Eigen/src/OrderingMethods/Ordering.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_ORDERING_H
 #define EIGEN_ORDERING_H

 namespace Eigen {

 #include "Eigen_Colamd.h"

 namespace internal {

 /** \internal
   * \ingroup OrderingMethods_Module
   * \param[in] A the input non-symmetric matrix
   * \param[out] symmat the symmetric pattern A^T+A from the input matrix \a A.
   * FIXME: The values should not be considered here
   */
 template<typename MatrixType>
 void ordering_helper_at_plus_a(const MatrixType& A, MatrixType& symmat)
 {
   MatrixType C;
   C = A.transpose(); // NOTE: Could be  costly
   for (int i = 0; i < C.rows(); i++)
   {
       for (typename MatrixType::InnerIterator it(C, i); it; ++it)
         it.valueRef() = typename MatrixType::Scalar(0);
   }
   symmat = C + A;
 }

 }

 /** \ingroup OrderingMethods_Module
   * \class AMDOrdering
   *
   * Functor computing the \em approximate \em minimum \em degree ordering
   * If the matrix is not structurally symmetric, an ordering of A^T+A is computed
   * \tparam  StorageIndex The type of indices of the matrix
   * \sa COLAMDOrdering
   */
 template <typename StorageIndex>
 class AMDOrdering
 {
   public:
     typedef PermutationMatrix<Dynamic, Dynamic, StorageIndex> PermutationType;

     /** Compute the permutation vector from a sparse matrix
      * This routine is much faster if the input matrix is column-major
      */
     template <typename MatrixType>
     void operator()(const MatrixType& mat, PermutationType& perm)
     {
       // Compute the symmetric pattern
       SparseMatrix<typename MatrixType::Scalar, ColMajor, StorageIndex> symm;
       internal::ordering_helper_at_plus_a(mat,symm);

       // Call the AMD routine
       //m_mat.prune(keep_diag());
       internal::minimum_degree_ordering(symm, perm);
     }

     /** Compute the permutation with a selfadjoint matrix */
     template <typename SrcType, unsigned int SrcUpLo>
     void operator()(const SparseSelfAdjointView<SrcType, SrcUpLo>& mat, PermutationType& perm)
     {
       SparseMatrix<typename SrcType::Scalar, ColMajor, StorageIndex> C; C = mat;

       // Call the AMD routine
       // m_mat.prune(keep_diag()); //Remove the diagonal elements
       internal::minimum_degree_ordering(C, perm);
     }
 };

 /** \ingroup OrderingMethods_Module
   * \class NaturalOrdering
   *
   * Functor computing the natural ordering (identity)
   *
   * \note Returns an empty permutation matrix
   * \tparam  StorageIndex The type of indices of the matrix
   */
 template <typename StorageIndex>
 class NaturalOrdering
 {
   public:
     typedef PermutationMatrix<Dynamic, Dynamic, StorageIndex> PermutationType;

     /** Compute the permutation vector from a column-major sparse matrix */
     template <typename MatrixType>
     void operator()(const MatrixType& /*mat*/, PermutationType& perm)
     {
       perm.resize(0);
     }

 };

 /** \ingroup OrderingMethods_Module
   * \class COLAMDOrdering
   *
   * \tparam  StorageIndex The type of indices of the matrix
   *
   * Functor computing the \em column \em approximate \em minimum \em degree ordering
   * The matrix should be in column-major and \b compressed format (see SparseMatrix::makeCompressed()).
   */
 template<typename StorageIndex>
 class COLAMDOrdering
 {
   public:
     typedef PermutationMatrix<Dynamic, Dynamic, StorageIndex> PermutationType;
     typedef Matrix<StorageIndex, Dynamic, 1> IndexVector;

     /** Compute the permutation vector \a perm form the sparse matrix \a mat
       * \warning The input sparse matrix \a mat must be in compressed mode (see SparseMatrix::makeCompressed()).
       */
     template <typename MatrixType>
     void operator() (const MatrixType& mat, PermutationType& perm)
     {
       eigen_assert(mat.isCompressed() && "COLAMDOrdering requires a sparse matrix in compressed mode. Call .makeCompressed() before passing it to COLAMDOrdering");

       StorageIndex m = StorageIndex(mat.rows());
       StorageIndex n = StorageIndex(mat.cols());
       StorageIndex nnz = StorageIndex(mat.nonZeros());
       // Get the recommended value of Alen to be used by colamd
       StorageIndex Alen = internal::colamd_recommended(nnz, m, n);
       // Set the default parameters
       double knobs [COLAMD_KNOBS];
       StorageIndex stats [COLAMD_STATS];
       internal::colamd_set_defaults(knobs);

       IndexVector p(n+1), A(Alen);
       for(StorageIndex i=0; i <= n; i++)   p(i) = mat.outerIndexPtr()[i];
       for(StorageIndex i=0; i < nnz; i++)  A(i) = mat.innerIndexPtr()[i];
       // Call Colamd routine to compute the ordering
       StorageIndex info = internal::colamd(m, n, Alen, A.data(), p.data(), knobs, stats);
       EIGEN_UNUSED_VARIABLE(info);
       eigen_assert( info && "COLAMD failed " );

       perm.resize(n);
       for (StorageIndex i = 0; i < n; i++) perm.indices()(p(i)) = i;
     }
 };

 } // 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_ORDERING_H
	#define EIGEN_ORDERING_H

	namespace Eigen {

	#include "Eigen_Colamd.h"

	namespace internal {

	/** \internal
	* \ingroup OrderingMethods_Module
	* \param[in] A the input non-symmetric matrix
	* \param[out] symmat the symmetric pattern A^T+A from the input matrix \a A.
	* FIXME: The values should not be considered here
	*/
	template<typename MatrixType>
	void ordering_helper_at_plus_a(const MatrixType& A, MatrixType& symmat)
	{
	MatrixType C;
	C = A.transpose(); // NOTE: Could be costly
	for (int i = 0; i < C.rows(); i++)
	{
	for (typename MatrixType::InnerIterator it(C, i); it; ++it)
	it.valueRef() = typename MatrixType::Scalar(0);
	}
	symmat = C + A;
	}

	}

	/** \ingroup OrderingMethods_Module
	* \class AMDOrdering
	*
	* Functor computing the \em approximate \em minimum \em degree ordering
	* If the matrix is not structurally symmetric, an ordering of A^T+A is computed
	* \tparam StorageIndex The type of indices of the matrix
	* \sa COLAMDOrdering
	*/
	template <typename StorageIndex>
	class AMDOrdering
	{
	public:
	typedef PermutationMatrix<Dynamic, Dynamic, StorageIndex> PermutationType;

	/** Compute the permutation vector from a sparse matrix
	* This routine is much faster if the input matrix is column-major
	*/
	template <typename MatrixType>
	void operator()(const MatrixType& mat, PermutationType& perm)
	{
	// Compute the symmetric pattern
	SparseMatrix<typename MatrixType::Scalar, ColMajor, StorageIndex> symm;
	internal::ordering_helper_at_plus_a(mat,symm);

	// Call the AMD routine
	//m_mat.prune(keep_diag());
	internal::minimum_degree_ordering(symm, perm);
	}

	/** Compute the permutation with a selfadjoint matrix */
	template <typename SrcType, unsigned int SrcUpLo>
	void operator()(const SparseSelfAdjointView<SrcType, SrcUpLo>& mat, PermutationType& perm)
	{
	SparseMatrix<typename SrcType::Scalar, ColMajor, StorageIndex> C; C = mat;

	// Call the AMD routine
	// m_mat.prune(keep_diag()); //Remove the diagonal elements
	internal::minimum_degree_ordering(C, perm);
	}
	};

	/** \ingroup OrderingMethods_Module
	* \class NaturalOrdering
	*
	* Functor computing the natural ordering (identity)
	*
	* \note Returns an empty permutation matrix
	* \tparam StorageIndex The type of indices of the matrix
	*/
	template <typename StorageIndex>
	class NaturalOrdering
	{
	public:
	typedef PermutationMatrix<Dynamic, Dynamic, StorageIndex> PermutationType;

	/** Compute the permutation vector from a column-major sparse matrix */
	template <typename MatrixType>
	void operator()(const MatrixType& /mat/, PermutationType& perm)
	{
	perm.resize(0);
	}

	};

	/** \ingroup OrderingMethods_Module
	* \class COLAMDOrdering
	*
	* \tparam StorageIndex The type of indices of the matrix
	*
	* Functor computing the \em column \em approximate \em minimum \em degree ordering
	* The matrix should be in column-major and \b compressed format (see SparseMatrix::makeCompressed()).
	*/
	template<typename StorageIndex>
	class COLAMDOrdering
	{
	public:
	typedef PermutationMatrix<Dynamic, Dynamic, StorageIndex> PermutationType;
	typedef Matrix<StorageIndex, Dynamic, 1> IndexVector;

	/** Compute the permutation vector \a perm form the sparse matrix \a mat
	* \warning The input sparse matrix \a mat must be in compressed mode (see SparseMatrix::makeCompressed()).
	*/
	template <typename MatrixType>
	void operator() (const MatrixType& mat, PermutationType& perm)
	{
	eigen_assert(mat.isCompressed() && "COLAMDOrdering requires a sparse matrix in compressed mode. Call .makeCompressed() before passing it to COLAMDOrdering");

	StorageIndex m = StorageIndex(mat.rows());
	StorageIndex n = StorageIndex(mat.cols());
	StorageIndex nnz = StorageIndex(mat.nonZeros());
	// Get the recommended value of Alen to be used by colamd
	StorageIndex Alen = internal::colamd_recommended(nnz, m, n);
	// Set the default parameters
	double knobs [COLAMD_KNOBS];
	StorageIndex stats [COLAMD_STATS];
	internal::colamd_set_defaults(knobs);

	IndexVector p(n+1), A(Alen);
	for(StorageIndex i=0; i <= n; i++) p(i) = mat.outerIndexPtr()[i];
	for(StorageIndex i=0; i < nnz; i++) A(i) = mat.innerIndexPtr()[i];
	// Call Colamd routine to compute the ordering
	StorageIndex info = internal::colamd(m, n, Alen, A.data(), p.data(), knobs, stats);
	EIGEN_UNUSED_VARIABLE(info);
	eigen_assert( info && "COLAMD failed " );

	perm.resize(n);
	for (StorageIndex i = 0; i < n; i++) perm.indices()(p(i)) = i;
	}
	};

	} // end namespace Eigen

	#endif