntriesA_);

  Values_.resize(MaxNumEntriesA_);

  Reorder_.resize(A_->NumMyRows());


  for (int i = 0 ; i < NumRowsA_ ; ++i)

    Reorder_[i] = -1;


  // first check how may singletons I do have

  for (int i = 0 ; i < NumRowsA_ ; ++i) {

    int Nnz;

    IFPACK_CHK_ERRV(A_->ExtractMyRowCopy(i,MaxNumEntriesA_,Nnz,

                                        &Values_[0], &Indices_[0]));

    if (Nnz != 1) {

      Reorder_[i] = NumRows_++;

    }

    else {

      NumSingletons_++;

    }

  }


  InvReorder_.resize(NumRows_);

  for (int i = 0 ; i < NumRowsA_ ; ++i) {

    if (Reorder_[i] < 0)

      continue;

    InvReorder_[Reorder_[i]] = i;

  }


  NumEntries_.resize(NumRows_);

  SingletonIndex_.resize(NumSingletons_);


  // now compute the nonzeros per row

  int count = 0;

  for (int i = 0 ; i < A_->NumMyRows() ; ++i) {


    int Nnz;

    IFPACK_CHK_ERRV(A_->ExtractMyRowCopy(i,MaxNumEntriesA_,Nnz,

                                          &Values_[0], &Indices_[0]));

    int ii = Reorder_[i];

    if (ii >= 0) {

      assert (Nnz != 1);


      NumEntries_[ii] = Nnz;

      NumNonzeros_ += Nnz;

      if (Nnz > MaxNumEntries_)

        MaxNumEntries_ = Nnz;

    }

    else {

      SingletonIndex_[count] = i;

      count++;

    }

  }


#if !defined(EPETRA_NO_32BIT_GLOBAL_INDICES) || !defined(EPETRA_NO_64BIT_GLOBAL_INDICES)

  Map_ = Teuchos::rcp( new Epetra_Map(NumRows_,0,Comm()) );

#endif


  // and finish up with the diagonal entry

  Diagonal_ = Teuchos::rcp( new Epetra_Vector(*Map_) );


  Epetra_Vector Diagonal(A_->Map());

  A_->ExtractDiagonalCopy(Diagonal);

  for (int i = 0 ; i < NumRows_ ; ++i) {

    int ii = InvReorder_[i];

    (*Diagonal_)[i] = Diagonal[ii];

  }


}


//==============================================================================


int Ifpack_SingletonFilter::

ExtractMyRowCopy(int MyRow, int Length, int & NumEntries,

                 double *Values, int * Indices) const

{

  int Nnz;


  if (Length < NumEntries_[MyRow])

    IFPACK_CHK_ERR(-1);


  int Row = InvReorder_[MyRow];

  IFPACK_CHK_ERR(A_->ExtractMyRowCopy(Row,MaxNumEntriesA_,Nnz,

                                     &Values_[0],&Indices_[0]));

  NumEntries = 0;

  for (int i = 0 ; i < Nnz ; ++i) {

    int ii = Reorder_[Indices_[i]];

    if ( ii >= 0) {

      Indices[NumEntries] = ii;

      Values[NumEntries] = Values_[i];

      NumEntries++;

    }

  }

  return(0);

}


//==============================================================================


int Ifpack_SingletonFilter::

ExtractDiagonalCopy(Epetra_Vector & Diagonal) const

{

  Diagonal = *Diagonal_;

  return(0);

}


//==============================================================================


int Ifpack_SingletonFilter::

Multiply(bool TransA, const Epetra_MultiVector& X,

         Epetra_MultiVector& Y) const

{


  int NumVectors = X.NumVectors();

  if (NumVectors != Y.NumVectors())

    IFPACK_CHK_ERR(-1);


  Y.PutScalar(0.0);


  std::vector<int> Indices(MaxNumEntries_);

  std::vector<double> Values(MaxNumEntries_);


  // cycle over all rows of the original matrix

  for (int i = 0 ; i < A_->NumMyRows() ; ++i) {


    if (Reorder_[i] < 0)

      continue; // skip singleton rows


    int Nnz;

    A_->ExtractMyRowCopy(i,MaxNumEntriesA_,Nnz,

                     &Values[0], &Indices[0]);

    if (!TransA) {

      // no transpose first

      for (int j = 0 ; j < NumVectors ; ++j) {

        for (int k = 0 ; k < Nnz ; ++k) {

          if (Reorder_[i] >= 0)

            Y[j][i] += Values[k] * X[j][Reorder_[Indices[k]]];

        }

      }

    }

    else {

      // transpose here

      for (int j = 0 ; j < NumVectors ; ++j) {

        for (int k = 0 ; k < Nnz ; ++k) {

          if (Reorder_[i] >= 0)

            Y[j][Reorder_[Indices[k]]] += Values[k] * X[j][i];

        }

      }

    }

  }


  return(0);

}


//==============================================================================


int Ifpack_SingletonFilter::

Solve(bool /* Upper */, bool /* Trans */, bool /* UnitDiagonal */,

      const Epetra_MultiVector& /* X */, Epetra_MultiVector& /* Y */) const

{

  return(-1);

}


//==============================================================================


int Ifpack_SingletonFilter::

Apply(const Epetra_MultiVector& X, Epetra_MultiVector& Y) const

{

  IFPACK_CHK_ERR(Multiply(false,X,Y));

  return(0);

}


//==============================================================================


int Ifpack_SingletonFilter::

ApplyInverse(const Epetra_MultiVector& /* X */, Epetra_MultiVector& /* Y */) const

{

  return(-1); // NOT IMPLEMENTED AT THIS STAGE

}


//==============================================================================


int Ifpack_SingletonFilter::

SolveSingletons(const Epetra_MultiVector& RHS,

                Epetra_MultiVector& LHS)

{

  for (int i = 0 ; i < NumSingletons_ ; ++i) {

    int ii = SingletonIndex_[i];

    // get the diagonal value for the singleton

    int Nnz;

    A_->ExtractMyRowCopy(ii,MaxNumEntriesA_,Nnz,

                        &Values_[0], &Indices_[0]);

    for (int j = 0 ; j < Nnz ; ++j) {

      if (Indices_[j] == ii) {

        for (int k = 0 ; k < LHS.NumVectors() ; ++k)

          LHS[k][ii] = RHS[k][ii] / Values_[j];

      }

    }

  }


  return(0);

}


//==============================================================================


int Ifpack_SingletonFilter::

CreateReducedRHS(const Epetra_MultiVector& LHS,

                 const Epetra_MultiVector& RHS,

                 Epetra_MultiVector& ReducedRHS)

{

  int NumVectors = LHS.NumVectors();


  for (int i = 0 ; i < NumRows_ ; ++i)

    for (int k = 0 ; k < NumVectors ; ++k)

      ReducedRHS[k][i] = RHS[k][InvReorder_[i]];


  for (int i = 0 ; i < NumRows_ ; ++i) {

    int ii = InvReorder_[i];

    int Nnz;

    IFPACK_CHK_ERR(A_->ExtractMyRowCopy(ii,MaxNumEntriesA_,Nnz,

                                        &Values_[0], &Indices_[0]));


    for (int j = 0 ; j < Nnz ; ++j) {

      if (Reorder_[Indices_[j]] == -1) {

        for (int k = 0 ; k < NumVectors ; ++k)

          ReducedRHS[k][i] -= Values_[j] * LHS[k][Indices_[j]];

      }

    }

  }

  return(0);

}


//==============================================================================


int Ifpack_SingletonFilter::

UpdateLHS(const Epetra_MultiVector& ReducedLHS,

          Epetra_MultiVector& LHS)

{

  for (int i = 0 ; i < NumRows_ ; ++i)

    for (int k = 0 ; k < LHS.NumVectors() ; ++k)

      LHS[k][InvReorder_[i]] = ReducedLHS[k][i];


  return(0);

}


Epetra_Comm.h

Epetra_ConfigDefs.h

Epetra_Import.h

Epetra_Map.h

Epetra_MultiVector.h

Epetra_RowMatrix.h

Epetra_Vector.h

Ifpack_ConfigDefs.h

IFPACK_CHK_ERR
#define IFPACK_CHK_ERR(ifpack_err)
Definition Ifpack_ConfigDefs.h:125

IFPACK_CHK_ERRV
#define IFPACK_CHK_ERRV(ifpack_err)
Definition Ifpack_ConfigDefs.h:133

Ifpack_SingletonFilter.h

RHS
#define RHS(a)
Definition MatGenFD.c:60

Epetra_Map

Epetra_MultiVector

Epetra_MultiVector::NumVectors
int NumVectors() const

Epetra_MultiVector::PutScalar
int PutScalar(double ScalarConstant)

Epetra_Vector

Ifpack_SingletonFilter::NumEntries_
std::vector< int > NumEntries_
Definition Ifpack_SingletonFilter.h:285

Ifpack_SingletonFilter::Indices_
std::vector< int > Indices_
Used in ExtractMyRowCopy, to avoid allocation each time.
Definition Ifpack_SingletonFilter.h:273

Ifpack_SingletonFilter::Ifpack_SingletonFilter
Ifpack_SingletonFilter(const Teuchos::RefCountPtr< Epetra_RowMatrix > &Matrix)
Constructor.
Definition Ifpack_SingletonFilter.cpp:54

Ifpack_SingletonFilter::Multiply
virtual int Multiply(bool TransA, const Epetra_MultiVector &X, Epetra_MultiVector &Y) const
Definition Ifpack_SingletonFilter.cpp:184

Ifpack_SingletonFilter::Map_
Teuchos::RefCountPtr< Epetra_Map > Map_
Definition Ifpack_SingletonFilter.h:292

Ifpack_SingletonFilter::InvReorder_
std::vector< int > InvReorder_
Definition Ifpack_SingletonFilter.h:283

Ifpack_SingletonFilter::SingletonIndex_
std::vector< int > SingletonIndex_
Definition Ifpack_SingletonFilter.h:280

Ifpack_SingletonFilter::NumNonzeros_
int NumNonzeros_
Definition Ifpack_SingletonFilter.h:291

Ifpack_SingletonFilter::ExtractMyRowCopy
virtual int ExtractMyRowCopy(int MyRow, int Length, int &NumEntries, double *Values, int *Indices) const
Definition Ifpack_SingletonFilter.cpp:151

Ifpack_SingletonFilter::MaxNumEntries_
int MaxNumEntries_
Definition Ifpack_SingletonFilter.h:289

Ifpack_SingletonFilter::Reorder_
std::vector< int > Reorder_
Definition Ifpack_SingletonFilter.h:282

Ifpack_SingletonFilter::NumSingletons_
int NumSingletons_
Definition Ifpack_SingletonFilter.h:279

Ifpack_SingletonFilter::SolveSingletons
int SolveSingletons(const Epetra_MultiVector &RHS, Epetra_MultiVector &LHS)
Definition Ifpack_SingletonFilter.cpp:254

Ifpack_SingletonFilter::NumRowsA_
int NumRowsA_
Definition Ifpack_SingletonFilter.h:288

Ifpack_SingletonFilter::UpdateLHS
int UpdateLHS(const Epetra_MultiVector &ReducedLHS, Epetra_MultiVector &LHS)
Definition Ifpack_SingletonFilter.cpp:304

Ifpack_SingletonFilter::A_
Teuchos::RefCountPtr< Epetra_RowMatrix > A_
Pointer to the matrix to be preconditioned.
Definition Ifpack_SingletonFilter.h:270

Ifpack_SingletonFilter::MaxNumEntriesA_
int MaxNumEntriesA_
Definition Ifpack_SingletonFilter.h:290

Ifpack_SingletonFilter::ApplyInverse
virtual int ApplyInverse(const Epetra_MultiVector &X, Epetra_MultiVector &Y) const
Definition Ifpack_SingletonFilter.cpp:247

Ifpack_SingletonFilter::Apply
virtual int Apply(const Epetra_MultiVector &X, Epetra_MultiVector &Y) const
Definition Ifpack_SingletonFilter.cpp:239

Ifpack_SingletonFilter::NumRows_
int NumRows_
Definition Ifpack_SingletonFilter.h:287

Ifpack_SingletonFilter::CreateReducedRHS
int CreateReducedRHS(const Epetra_MultiVector &LHS, const Epetra_MultiVector &RHS, Epetra_MultiVector &ReducedRHS)
Definition Ifpack_SingletonFilter.cpp:276

Ifpack_SingletonFilter::Diagonal_
Teuchos::RefCountPtr< Epetra_Vector > Diagonal_
Definition Ifpack_SingletonFilter.h:294

Ifpack_SingletonFilter::Solve
virtual int Solve(bool Upper, bool Trans, bool UnitDiagonal, const Epetra_MultiVector &X, Epetra_MultiVector &Y) const
Definition Ifpack_SingletonFilter.cpp:231

Ifpack_SingletonFilter::ExtractDiagonalCopy
virtual int ExtractDiagonalCopy(Epetra_Vector &Diagonal) const
Definition Ifpack_SingletonFilter.cpp:176

Ifpack_SingletonFilter::Values_
std::vector< double > Values_
Used in ExtractMyRowCopy, to avoid allocation each time.
Definition Ifpack_SingletonFilter.h:275

Ifpack_SingletonFilter::Comm
const Epetra_Comm & Comm() const
Definition Ifpack_SingletonFilter.h:233

NumVectors
const int NumVectors
Definition performance.cpp:71