Eigen/src/PaStiXSupport/PaStiXSupport.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.fr>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_PASTIXSUPPORT_H
 #define EIGEN_PASTIXSUPPORT_H

 // IWYU pragma: private
 #include "./InternalHeaderCheck.h"

 namespace Eigen {

 #if defined(DCOMPLEX)
 #define PASTIX_COMPLEX COMPLEX
 #define PASTIX_DCOMPLEX DCOMPLEX
 #else
 #define PASTIX_COMPLEX std::complex<float>
 #define PASTIX_DCOMPLEX std::complex<double>
 #endif

 /** \ingroup PaStiXSupport_Module
  * \brief Interface to the PaStix solver
  *
  * This class is used to solve the linear systems A.X = B via the PaStix library.
  * The matrix can be either real or complex, symmetric or not.
  *
  * \sa TutorialSparseDirectSolvers
  */
 template <typename MatrixType_, bool IsStrSym = false>
 class PastixLU;
 template <typename MatrixType_, int Options>
 class PastixLLT;
 template <typename MatrixType_, int Options>
 class PastixLDLT;

 namespace internal {

 template <class Pastix>
 struct pastix_traits;

 template <typename MatrixType_>
 struct pastix_traits<PastixLU<MatrixType_> > {
   typedef MatrixType_ MatrixType;
   typedef typename MatrixType_::Scalar Scalar;
   typedef typename MatrixType_::RealScalar RealScalar;
   typedef typename MatrixType_::StorageIndex StorageIndex;
 };

 template <typename MatrixType_, int Options>
 struct pastix_traits<PastixLLT<MatrixType_, Options> > {
   typedef MatrixType_ MatrixType;
   typedef typename MatrixType_::Scalar Scalar;
   typedef typename MatrixType_::RealScalar RealScalar;
   typedef typename MatrixType_::StorageIndex StorageIndex;
 };

 template <typename MatrixType_, int Options>
 struct pastix_traits<PastixLDLT<MatrixType_, Options> > {
   typedef MatrixType_ MatrixType;
   typedef typename MatrixType_::Scalar Scalar;
   typedef typename MatrixType_::RealScalar RealScalar;
   typedef typename MatrixType_::StorageIndex StorageIndex;
 };

 inline void eigen_pastix(pastix_data_t **pastix_data, int pastix_comm, int n, int *ptr, int *idx, float *vals,
                          int *perm, int *invp, float *x, int nbrhs, int *iparm, double *dparm) {
   if (n == 0) {
     ptr = NULL;
     idx = NULL;
     vals = NULL;
   }
   if (nbrhs == 0) {
     x = NULL;
     nbrhs = 1;
   }
   s_pastix(pastix_data, pastix_comm, n, ptr, idx, vals, perm, invp, x, nbrhs, iparm, dparm);
 }

 inline void eigen_pastix(pastix_data_t **pastix_data, int pastix_comm, int n, int *ptr, int *idx, double *vals,
                          int *perm, int *invp, double *x, int nbrhs, int *iparm, double *dparm) {
   if (n == 0) {
     ptr = NULL;
     idx = NULL;
     vals = NULL;
   }
   if (nbrhs == 0) {
     x = NULL;
     nbrhs = 1;
   }
   d_pastix(pastix_data, pastix_comm, n, ptr, idx, vals, perm, invp, x, nbrhs, iparm, dparm);
 }

 inline void eigen_pastix(pastix_data_t **pastix_data, int pastix_comm, int n, int *ptr, int *idx,
                          std::complex<float> *vals, int *perm, int *invp, std::complex<float> *x, int nbrhs, int *iparm,
                          double *dparm) {
   if (n == 0) {
     ptr = NULL;
     idx = NULL;
     vals = NULL;
   }
   if (nbrhs == 0) {
     x = NULL;
     nbrhs = 1;
   }
   c_pastix(pastix_data, pastix_comm, n, ptr, idx, reinterpret_cast<PASTIX_COMPLEX *>(vals), perm, invp,
            reinterpret_cast<PASTIX_COMPLEX *>(x), nbrhs, iparm, dparm);
 }

 inline void eigen_pastix(pastix_data_t **pastix_data, int pastix_comm, int n, int *ptr, int *idx,
                          std::complex<double> *vals, int *perm, int *invp, std::complex<double> *x, int nbrhs,
                          int *iparm, double *dparm) {
   if (n == 0) {
     ptr = NULL;
     idx = NULL;
     vals = NULL;
   }
   if (nbrhs == 0) {
     x = NULL;
     nbrhs = 1;
   }
   z_pastix(pastix_data, pastix_comm, n, ptr, idx, reinterpret_cast<PASTIX_DCOMPLEX *>(vals), perm, invp,
            reinterpret_cast<PASTIX_DCOMPLEX *>(x), nbrhs, iparm, dparm);
 }

 // Convert the matrix  to Fortran-style Numbering
 template <typename MatrixType>
 void c_to_fortran_numbering(MatrixType &mat) {
   if (!(mat.outerIndexPtr()[0])) {
     int i;
     for (i = 0; i <= mat.rows(); ++i) ++mat.outerIndexPtr()[i];
     for (i = 0; i < mat.nonZeros(); ++i) ++mat.innerIndexPtr()[i];
   }
 }

 // Convert to C-style Numbering
 template <typename MatrixType>
 void fortran_to_c_numbering(MatrixType &mat) {
   // Check the Numbering
   if (mat.outerIndexPtr()[0] == 1) {  // Convert to C-style numbering
     int i;
     for (i = 0; i <= mat.rows(); ++i) --mat.outerIndexPtr()[i];
     for (i = 0; i < mat.nonZeros(); ++i) --mat.innerIndexPtr()[i];
   }
 }
 }  // namespace internal

 // This is the base class to interface with PaStiX functions.
 // Users should not used this class directly.
 template <class Derived>
 class PastixBase : public SparseSolverBase<Derived> {
  protected:
   typedef SparseSolverBase<Derived> Base;
   using Base::derived;
   using Base::m_isInitialized;

  public:
   using Base::_solve_impl;

   typedef typename internal::pastix_traits<Derived>::MatrixType MatrixType_;
   typedef MatrixType_ MatrixType;
   typedef typename MatrixType::Scalar Scalar;
   typedef typename MatrixType::RealScalar RealScalar;
   typedef typename MatrixType::StorageIndex StorageIndex;
   typedef Matrix<Scalar, Dynamic, 1> Vector;
   typedef SparseMatrix<Scalar, ColMajor> ColSpMatrix;
   enum { ColsAtCompileTime = MatrixType::ColsAtCompileTime, MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime };

  public:
   PastixBase() : m_initisOk(false), m_analysisIsOk(false), m_factorizationIsOk(false), m_pastixdata(0), m_size(0) {
     init();
   }

   ~PastixBase() { clean(); }

   template <typename Rhs, typename Dest>
   bool _solve_impl(const MatrixBase<Rhs> &b, MatrixBase<Dest> &x) const;

   /** Returns a reference to the integer vector IPARM of PaStiX parameters
    * to modify the default parameters.
    * The statistics related to the different phases of factorization and solve are saved here as well
    * \sa analyzePattern() factorize()
    */
   Array<StorageIndex, IPARM_SIZE, 1> &iparm() { return m_iparm; }

   /** Return a reference to a particular index parameter of the IPARM vector
    * \sa iparm()
    */

   int &iparm(int idxparam) { return m_iparm(idxparam); }

   /** Returns a reference to the double vector DPARM of PaStiX parameters
    * The statistics related to the different phases of factorization and solve are saved here as well
    * \sa analyzePattern() factorize()
    */
   Array<double, DPARM_SIZE, 1> &dparm() { return m_dparm; }

   /** Return a reference to a particular index parameter of the DPARM vector
    * \sa dparm()
    */
   double &dparm(int idxparam) { return m_dparm(idxparam); }

   inline Index cols() const { return m_size; }
   inline Index rows() const { return m_size; }

   /** \brief Reports whether previous computation was successful.
    *
    * \returns \c Success if computation was successful,
    *          \c NumericalIssue if the PaStiX reports a problem
    *          \c InvalidInput if the input matrix is invalid
    *
    * \sa iparm()
    */
   ComputationInfo info() const {
     eigen_assert(m_isInitialized && "Decomposition is not initialized.");
     return m_info;
   }

  protected:
   // Initialize the Pastix data structure, check the matrix
   void init();

   // Compute the ordering and the symbolic factorization
   void analyzePattern(ColSpMatrix &mat);

   // Compute the numerical factorization
   void factorize(ColSpMatrix &mat);

   // Free all the data allocated by Pastix
   void clean() {
     eigen_assert(m_initisOk && "The Pastix structure should be allocated first");
     m_iparm(IPARM_START_TASK) = API_TASK_CLEAN;
     m_iparm(IPARM_END_TASK) = API_TASK_CLEAN;
     internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, 0, 0, 0, (Scalar *)0, m_perm.data(), m_invp.data(), 0, 0,
                            m_iparm.data(), m_dparm.data());
   }

   void compute(ColSpMatrix &mat);

   int m_initisOk;
   int m_analysisIsOk;
   int m_factorizationIsOk;
   mutable ComputationInfo m_info;
   mutable pastix_data_t *m_pastixdata;              // Data structure for pastix
   mutable int m_comm;                               // The MPI communicator identifier
   mutable Array<int, IPARM_SIZE, 1> m_iparm;        // integer vector for the input parameters
   mutable Array<double, DPARM_SIZE, 1> m_dparm;     // Scalar vector for the input parameters
   mutable Matrix<StorageIndex, Dynamic, 1> m_perm;  // Permutation vector
   mutable Matrix<StorageIndex, Dynamic, 1> m_invp;  // Inverse permutation vector
   mutable int m_size;                               // Size of the matrix
 };

 /** Initialize the PaStiX data structure.
  *A first call to this function fills iparm and dparm with the default PaStiX parameters
  * \sa iparm() dparm()
  */
 template <class Derived>
 void PastixBase<Derived>::init() {
   m_size = 0;
   m_iparm.setZero(IPARM_SIZE);
   m_dparm.setZero(DPARM_SIZE);

   m_iparm(IPARM_MODIFY_PARAMETER) = API_NO;
   pastix(&m_pastixdata, MPI_COMM_WORLD, 0, 0, 0, 0, 0, 0, 0, 1, m_iparm.data(), m_dparm.data());

   m_iparm[IPARM_MATRIX_VERIFICATION] = API_NO;
   m_iparm[IPARM_VERBOSE] = API_VERBOSE_NOT;
   m_iparm[IPARM_ORDERING] = API_ORDER_SCOTCH;
   m_iparm[IPARM_INCOMPLETE] = API_NO;
   m_iparm[IPARM_OOC_LIMIT] = 2000;
   m_iparm[IPARM_RHS_MAKING] = API_RHS_B;
   m_iparm(IPARM_MATRIX_VERIFICATION) = API_NO;

   m_iparm(IPARM_START_TASK) = API_TASK_INIT;
   m_iparm(IPARM_END_TASK) = API_TASK_INIT;
   internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, 0, 0, 0, (Scalar *)0, 0, 0, 0, 0, m_iparm.data(),
                          m_dparm.data());

   // Check the returned error
   if (m_iparm(IPARM_ERROR_NUMBER)) {
     m_info = InvalidInput;
     m_initisOk = false;
   } else {
     m_info = Success;
     m_initisOk = true;
   }
 }

 template <class Derived>
 void PastixBase<Derived>::compute(ColSpMatrix &mat) {
   eigen_assert(mat.rows() == mat.cols() && "The input matrix should be squared");

   analyzePattern(mat);
   factorize(mat);

   m_iparm(IPARM_MATRIX_VERIFICATION) = API_NO;
 }

 template <class Derived>
 void PastixBase<Derived>::analyzePattern(ColSpMatrix &mat) {
   eigen_assert(m_initisOk && "The initialization of PaSTiX failed");

   // clean previous calls
   if (m_size > 0) clean();

   m_size = internal::convert_index<int>(mat.rows());
   m_perm.resize(m_size);
   m_invp.resize(m_size);

   m_iparm(IPARM_START_TASK) = API_TASK_ORDERING;
   m_iparm(IPARM_END_TASK) = API_TASK_ANALYSE;
   internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, m_size, mat.outerIndexPtr(), mat.innerIndexPtr(),
                          mat.valuePtr(), m_perm.data(), m_invp.data(), 0, 0, m_iparm.data(), m_dparm.data());

   // Check the returned error
   if (m_iparm(IPARM_ERROR_NUMBER)) {
     m_info = NumericalIssue;
     m_analysisIsOk = false;
   } else {
     m_info = Success;
     m_analysisIsOk = true;
   }
 }

 template <class Derived>
 void PastixBase<Derived>::factorize(ColSpMatrix &mat) {
   //   if(&m_cpyMat != &mat) m_cpyMat = mat;
   eigen_assert(m_analysisIsOk && "The analysis phase should be called before the factorization phase");
   m_iparm(IPARM_START_TASK) = API_TASK_NUMFACT;
   m_iparm(IPARM_END_TASK) = API_TASK_NUMFACT;
   m_size = internal::convert_index<int>(mat.rows());

   internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, m_size, mat.outerIndexPtr(), mat.innerIndexPtr(),
                          mat.valuePtr(), m_perm.data(), m_invp.data(), 0, 0, m_iparm.data(), m_dparm.data());

   // Check the returned error
   if (m_iparm(IPARM_ERROR_NUMBER)) {
     m_info = NumericalIssue;
     m_factorizationIsOk = false;
     m_isInitialized = false;
   } else {
     m_info = Success;
     m_factorizationIsOk = true;
     m_isInitialized = true;
   }
 }

 /* Solve the system */
 template <typename Base>
 template <typename Rhs, typename Dest>
 bool PastixBase<Base>::_solve_impl(const MatrixBase<Rhs> &b, MatrixBase<Dest> &x) const {
   eigen_assert(m_isInitialized && "The matrix should be factorized first");
   EIGEN_STATIC_ASSERT((Dest::Flags & RowMajorBit) == 0, THIS_METHOD_IS_ONLY_FOR_COLUMN_MAJOR_MATRICES);
   int rhs = 1;

   x = b; /* on return, x is overwritten by the computed solution */

   for (int i = 0; i < b.cols(); i++) {
     m_iparm[IPARM_START_TASK] = API_TASK_SOLVE;
     m_iparm[IPARM_END_TASK] = API_TASK_REFINE;

     internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, internal::convert_index<int>(x.rows()), 0, 0, 0,
                            m_perm.data(), m_invp.data(), &x(0, i), rhs, m_iparm.data(), m_dparm.data());
   }

   // Check the returned error
   m_info = m_iparm(IPARM_ERROR_NUMBER) == 0 ? Success : NumericalIssue;

   return m_iparm(IPARM_ERROR_NUMBER) == 0;
 }

 /** \ingroup PaStiXSupport_Module
  * \class PastixLU
  * \brief Sparse direct LU solver based on PaStiX library
  *
  * This class is used to solve the linear systems A.X = B with a supernodal LU
  * factorization in the PaStiX library. The matrix A should be squared and nonsingular
  * PaStiX requires that the matrix A has a symmetric structural pattern.
  * This interface can symmetrize the input matrix otherwise.
  * The vectors or matrices X and B can be either dense or sparse.
  *
  * \tparam MatrixType_ the type of the sparse matrix A, it must be a SparseMatrix<>
  * \tparam IsStrSym Indicates if the input matrix has a symmetric pattern, default is false
  * NOTE : Note that if the analysis and factorization phase are called separately,
  * the input matrix will be symmetrized at each call, hence it is advised to
  * symmetrize the matrix in a end-user program and set \p IsStrSym to true
  *
  * \implsparsesolverconcept
  *
  * \sa \ref TutorialSparseSolverConcept, class SparseLU
  *
  */
 template <typename MatrixType_, bool IsStrSym>
 class PastixLU : public PastixBase<PastixLU<MatrixType_> > {
  public:
   typedef MatrixType_ MatrixType;
   typedef PastixBase<PastixLU<MatrixType> > Base;
   typedef typename Base::ColSpMatrix ColSpMatrix;
   typedef typename MatrixType::StorageIndex StorageIndex;

  public:
   PastixLU() : Base() { init(); }

   explicit PastixLU(const MatrixType &matrix) : Base() {
     init();
     compute(matrix);
   }
   /** Compute the LU supernodal factorization of \p matrix.
    * iparm and dparm can be used to tune the PaStiX parameters.
    * see the PaStiX user's manual
    * \sa analyzePattern() factorize()
    */
   void compute(const MatrixType &matrix) {
     m_structureIsUptodate = false;
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::compute(temp);
   }
   /** Compute the LU symbolic factorization of \p matrix using its sparsity pattern.
    * Several ordering methods can be used at this step. See the PaStiX user's manual.
    * The result of this operation can be used with successive matrices having the same pattern as \p matrix
    * \sa factorize()
    */
   void analyzePattern(const MatrixType &matrix) {
     m_structureIsUptodate = false;
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::analyzePattern(temp);
   }

   /** Compute the LU supernodal factorization of \p matrix
    * WARNING The matrix \p matrix should have the same structural pattern
    * as the same used in the analysis phase.
    * \sa analyzePattern()
    */
   void factorize(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::factorize(temp);
   }

  protected:
   void init() {
     m_structureIsUptodate = false;
     m_iparm(IPARM_SYM) = API_SYM_NO;
     m_iparm(IPARM_FACTORIZATION) = API_FACT_LU;
   }

   void grabMatrix(const MatrixType &matrix, ColSpMatrix &out) {
     if (IsStrSym)
       out = matrix;
     else {
       if (!m_structureIsUptodate) {
         // update the transposed structure
         m_transposedStructure = matrix.transpose();

         // Set the elements of the matrix to zero
         for (Index j = 0; j < m_transposedStructure.outerSize(); ++j)
           for (typename ColSpMatrix::InnerIterator it(m_transposedStructure, j); it; ++it) it.valueRef() = 0.0;

         m_structureIsUptodate = true;
       }

       out = m_transposedStructure + matrix;
     }
     internal::c_to_fortran_numbering(out);
   }

   using Base::m_dparm;
   using Base::m_iparm;

   ColSpMatrix m_transposedStructure;
   bool m_structureIsUptodate;
 };

 /** \ingroup PaStiXSupport_Module
  * \class PastixLLT
  * \brief A sparse direct supernodal Cholesky (LLT) factorization and solver based on the PaStiX library
  *
  * This class is used to solve the linear systems A.X = B via a LL^T supernodal Cholesky factorization
  * available in the PaStiX library. The matrix A should be symmetric and positive definite
  * WARNING Selfadjoint complex matrices are not supported in the current version of PaStiX
  * The vectors or matrices X and B can be either dense or sparse
  *
  * \tparam MatrixType the type of the sparse matrix A, it must be a SparseMatrix<>
  * \tparam UpLo The part of the matrix to use : Lower or Upper. The default is Lower as required by PaStiX
  *
  * \implsparsesolverconcept
  *
  * \sa \ref TutorialSparseSolverConcept, class SimplicialLLT
  */
 template <typename MatrixType_, int UpLo_>
 class PastixLLT : public PastixBase<PastixLLT<MatrixType_, UpLo_> > {
  public:
   typedef MatrixType_ MatrixType;
   typedef PastixBase<PastixLLT<MatrixType, UpLo_> > Base;
   typedef typename Base::ColSpMatrix ColSpMatrix;

  public:
   enum { UpLo = UpLo_ };
   PastixLLT() : Base() { init(); }

   explicit PastixLLT(const MatrixType &matrix) : Base() {
     init();
     compute(matrix);
   }

   /** Compute the L factor of the LL^T supernodal factorization of \p matrix
    * \sa analyzePattern() factorize()
    */
   void compute(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::compute(temp);
   }

   /** Compute the LL^T symbolic factorization of \p matrix using its sparsity pattern
    * The result of this operation can be used with successive matrices having the same pattern as \p matrix
    * \sa factorize()
    */
   void analyzePattern(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::analyzePattern(temp);
   }
   /** Compute the LL^T supernodal numerical factorization of \p matrix
    * \sa analyzePattern()
    */
   void factorize(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::factorize(temp);
   }

  protected:
   using Base::m_iparm;

   void init() {
     m_iparm(IPARM_SYM) = API_SYM_YES;
     m_iparm(IPARM_FACTORIZATION) = API_FACT_LLT;
   }

   void grabMatrix(const MatrixType &matrix, ColSpMatrix &out) {
     out.resize(matrix.rows(), matrix.cols());
     // Pastix supports only lower, column-major matrices
     out.template selfadjointView<Lower>() = matrix.template selfadjointView<UpLo>();
     internal::c_to_fortran_numbering(out);
   }
 };

 /** \ingroup PaStiXSupport_Module
  * \class PastixLDLT
  * \brief A sparse direct supernodal Cholesky (LLT) factorization and solver based on the PaStiX library
  *
  * This class is used to solve the linear systems A.X = B via a LDL^T supernodal Cholesky factorization
  * available in the PaStiX library. The matrix A should be symmetric and positive definite
  * WARNING Selfadjoint complex matrices are not supported in the current version of PaStiX
  * The vectors or matrices X and B can be either dense or sparse
  *
  * \tparam MatrixType the type of the sparse matrix A, it must be a SparseMatrix<>
  * \tparam UpLo The part of the matrix to use : Lower or Upper. The default is Lower as required by PaStiX
  *
  * \implsparsesolverconcept
  *
  * \sa \ref TutorialSparseSolverConcept, class SimplicialLDLT
  */
 template <typename MatrixType_, int UpLo_>
 class PastixLDLT : public PastixBase<PastixLDLT<MatrixType_, UpLo_> > {
  public:
   typedef MatrixType_ MatrixType;
   typedef PastixBase<PastixLDLT<MatrixType, UpLo_> > Base;
   typedef typename Base::ColSpMatrix ColSpMatrix;

  public:
   enum { UpLo = UpLo_ };
   PastixLDLT() : Base() { init(); }

   explicit PastixLDLT(const MatrixType &matrix) : Base() {
     init();
     compute(matrix);
   }

   /** Compute the L and D factors of the LDL^T factorization of \p matrix
    * \sa analyzePattern() factorize()
    */
   void compute(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::compute(temp);
   }

   /** Compute the LDL^T symbolic factorization of \p matrix using its sparsity pattern
    * The result of this operation can be used with successive matrices having the same pattern as \p matrix
    * \sa factorize()
    */
   void analyzePattern(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::analyzePattern(temp);
   }
   /** Compute the LDL^T supernodal numerical factorization of \p matrix
    *
    */
   void factorize(const MatrixType &matrix) {
     ColSpMatrix temp;
     grabMatrix(matrix, temp);
     Base::factorize(temp);
   }

  protected:
   using Base::m_iparm;

   void init() {
     m_iparm(IPARM_SYM) = API_SYM_YES;
     m_iparm(IPARM_FACTORIZATION) = API_FACT_LDLT;
   }

   void grabMatrix(const MatrixType &matrix, ColSpMatrix &out) {
     // Pastix supports only lower, column-major matrices
     out.resize(matrix.rows(), matrix.cols());
     out.template selfadjointView<Lower>() = matrix.template selfadjointView<UpLo>();
     internal::c_to_fortran_numbering(out);
   }
 };

 }  // end namespace Eigen

 #endif
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.fr>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_PASTIXSUPPORT_H
	#define EIGEN_PASTIXSUPPORT_H

	// IWYU pragma: private
	#include "./InternalHeaderCheck.h"

	namespace Eigen {

	#if defined(DCOMPLEX)
	#define PASTIX_COMPLEX COMPLEX
	#define PASTIX_DCOMPLEX DCOMPLEX
	#else
	#define PASTIX_COMPLEX std::complex<float>
	#define PASTIX_DCOMPLEX std::complex<double>
	#endif

	/** \ingroup PaStiXSupport_Module
	* \brief Interface to the PaStix solver
	*
	* This class is used to solve the linear systems A.X = B via the PaStix library.
	* The matrix can be either real or complex, symmetric or not.
	*
	* \sa TutorialSparseDirectSolvers
	*/
	template <typename MatrixType_, bool IsStrSym = false>
	class PastixLU;
	template <typename MatrixType_, int Options>
	class PastixLLT;
	template <typename MatrixType_, int Options>
	class PastixLDLT;

	namespace internal {

	template <class Pastix>
	struct pastix_traits;

	template <typename MatrixType_>
	struct pastix_traits<PastixLU<MatrixType_> > {
	typedef MatrixType_ MatrixType;
	typedef typename MatrixType_::Scalar Scalar;
	typedef typename MatrixType_::RealScalar RealScalar;
	typedef typename MatrixType_::StorageIndex StorageIndex;
	};

	template <typename MatrixType_, int Options>
	struct pastix_traits<PastixLLT<MatrixType_, Options> > {
	typedef MatrixType_ MatrixType;
	typedef typename MatrixType_::Scalar Scalar;
	typedef typename MatrixType_::RealScalar RealScalar;
	typedef typename MatrixType_::StorageIndex StorageIndex;
	};

	template <typename MatrixType_, int Options>
	struct pastix_traits<PastixLDLT<MatrixType_, Options> > {
	typedef MatrixType_ MatrixType;
	typedef typename MatrixType_::Scalar Scalar;
	typedef typename MatrixType_::RealScalar RealScalar;
	typedef typename MatrixType_::StorageIndex StorageIndex;
	};

	inline void eigen_pastix(pastix_data_t *pastix_data, int pastix_comm, int n, int ptr, int idx, float vals,
	int perm, int invp, float x, int nbrhs, int iparm, double *dparm) {
	if (n == 0) {
	ptr = NULL;
	idx = NULL;
	vals = NULL;
	}
	if (nbrhs == 0) {
	x = NULL;
	nbrhs = 1;
	}
	s_pastix(pastix_data, pastix_comm, n, ptr, idx, vals, perm, invp, x, nbrhs, iparm, dparm);
	}

	inline void eigen_pastix(pastix_data_t *pastix_data, int pastix_comm, int n, int ptr, int idx, double vals,
	int perm, int invp, double x, int nbrhs, int iparm, double *dparm) {
	if (n == 0) {
	ptr = NULL;
	idx = NULL;
	vals = NULL;
	}
	if (nbrhs == 0) {
	x = NULL;
	nbrhs = 1;
	}
	d_pastix(pastix_data, pastix_comm, n, ptr, idx, vals, perm, invp, x, nbrhs, iparm, dparm);
	}

	inline void eigen_pastix(pastix_data_t *pastix_data, int pastix_comm, int n, int ptr, int *idx,
	std::complex<float> vals, int perm, int invp, std::complex<float> x, int nbrhs, int *iparm,
	double *dparm) {
	if (n == 0) {
	ptr = NULL;
	idx = NULL;
	vals = NULL;
	}
	if (nbrhs == 0) {
	x = NULL;
	nbrhs = 1;
	}
	c_pastix(pastix_data, pastix_comm, n, ptr, idx, reinterpret_cast<PASTIX_COMPLEX *>(vals), perm, invp,
	reinterpret_cast<PASTIX_COMPLEX *>(x), nbrhs, iparm, dparm);
	}

	inline void eigen_pastix(pastix_data_t *pastix_data, int pastix_comm, int n, int ptr, int *idx,
	std::complex<double> vals, int perm, int invp, std::complex<double> x, int nbrhs,
	int iparm, double dparm) {
	if (n == 0) {
	ptr = NULL;
	idx = NULL;
	vals = NULL;
	}
	if (nbrhs == 0) {
	x = NULL;
	nbrhs = 1;
	}
	z_pastix(pastix_data, pastix_comm, n, ptr, idx, reinterpret_cast<PASTIX_DCOMPLEX *>(vals), perm, invp,
	reinterpret_cast<PASTIX_DCOMPLEX *>(x), nbrhs, iparm, dparm);
	}

	// Convert the matrix to Fortran-style Numbering
	template <typename MatrixType>
	void c_to_fortran_numbering(MatrixType &mat) {
	if (!(mat.outerIndexPtr()[0])) {
	int i;
	for (i = 0; i <= mat.rows(); ++i) ++mat.outerIndexPtr()[i];
	for (i = 0; i < mat.nonZeros(); ++i) ++mat.innerIndexPtr()[i];
	}
	}

	// Convert to C-style Numbering
	template <typename MatrixType>
	void fortran_to_c_numbering(MatrixType &mat) {
	// Check the Numbering
	if (mat.outerIndexPtr()[0] == 1) { // Convert to C-style numbering
	int i;
	for (i = 0; i <= mat.rows(); ++i) --mat.outerIndexPtr()[i];
	for (i = 0; i < mat.nonZeros(); ++i) --mat.innerIndexPtr()[i];
	}
	}
	} // namespace internal

	// This is the base class to interface with PaStiX functions.
	// Users should not used this class directly.
	template <class Derived>
	class PastixBase : public SparseSolverBase<Derived> {
	protected:
	typedef SparseSolverBase<Derived> Base;
	using Base::derived;
	using Base::m_isInitialized;

	public:
	using Base::_solve_impl;

	typedef typename internal::pastix_traits<Derived>::MatrixType MatrixType_;
	typedef MatrixType_ MatrixType;
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::RealScalar RealScalar;
	typedef typename MatrixType::StorageIndex StorageIndex;
	typedef Matrix<Scalar, Dynamic, 1> Vector;
	typedef SparseMatrix<Scalar, ColMajor> ColSpMatrix;
	enum { ColsAtCompileTime = MatrixType::ColsAtCompileTime, MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime };

	public:
	PastixBase() : m_initisOk(false), m_analysisIsOk(false), m_factorizationIsOk(false), m_pastixdata(0), m_size(0) {
	init();
	}

	~PastixBase() { clean(); }

	template <typename Rhs, typename Dest>
	bool _solve_impl(const MatrixBase<Rhs> &b, MatrixBase<Dest> &x) const;

	/** Returns a reference to the integer vector IPARM of PaStiX parameters
	* to modify the default parameters.
	* The statistics related to the different phases of factorization and solve are saved here as well
	* \sa analyzePattern() factorize()
	*/
	Array<StorageIndex, IPARM_SIZE, 1> &iparm() { return m_iparm; }

	/** Return a reference to a particular index parameter of the IPARM vector
	* \sa iparm()
	*/

	int &iparm(int idxparam) { return m_iparm(idxparam); }

	/** Returns a reference to the double vector DPARM of PaStiX parameters
	* The statistics related to the different phases of factorization and solve are saved here as well
	* \sa analyzePattern() factorize()
	*/
	Array<double, DPARM_SIZE, 1> &dparm() { return m_dparm; }

	/** Return a reference to a particular index parameter of the DPARM vector
	* \sa dparm()
	*/
	double &dparm(int idxparam) { return m_dparm(idxparam); }

	inline Index cols() const { return m_size; }
	inline Index rows() const { return m_size; }

	/** \brief Reports whether previous computation was successful.
	*
	* \returns \c Success if computation was successful,
	* \c NumericalIssue if the PaStiX reports a problem
	* \c InvalidInput if the input matrix is invalid
	*
	* \sa iparm()
	*/
	ComputationInfo info() const {
	eigen_assert(m_isInitialized && "Decomposition is not initialized.");
	return m_info;
	}

	protected:
	// Initialize the Pastix data structure, check the matrix
	void init();

	// Compute the ordering and the symbolic factorization
	void analyzePattern(ColSpMatrix &mat);

	// Compute the numerical factorization
	void factorize(ColSpMatrix &mat);

	// Free all the data allocated by Pastix
	void clean() {
	eigen_assert(m_initisOk && "The Pastix structure should be allocated first");
	m_iparm(IPARM_START_TASK) = API_TASK_CLEAN;
	m_iparm(IPARM_END_TASK) = API_TASK_CLEAN;
	internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, 0, 0, 0, (Scalar *)0, m_perm.data(), m_invp.data(), 0, 0,
	m_iparm.data(), m_dparm.data());
	}

	void compute(ColSpMatrix &mat);

	int m_initisOk;
	int m_analysisIsOk;
	int m_factorizationIsOk;
	mutable ComputationInfo m_info;
	mutable pastix_data_t *m_pastixdata; // Data structure for pastix
	mutable int m_comm; // The MPI communicator identifier
	mutable Array<int, IPARM_SIZE, 1> m_iparm; // integer vector for the input parameters
	mutable Array<double, DPARM_SIZE, 1> m_dparm; // Scalar vector for the input parameters
	mutable Matrix<StorageIndex, Dynamic, 1> m_perm; // Permutation vector
	mutable Matrix<StorageIndex, Dynamic, 1> m_invp; // Inverse permutation vector
	mutable int m_size; // Size of the matrix
	};

	/** Initialize the PaStiX data structure.
	*A first call to this function fills iparm and dparm with the default PaStiX parameters
	* \sa iparm() dparm()
	*/
	template <class Derived>
	void PastixBase<Derived>::init() {
	m_size = 0;
	m_iparm.setZero(IPARM_SIZE);
	m_dparm.setZero(DPARM_SIZE);

	m_iparm(IPARM_MODIFY_PARAMETER) = API_NO;
	pastix(&m_pastixdata, MPI_COMM_WORLD, 0, 0, 0, 0, 0, 0, 0, 1, m_iparm.data(), m_dparm.data());

	m_iparm[IPARM_MATRIX_VERIFICATION] = API_NO;
	m_iparm[IPARM_VERBOSE] = API_VERBOSE_NOT;
	m_iparm[IPARM_ORDERING] = API_ORDER_SCOTCH;
	m_iparm[IPARM_INCOMPLETE] = API_NO;
	m_iparm[IPARM_OOC_LIMIT] = 2000;
	m_iparm[IPARM_RHS_MAKING] = API_RHS_B;
	m_iparm(IPARM_MATRIX_VERIFICATION) = API_NO;

	m_iparm(IPARM_START_TASK) = API_TASK_INIT;
	m_iparm(IPARM_END_TASK) = API_TASK_INIT;
	internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, 0, 0, 0, (Scalar *)0, 0, 0, 0, 0, m_iparm.data(),
	m_dparm.data());

	// Check the returned error
	if (m_iparm(IPARM_ERROR_NUMBER)) {
	m_info = InvalidInput;
	m_initisOk = false;
	} else {
	m_info = Success;
	m_initisOk = true;
	}
	}

	template <class Derived>
	void PastixBase<Derived>::compute(ColSpMatrix &mat) {
	eigen_assert(mat.rows() == mat.cols() && "The input matrix should be squared");

	analyzePattern(mat);
	factorize(mat);

	m_iparm(IPARM_MATRIX_VERIFICATION) = API_NO;
	}

	template <class Derived>
	void PastixBase<Derived>::analyzePattern(ColSpMatrix &mat) {
	eigen_assert(m_initisOk && "The initialization of PaSTiX failed");

	// clean previous calls
	if (m_size > 0) clean();

	m_size = internal::convert_index<int>(mat.rows());
	m_perm.resize(m_size);
	m_invp.resize(m_size);

	m_iparm(IPARM_START_TASK) = API_TASK_ORDERING;
	m_iparm(IPARM_END_TASK) = API_TASK_ANALYSE;
	internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, m_size, mat.outerIndexPtr(), mat.innerIndexPtr(),
	mat.valuePtr(), m_perm.data(), m_invp.data(), 0, 0, m_iparm.data(), m_dparm.data());

	// Check the returned error
	if (m_iparm(IPARM_ERROR_NUMBER)) {
	m_info = NumericalIssue;
	m_analysisIsOk = false;
	} else {
	m_info = Success;
	m_analysisIsOk = true;
	}
	}

	template <class Derived>
	void PastixBase<Derived>::factorize(ColSpMatrix &mat) {
	// if(&m_cpyMat != &mat) m_cpyMat = mat;
	eigen_assert(m_analysisIsOk && "The analysis phase should be called before the factorization phase");
	m_iparm(IPARM_START_TASK) = API_TASK_NUMFACT;
	m_iparm(IPARM_END_TASK) = API_TASK_NUMFACT;
	m_size = internal::convert_index<int>(mat.rows());

	internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, m_size, mat.outerIndexPtr(), mat.innerIndexPtr(),
	mat.valuePtr(), m_perm.data(), m_invp.data(), 0, 0, m_iparm.data(), m_dparm.data());

	// Check the returned error
	if (m_iparm(IPARM_ERROR_NUMBER)) {
	m_info = NumericalIssue;
	m_factorizationIsOk = false;
	m_isInitialized = false;
	} else {
	m_info = Success;
	m_factorizationIsOk = true;
	m_isInitialized = true;
	}
	}

	/* Solve the system */
	template <typename Base>
	template <typename Rhs, typename Dest>
	bool PastixBase<Base>::_solve_impl(const MatrixBase<Rhs> &b, MatrixBase<Dest> &x) const {
	eigen_assert(m_isInitialized && "The matrix should be factorized first");
	EIGEN_STATIC_ASSERT((Dest::Flags & RowMajorBit) == 0, THIS_METHOD_IS_ONLY_FOR_COLUMN_MAJOR_MATRICES);
	int rhs = 1;

	x = b; /* on return, x is overwritten by the computed solution */

	for (int i = 0; i < b.cols(); i++) {
	m_iparm[IPARM_START_TASK] = API_TASK_SOLVE;
	m_iparm[IPARM_END_TASK] = API_TASK_REFINE;

	internal::eigen_pastix(&m_pastixdata, MPI_COMM_WORLD, internal::convert_index<int>(x.rows()), 0, 0, 0,
	m_perm.data(), m_invp.data(), &x(0, i), rhs, m_iparm.data(), m_dparm.data());
	}

	// Check the returned error
	m_info = m_iparm(IPARM_ERROR_NUMBER) == 0 ? Success : NumericalIssue;

	return m_iparm(IPARM_ERROR_NUMBER) == 0;
	}

	/** \ingroup PaStiXSupport_Module
	* \class PastixLU
	* \brief Sparse direct LU solver based on PaStiX library
	*
	* This class is used to solve the linear systems A.X = B with a supernodal LU
	* factorization in the PaStiX library. The matrix A should be squared and nonsingular
	* PaStiX requires that the matrix A has a symmetric structural pattern.
	* This interface can symmetrize the input matrix otherwise.
	* The vectors or matrices X and B can be either dense or sparse.
	*
	* \tparam MatrixType_ the type of the sparse matrix A, it must be a SparseMatrix<>
	* \tparam IsStrSym Indicates if the input matrix has a symmetric pattern, default is false
	* NOTE : Note that if the analysis and factorization phase are called separately,
	* the input matrix will be symmetrized at each call, hence it is advised to
	* symmetrize the matrix in a end-user program and set \p IsStrSym to true
	*
	* \implsparsesolverconcept
	*
	* \sa \ref TutorialSparseSolverConcept, class SparseLU
	*
	*/
	template <typename MatrixType_, bool IsStrSym>
	class PastixLU : public PastixBase<PastixLU<MatrixType_> > {
	public:
	typedef MatrixType_ MatrixType;
	typedef PastixBase<PastixLU<MatrixType> > Base;
	typedef typename Base::ColSpMatrix ColSpMatrix;
	typedef typename MatrixType::StorageIndex StorageIndex;

	public:
	PastixLU() : Base() { init(); }

	explicit PastixLU(const MatrixType &matrix) : Base() {
	init();
	compute(matrix);
	}
	/** Compute the LU supernodal factorization of \p matrix.
	* iparm and dparm can be used to tune the PaStiX parameters.
	* see the PaStiX user's manual
	* \sa analyzePattern() factorize()
	*/
	void compute(const MatrixType &matrix) {
	m_structureIsUptodate = false;
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::compute(temp);
	}
	/** Compute the LU symbolic factorization of \p matrix using its sparsity pattern.
	* Several ordering methods can be used at this step. See the PaStiX user's manual.
	* The result of this operation can be used with successive matrices having the same pattern as \p matrix
	* \sa factorize()
	*/
	void analyzePattern(const MatrixType &matrix) {
	m_structureIsUptodate = false;
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::analyzePattern(temp);
	}

	/** Compute the LU supernodal factorization of \p matrix
	* WARNING The matrix \p matrix should have the same structural pattern
	* as the same used in the analysis phase.
	* \sa analyzePattern()
	*/
	void factorize(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::factorize(temp);
	}

	protected:
	void init() {
	m_structureIsUptodate = false;
	m_iparm(IPARM_SYM) = API_SYM_NO;
	m_iparm(IPARM_FACTORIZATION) = API_FACT_LU;
	}

	void grabMatrix(const MatrixType &matrix, ColSpMatrix &out) {
	if (IsStrSym)
	out = matrix;
	else {
	if (!m_structureIsUptodate) {
	// update the transposed structure
	m_transposedStructure = matrix.transpose();

	// Set the elements of the matrix to zero
	for (Index j = 0; j < m_transposedStructure.outerSize(); ++j)
	for (typename ColSpMatrix::InnerIterator it(m_transposedStructure, j); it; ++it) it.valueRef() = 0.0;

	m_structureIsUptodate = true;
	}

	out = m_transposedStructure + matrix;
	}
	internal::c_to_fortran_numbering(out);
	}

	using Base::m_dparm;
	using Base::m_iparm;

	ColSpMatrix m_transposedStructure;
	bool m_structureIsUptodate;
	};

	/** \ingroup PaStiXSupport_Module
	* \class PastixLLT
	* \brief A sparse direct supernodal Cholesky (LLT) factorization and solver based on the PaStiX library
	*
	* This class is used to solve the linear systems A.X = B via a LL^T supernodal Cholesky factorization
	* available in the PaStiX library. The matrix A should be symmetric and positive definite
	* WARNING Selfadjoint complex matrices are not supported in the current version of PaStiX
	* The vectors or matrices X and B can be either dense or sparse
	*
	* \tparam MatrixType the type of the sparse matrix A, it must be a SparseMatrix<>
	* \tparam UpLo The part of the matrix to use : Lower or Upper. The default is Lower as required by PaStiX
	*
	* \implsparsesolverconcept
	*
	* \sa \ref TutorialSparseSolverConcept, class SimplicialLLT
	*/
	template <typename MatrixType_, int UpLo_>
	class PastixLLT : public PastixBase<PastixLLT<MatrixType_, UpLo_> > {
	public:
	typedef MatrixType_ MatrixType;
	typedef PastixBase<PastixLLT<MatrixType, UpLo_> > Base;
	typedef typename Base::ColSpMatrix ColSpMatrix;

	public:
	enum { UpLo = UpLo_ };
	PastixLLT() : Base() { init(); }

	explicit PastixLLT(const MatrixType &matrix) : Base() {
	init();
	compute(matrix);
	}

	/** Compute the L factor of the LL^T supernodal factorization of \p matrix
	* \sa analyzePattern() factorize()
	*/
	void compute(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::compute(temp);
	}

	/** Compute the LL^T symbolic factorization of \p matrix using its sparsity pattern
	* The result of this operation can be used with successive matrices having the same pattern as \p matrix
	* \sa factorize()
	*/
	void analyzePattern(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::analyzePattern(temp);
	}
	/** Compute the LL^T supernodal numerical factorization of \p matrix
	* \sa analyzePattern()
	*/
	void factorize(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::factorize(temp);
	}

	protected:
	using Base::m_iparm;

	void init() {
	m_iparm(IPARM_SYM) = API_SYM_YES;
	m_iparm(IPARM_FACTORIZATION) = API_FACT_LLT;
	}

	void grabMatrix(const MatrixType &matrix, ColSpMatrix &out) {
	out.resize(matrix.rows(), matrix.cols());
	// Pastix supports only lower, column-major matrices
	out.template selfadjointView<Lower>() = matrix.template selfadjointView<UpLo>();
	internal::c_to_fortran_numbering(out);
	}
	};

	/** \ingroup PaStiXSupport_Module
	* \class PastixLDLT
	* \brief A sparse direct supernodal Cholesky (LLT) factorization and solver based on the PaStiX library
	*
	* This class is used to solve the linear systems A.X = B via a LDL^T supernodal Cholesky factorization
	* available in the PaStiX library. The matrix A should be symmetric and positive definite
	* WARNING Selfadjoint complex matrices are not supported in the current version of PaStiX
	* The vectors or matrices X and B can be either dense or sparse
	*
	* \tparam MatrixType the type of the sparse matrix A, it must be a SparseMatrix<>
	* \tparam UpLo The part of the matrix to use : Lower or Upper. The default is Lower as required by PaStiX
	*
	* \implsparsesolverconcept
	*
	* \sa \ref TutorialSparseSolverConcept, class SimplicialLDLT
	*/
	template <typename MatrixType_, int UpLo_>
	class PastixLDLT : public PastixBase<PastixLDLT<MatrixType_, UpLo_> > {
	public:
	typedef MatrixType_ MatrixType;
	typedef PastixBase<PastixLDLT<MatrixType, UpLo_> > Base;
	typedef typename Base::ColSpMatrix ColSpMatrix;

	public:
	enum { UpLo = UpLo_ };
	PastixLDLT() : Base() { init(); }

	explicit PastixLDLT(const MatrixType &matrix) : Base() {
	init();
	compute(matrix);
	}

	/** Compute the L and D factors of the LDL^T factorization of \p matrix
	* \sa analyzePattern() factorize()
	*/
	void compute(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::compute(temp);
	}

	/** Compute the LDL^T symbolic factorization of \p matrix using its sparsity pattern
	* The result of this operation can be used with successive matrices having the same pattern as \p matrix
	* \sa factorize()
	*/
	void analyzePattern(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::analyzePattern(temp);
	}
	/** Compute the LDL^T supernodal numerical factorization of \p matrix
	*
	*/
	void factorize(const MatrixType &matrix) {
	ColSpMatrix temp;
	grabMatrix(matrix, temp);
	Base::factorize(temp);
	}

	protected:
	using Base::m_iparm;

	void init() {
	m_iparm(IPARM_SYM) = API_SYM_YES;
	m_iparm(IPARM_FACTORIZATION) = API_FACT_LDLT;
	}

	void grabMatrix(const MatrixType &matrix, ColSpMatrix &out) {
	// Pastix supports only lower, column-major matrices
	out.resize(matrix.rows(), matrix.cols());
	out.template selfadjointView<Lower>() = matrix.template selfadjointView<UpLo>();
	internal::c_to_fortran_numbering(out);
	}
	};

	} // end namespace Eigen

	#endif