/usr/include/trilinos/Trilinos_Util

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#ifndef __TRILINOS_UTILS_GALLERY_H
#define __TRILINOS_UTILS_GALLERY_H

class Epetra_Comm;
class Epetra_Map;
class Epetra_BlockMap;
class Vector;
#include "Epetra_ConfigDefs.h"
#include "Epetra_CrsMatrix.h"
#include "Epetra_VbrMatrix.h"
class Epetra_Export;
class Epetra_LinearProblem;
#include <string>
#include <vector>
#include "Trilinos_Util_CommandLineParser.h"

namespace Trilinos_Util {

class CrsMatrixGallery
{
public:

  //@{ \name Constructors/Destructor.
  //! Triutils_Gallery Constructor.
  /*! Creates a Triutils_Gallery instance.

  The first parameter is the name of the matrix. We refer to the Trilinos
  Tutorial for a detailed description of available matrices.

  \note The matrix name can be empty (""), and set later using, for example,
  Set("matrix_name","laplace_2d");

  An example of program using this class is reported below.

  \code
int main(int argc, char *argv[])
{

#ifdef HAVE_MPI
  MPI_Init(&argc,&argv);
  Epetra_MpiComm Comm (MPI_COMM_WORLD);
#else
  Epetra_SerialComm Comm;
#endif

  // create an Epetra matrix reading an H/B matrix
  Trilinos_Util_CrsMatrixGallery Gallery("hb", Comm);

  // set the name of the matrix
  Gallery.Set("matrix name", "bcsstk14.rsa");

  Epetra_CrsMatrix * A;
  Epetra_Vector * ExactSolution;
  Epetra_Vector * RHS;
  Epetra_Vector * StartingSolution;

  // at this point the matrix is read from file
  A = Gallery.GetMatrix();
  ExactSolution = Gallery.GetExactSolution();

  // at this point the RHS is allocated and filled
  RHS = Gallery.GetRHS();
  StartingSolution = Gallery.GetStartingSolution();

  // create linear problem
  Epetra_LinearProblem Problem(A,StartingSolution,RHS);
  // create AztecOO instance
  AztecOO Solver(Problem);

  Solver.SetAztecOption( AZ_precond, AZ_dom_decomp );
  Solver.Iterate(1000,1E-9);

  // compute residual
  double residual;

  Gallery.ComputeResidual(&residual);
  if( Comm.MyPID()==0 ) cout << "||b-Ax||_2 = " << residual << endl;

  Gallery.ComputeDiffBetweenStartingAndExactSolutions(&residual);
  if( Comm.MyPID()==0 ) cout << "||x_exact - x||_2 = " << residual << endl;

 #ifdef HAVE_MPI
  MPI_Finalize() ;
#endif

return 0 ;
  }
  \endcode

  Class CommandLineParser can be used as well. In this case, one may
  decide to use the following:
  \code
  Trilinos_Util::CommandLineParser CLP(argc,argv);
  // set a problem with no matrix name
  Trilinos_Util::CrsMatrixGallery Gallery("", Comm);
  // read parameters and settings from the shell line
  G.Set(CLP);
  // continue with your code...
  \endcode

  \param In
  comm - Epetra communicator
  */
  CrsMatrixGallery( const std::string name, const Epetra_Comm & comm, bool UseLongLong
#if defined(EPETRA_NO_32BIT_GLOBAL_INDICES)
    = true
#else
    = false
#endif
    );


  //! Creates an Triutils_Gallery object using a given map.
  /*! Create a Triutils_Gallery object using an Epetra_Map.
    Problem size must match the elements in map.

    \param In
    name - definition of the problem to be created.

    \param In
    map - Epetra_Map
  */
  CrsMatrixGallery( const std::string name, const Epetra_Map & map );

  //! Triutils_Gallery destructor
  ~CrsMatrixGallery();

  //@}

  //@{ \name Setting methods

  //! Sets a gallery options using an interger value.
  int Set(const std::string parameter, const int value);

  //!  Sets a gallery options using a C++ string .
  int Set(const std::string parameter, const std::string value );

  //! Sets a gallery options using an double value.
  int Set(const std::string parameter, const double value);

  //! Sets a gallery options using an Epetra_Vector.
  /*! Sets a gallery options using an Epetra_Vector. The Epetra_Vector
  is copied into internal structures, and freed by the destructor.
  */
  int Set(const std::string parameter, const Epetra_Vector & value);

  //! Sets gallery options using values passed from the shell
  int Set(Trilinos_Util::CommandLineParser & CLP);

  //@}

  //@{ \name Extraction methods.

  //! Returns a pointer to the CrsMatrix.
  Epetra_CrsMatrix * GetMatrix();

  Epetra_CrsMatrix & GetMatrixRef();

  //! Returns a pointer to the exact solution.
  /*! Returns a pointer to the exact solution.

    Some choices are available to define the exact solution, using
    Set("exact solution", value). value can be:
    - constant: the exact solution vector is made up of 1's.
    - random: a random solution vector
    - linear: value at node i is defined as alpha*i. The double value
    alpha can be set via Set("alpha",DoubleVal).
  */
  Epetra_MultiVector * GetExactSolution();

  //! Returns a pointer to the starting solution (typically, for HB problems).
  /*! Returns a pointer to the starting solution. This is typically used
    while reading a HB problem. However, the user can set a starting
    solution using Set("starting solution", "value"). Value can be
    - zero
    - random
  */
  Epetra_MultiVector * GetStartingSolution();

  //! Returns a pointer to the rhs corresponding to the selected exact solution.
  Epetra_MultiVector * GetRHS();

  //! Returns a pointer the internally stored Map.
  const Epetra_Map * GetMap();

  const Epetra_Map & GetMapRef();

  // ==================== //
  // LINEAR PROBLEM STUFF //
  // ==================== //

  //! Returns a pointer to Epetra_LinearProblem
  Epetra_LinearProblem * GetLinearProblem();

  //! Computes the 2-norm of the residual
  void ComputeResidual(double* residual);

  //! Computes the 2-norm of the difference between the starting solution and the exact solution
  void ComputeDiffBetweenStartingAndExactSolutions(double* residual);

  //! Print out matrix and vectors
  void PrintMatrixAndVectors(std::ostream & os);

  void PrintMatrixAndVectors();

  //! Get pointers to double vectors containing coordinates of points.
  void GetCartesianCoordinates(double * & x, double * & y, double * & z);

  //! Print out detailed information about the problem at hand
  friend std::ostream & operator << (std::ostream& os,
        const Trilinos_Util::CrsMatrixGallery & G );

  //! Print matrix on file in MATLAB format
  int WriteMatrix( const std::string & FileName, const bool UseSparse=true );

  //@}

protected:

  //@{ \name Creation methods.

  //! Creates a map.
  /*! Creates an Epetra_Map. Before calling this function, the problem
  size must have been specified.

  CreateMap() allows some different maps. The type of map is set using
  Set("map",value). Value is a string, defined as:
  - linear: Creates a linear map. Elements are divided into continuous
  chunks among the processors.

  - box: used for problems defined on cartesian grids over a square. The
  nodes is subdivided into mx x my subdomains. mx and my are specified
  via Set("mx",IntValue) and Set("my",IntValue).

  - interlaces: elements are subdivided so that element i is assigned to
  process i%NumProcs.

  - random: assign each node to a random process

  - greedy: (only for HB matrices) implements a greedy algorithm to
    decompose the graph of the HB matrix among the processes

  */
  void CreateMap();

  template<typename int_type>
  void TCreateMap();

  //! Creates the CrdMatrix.
  void CreateMatrix();

  template<typename int_type>
  void TCreateMatrix();

  //! Creates the exact solution.
  template<typename int_type>
  void TCreateExactSolution();

  void CreateExactSolution();

  //! Creates the starting solution.
  void CreateStartingSolution();

  //! Create the RHS corresponding to the desired exact solution.
  template<typename int_type>
  void TCreateRHS();

  void CreateRHS();

  // Create an identity matrix.
  template<typename int_type>
  void CreateEye();

  // Creates a diagonal matrix. Elements on the diagonal are called `a'.
  template<typename int_type>
  void CreateMatrixDiag();

  // Creates a tridiagonal matrix. Elements on the diagonal are called `a',
  // elements on the sub-diagonal 'b', and on the super-diagonal 'c'.
  template<typename int_type>
  void CreateMatrixTriDiag();

  // Create a matrix for a Laplacian in 1D
  template<typename int_type>
  void CreateMatrixLaplace1d();

  template<typename int_type>
  void CreateMatrixLaplace1dNeumann();

  template<typename int_type>
  void CreateMatrixCrossStencil2d();

  template<typename int_type>
  void CreateMatrixCrossStencil2dVector();

  template<typename int_type>
  void CreateMatrixLaplace2d();

  template<typename int_type>
  void CreateMatrixLaplace2d_BC();

  template<typename int_type>
  void CreateMatrixLaplace2d_9pt();

  template<typename int_type>
  void CreateMatrixStretched2d();

  template<typename int_type>
  void CreateMatrixRecirc2d();

  template<typename int_type>
  void CreateMatrixRecirc2dDivFree();

  template<typename int_type>
  void CreateMatrixLaplace2dNeumann();

  template<typename int_type>
  void CreateMatrixUniFlow2d();

  template<typename int_type>
  void CreateMatrixLaplace3d();

  template<typename int_type>
  void CreateMatrixCrossStencil3d();

  template<typename int_type>
  void CreateMatrixCrossStencil3dVector();

  template<typename int_type>
  void CreateMatrixLehmer();

  template<typename int_type>
  void CreateMatrixMinij();

  template<typename int_type>
  void CreateMatrixRis();

  template<typename int_type>
  void CreateMatrixHilbert();

  template<typename int_type>
  void CreateMatrixJordblock();

  template<typename int_type>
  void CreateMatrixCauchy();

  template<typename int_type>
  void CreateMatrixFiedler();

  template<typename int_type>
  void CreateMatrixHanowa();

  template<typename int_type>
  void CreateMatrixKMS();

  template<typename int_type>
  void CreateMatrixParter();

  template<typename int_type>
  void CreateMatrixPei();

  template<typename int_type>
  void CreateMatrixOnes();

  template<typename int_type>
  void CreateMatrixVander();

  // read an HB matrix. This function requires other Trilinos util files
  template<typename int_type>
  void TReadMatrix();

  // returns the neighbors of a given node. The node is supposed to be on
  // a 2D Cartesian grid
  void  GetNeighboursCartesian2d( const int i, const int nx, const int ny,
          int & left, int & right,
          int & lower, int & upper);
  // returns the neighbors of a given node. The node is supposed to be on
  // a 3D Cartesian grid
  void  GetNeighboursCartesian3d( const int i, const int nx, const int ny, const int nz,
          int & left, int & right, int & lower, int & upper,
          int & below, int & above );

  template<typename int_type>
  void TGetCartesianCoordinates(double * & x, double * & y, double * & z);

  // put to NULL or default values all internal data
  void ZeroOutData();

  void SetupCartesianGrid2D();

  void SetupCartesianGrid3D();

  void ExactSolQuadXY(double x, double y, double & u);

  void ExactSolQuadXY(double x, double y, double & u,
          double & ux, double & uy,
          double & uxx, double & uyy);


  //@}

  // ======================== //
  // I N T E R N A L  D A T A //
  // ======================== //

  const Epetra_Comm * comm_;

  // matrix and vectors (scalar)
  Epetra_CrsMatrix * matrix_;
  Epetra_MultiVector * ExactSolution_;
  Epetra_MultiVector * StartingSolution_;
  Epetra_MultiVector * rhs_;
  Epetra_Map * map_;

  // linear problem
  Epetra_LinearProblem * LinearProblem_;

  // information about the problem to generate
  std::string name_;
  long long NumGlobalElements_;
  int NumMyElements_;
#ifndef EPETRA_NO_32BIT_GLOBAL_INDICES
  int * MyGlobalElements_int_;
  std::vector<int> MapMap_int_;
#endif
#ifndef EPETRA_NO_64BIT_GLOBAL_INDICES
  long long * MyGlobalElements_LL_;
  std::vector<long long> MapMap_LL_;
#endif
  std::string MapType_;
  bool ContiguousMap_;
  std::string ExactSolutionType_;
  std::string StartingSolutionType_;
  std::string ExpandType_;
  std::string RhsType_;

  // parameters
  int nx_, ny_, nz_;
  int mx_, my_, mz_;

  double lx_, ly_, lz_;

  int NumPDEEqns_;
  int NumVectors_;

  Epetra_Vector * VectorA_, * VectorB_, * VectorC_, * VectorD_, * VectorE_, *VectorF_, * VectorG_;

  double a_, b_, c_, d_, e_, f_, g_;
  double alpha_, beta_, gamma_, delta_;
  double conv_, diff_, source_;
  double epsilon_;

  std::string FileName_;

  // others
  std::string ErrorMsg;
  std::string OutputMsg;
  bool verbose_;

  bool UseLongLong_;

  template<typename int_type>
  int_type*& MyGlobalElementsPtr();

  template<typename int_type>
  std::vector<int_type>& MapMapRef();
};

#ifndef EPETRA_NO_64BIT_GLOBAL_INDICES
template<> inline long long*& CrsMatrixGallery::MyGlobalElementsPtr<long long>() { return MyGlobalElements_LL_; }
template<> inline std::vector<long long>& CrsMatrixGallery::MapMapRef<long long>() { return MapMap_LL_; }
#endif

#ifndef EPETRA_NO_32BIT_GLOBAL_INDICES
template<> inline int*& CrsMatrixGallery::MyGlobalElementsPtr<int>() { return MyGlobalElements_int_; }
template<> inline std::vector<int>& CrsMatrixGallery::MapMapRef<int>() { return MapMap_int_; }
#endif

// ========================= //
// extension to VBR matrices //
// ==========================//

#ifndef EPETRA_NO_32BIT_GLOBAL_INDICES // CJ: TODO FIXME for long long

class VbrMatrixGallery : public CrsMatrixGallery
{

public:

  VbrMatrixGallery(const std::string name, const Epetra_Map & map) :
    CrsMatrixGallery(name,map),
    VbrMatrix_(0),
    VbrExactSolution_(0),
    VbrStartingSolution_(0),
    VbrRhs_(0),
    BlockMap_(0),
    MaxBlkSize_(1),
    VbrLinearProblem_(0)
   {} ;

  VbrMatrixGallery(const std::string name, const Epetra_Comm & Comm, bool UseLongLong
#if defined(EPETRA_NO_32BIT_GLOBAL_INDICES)
    = true
#else
    = false
#endif
    ) :
    CrsMatrixGallery(name,Comm,UseLongLong),
    VbrMatrix_(0),
    VbrExactSolution_(0),
    VbrStartingSolution_(0),
    VbrRhs_(0),
    BlockMap_(0),
    MaxBlkSize_(1),
    VbrLinearProblem_(0)
  {} ;

  ~VbrMatrixGallery();

  // ========= //
  // VBR STUFF //
  // ========= //

  //! Returns a pointer the internally stored BlockMap.
  const Epetra_BlockMap * GetBlockMap();

  const Epetra_BlockMap & GetBlockMapRef();

  //! Returns a VbrMatrix, starting from the CsrMatrix.
  /*! Returns a VbrMatrix, starting from the CsrMatrix. This vbr matrix
    is formally equivalent to the CrsMatrix returned by
    GetMatrix(). However, each node of the CrsMatrix is replicated
    num_PDE_eqns times (this value is passed in input, or set via Set("num pde
    eqns",IntValue)).
  */
  Epetra_VbrMatrix * GetVbrMatrix(const int NumPDEEqns);

  //! Returns a VbrMatrix, starting from the CsrMatrix.
  Epetra_VbrMatrix * GetVbrMatrix();

  Epetra_VbrMatrix & GetVbrMatrixRef();

  //! Returns a pointer to the RHS for the selected Vbr exact solution
  /*!  Returns a pointer to the RHS  corresponding to the selected exact solution to the linear systems defined by the Epetra_VbrMatrix.
   */
  Epetra_MultiVector * GetVbrRHS();

  //! Returns a pointer to the selected Vbr exact solution
  Epetra_MultiVector * GetVbrExactSolution();

  //! Returns a pointer to the starting solution for Vbr problems
  Epetra_MultiVector * GetVbrStartingSolution();


  // create the Vbr matrix.
  void CreateVbrMatrix(void);

  template<typename int_type>
  void TCreateVbrMatrix(void);

  //! Returns a pointer to Epetra_LinearProblem for VBR
  Epetra_LinearProblem * GetVbrLinearProblem();

  //! Computes the 2-norm of the residual for the VBR problem
  void ComputeResidualVbr(double* residual);

  //! Computes the 2-norm of the difference between the starting solution and the exact solution for the VBR problem
  void ComputeDiffBetweenStartingAndExactSolutionsVbr(double* residual);

  //! Print out Vbr matrix and vectors
  void PrintVbrMatrixAndVectors(std::ostream & os);

  void PrintVbrMatrixAndVectors();

protected:

  // Creates a block map, based on map, wich NumPDEEqns equations on each node.
  void CreateBlockMap(void);

  template<typename int_type>
  void TCreateBlockMap(void);

  //! Creates the exact solution for a Epetra_VbrMatrix.
  void CreateVbrExactSolution(void);

  //! Creates the starting solution for Vbr.
  void CreateVbrStartingSolution();

  //!  Create the RHS corresponding to the desired exact solution for the Vbr problem.
  void CreateVbrRHS();

  // matrix and vectors (vbr)
  Epetra_VbrMatrix * VbrMatrix_;
  Epetra_MultiVector * VbrExactSolution_;
  Epetra_MultiVector * VbrStartingSolution_;
  Epetra_MultiVector * VbrRhs_;
  Epetra_BlockMap * BlockMap_;
  int MaxBlkSize_;

  // linear problem
  Epetra_LinearProblem * VbrLinearProblem_;
};

#endif

} // namespace Trilinos_Util
#endif
libtrilinos-triutils-dev 12.12.1-5 / usr / include / trilinos / Trilinos_Util_CrsMatrixGallery.h
