Eigen/src/Eigenvalues/GeneralizedSelfAdjointEigenSolver.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008-2010 Gael Guennebaud <gael.guennebaud@inria.fr>
 // Copyright (C) 2010 Jitse Niesen <jitse@maths.leeds.ac.uk>
 //
 // 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_GENERALIZEDSELFADJOINTEIGENSOLVER_H
 #define EIGEN_GENERALIZEDSELFADJOINTEIGENSOLVER_H

 #include "./Tridiagonalization.h"

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

 namespace Eigen {

 /** \eigenvalues_module \ingroup Eigenvalues_Module
  *
  *
  * \class GeneralizedSelfAdjointEigenSolver
  *
  * \brief Computes eigenvalues and eigenvectors of the generalized selfadjoint eigen problem
  *
  * \tparam MatrixType_ the type of the matrix of which we are computing the
  * eigendecomposition; this is expected to be an instantiation of the Matrix
  * class template.
  *
  * This class solves the generalized eigenvalue problem
  * \f$ Av = \lambda Bv \f$. In this case, the matrix \f$ A \f$ should be
  * selfadjoint and the matrix \f$ B \f$ should be positive definite.
  *
  * Only the \b lower \b triangular \b part of the input matrix is referenced.
  *
  * Call the function compute() to compute the eigenvalues and eigenvectors of
  * a given matrix. Alternatively, you can use the
  * GeneralizedSelfAdjointEigenSolver(const MatrixType&, const MatrixType&, int)
  * constructor which computes the eigenvalues and eigenvectors at construction time.
  * Once the eigenvalue and eigenvectors are computed, they can be retrieved with the eigenvalues()
  * and eigenvectors() functions.
  *
  * The documentation for GeneralizedSelfAdjointEigenSolver(const MatrixType&, const MatrixType&, int)
  * contains an example of the typical use of this class.
  *
  * \sa class SelfAdjointEigenSolver, class EigenSolver, class ComplexEigenSolver
  */
 template <typename MatrixType_>
 class GeneralizedSelfAdjointEigenSolver : public SelfAdjointEigenSolver<MatrixType_> {
   typedef SelfAdjointEigenSolver<MatrixType_> Base;

  public:
   typedef MatrixType_ MatrixType;

   /** \brief Default constructor for fixed-size matrices.
    *
    * The default constructor is useful in cases in which the user intends to
    * perform decompositions via compute(). This constructor
    * can only be used if \p MatrixType_ is a fixed-size matrix; use
    * GeneralizedSelfAdjointEigenSolver(Index) for dynamic-size matrices.
    */
   GeneralizedSelfAdjointEigenSolver() : Base() {}

   /** \brief Constructor, pre-allocates memory for dynamic-size matrices.
    *
    * \param [in]  size  Positive integer, size of the matrix whose
    * eigenvalues and eigenvectors will be computed.
    *
    * This constructor is useful for dynamic-size matrices, when the user
    * intends to perform decompositions via compute(). The \p size
    * parameter is only used as a hint. It is not an error to give a wrong
    * \p size, but it may impair performance.
    *
    * \sa compute() for an example
    */
   explicit GeneralizedSelfAdjointEigenSolver(Index size) : Base(size) {}

   /** \brief Constructor; computes generalized eigendecomposition of given matrix pencil.
    *
    * \param[in]  matA  Selfadjoint matrix in matrix pencil.
    *                   Only the lower triangular part of the matrix is referenced.
    * \param[in]  matB  Positive-definite matrix in matrix pencil.
    *                   Only the lower triangular part of the matrix is referenced.
    * \param[in]  options A or-ed set of flags {#ComputeEigenvectors,#EigenvaluesOnly} | {#Ax_lBx,#ABx_lx,#BAx_lx}.
    *                     Default is #ComputeEigenvectors|#Ax_lBx.
    *
    * This constructor calls compute(const MatrixType&, const MatrixType&, int)
    * to compute the eigenvalues and (if requested) the eigenvectors of the
    * generalized eigenproblem \f$ Ax = \lambda B x \f$ with \a matA the
    * selfadjoint matrix \f$ A \f$ and \a matB the positive definite matrix
    * \f$ B \f$. Each eigenvector \f$ x \f$ satisfies the property
    * \f$ x^* B x = 1 \f$. The eigenvectors are computed if
    * \a options contains ComputeEigenvectors.
    *
    * In addition, the two following variants can be solved via \p options:
    * - \c ABx_lx: \f$ ABx = \lambda x \f$
    * - \c BAx_lx: \f$ BAx = \lambda x \f$
    *
    * Example: \include SelfAdjointEigenSolver_SelfAdjointEigenSolver_MatrixType2.cpp
    * Output: \verbinclude SelfAdjointEigenSolver_SelfAdjointEigenSolver_MatrixType2.out
    *
    * \sa compute(const MatrixType&, const MatrixType&, int)
    */
   GeneralizedSelfAdjointEigenSolver(const MatrixType& matA, const MatrixType& matB,
                                     int options = ComputeEigenvectors | Ax_lBx)
       : Base(matA.cols()) {
     compute(matA, matB, options);
   }

   /** \brief Computes generalized eigendecomposition of given matrix pencil.
    *
    * \param[in]  matA  Selfadjoint matrix in matrix pencil.
    *                   Only the lower triangular part of the matrix is referenced.
    * \param[in]  matB  Positive-definite matrix in matrix pencil.
    *                   Only the lower triangular part of the matrix is referenced.
    * \param[in]  options A or-ed set of flags {#ComputeEigenvectors,#EigenvaluesOnly} | {#Ax_lBx,#ABx_lx,#BAx_lx}.
    *                     Default is #ComputeEigenvectors|#Ax_lBx.
    *
    * \returns    Reference to \c *this
    *
    * According to \p options, this function computes eigenvalues and (if requested)
    * the eigenvectors of one of the following three generalized eigenproblems:
    * - \c Ax_lBx: \f$ Ax = \lambda B x \f$
    * - \c ABx_lx: \f$ ABx = \lambda x \f$
    * - \c BAx_lx: \f$ BAx = \lambda x \f$
    * with \a matA the selfadjoint matrix \f$ A \f$ and \a matB the positive definite
    * matrix \f$ B \f$.
    * In addition, each eigenvector \f$ x \f$ satisfies the property \f$ x^* B x = 1 \f$.
    *
    * The eigenvalues() function can be used to retrieve
    * the eigenvalues. If \p options contains ComputeEigenvectors, then the
    * eigenvectors are also computed and can be retrieved by calling
    * eigenvectors().
    *
    * The implementation uses LLT to compute the Cholesky decomposition
    * \f$ B = LL^* \f$ and computes the classical eigendecomposition
    * of the selfadjoint matrix \f$ L^{-1} A (L^*)^{-1} \f$ if \p options contains Ax_lBx
    * and of \f$ L^{*} A L \f$ otherwise. This solves the
    * generalized eigenproblem, because any solution of the generalized
    * eigenproblem \f$ Ax = \lambda B x \f$ corresponds to a solution
    * \f$ L^{-1} A (L^*)^{-1} (L^* x) = \lambda (L^* x) \f$ of the
    * eigenproblem for \f$ L^{-1} A (L^*)^{-1} \f$. Similar statements
    * can be made for the two other variants.
    *
    * Example: \include SelfAdjointEigenSolver_compute_MatrixType2.cpp
    * Output: \verbinclude SelfAdjointEigenSolver_compute_MatrixType2.out
    *
    * \sa GeneralizedSelfAdjointEigenSolver(const MatrixType&, const MatrixType&, int)
    */
   GeneralizedSelfAdjointEigenSolver& compute(const MatrixType& matA, const MatrixType& matB,
                                              int options = ComputeEigenvectors | Ax_lBx);

  protected:
 };

 template <typename MatrixType>
 GeneralizedSelfAdjointEigenSolver<MatrixType>& GeneralizedSelfAdjointEigenSolver<MatrixType>::compute(
     const MatrixType& matA, const MatrixType& matB, int options) {
   eigen_assert(matA.cols() == matA.rows() && matB.rows() == matA.rows() && matB.cols() == matB.rows());
   eigen_assert((options & ~(EigVecMask | GenEigMask)) == 0 && (options & EigVecMask) != EigVecMask &&
                ((options & GenEigMask) == 0 || (options & GenEigMask) == Ax_lBx || (options & GenEigMask) == ABx_lx ||
                 (options & GenEigMask) == BAx_lx) &&
                "invalid option parameter");

   bool computeEigVecs = ((options & EigVecMask) == 0) || ((options & EigVecMask) == ComputeEigenvectors);

   // Compute the cholesky decomposition of matB = L L' = U'U
   LLT<MatrixType> cholB(matB);

   int type = (options & GenEigMask);
   if (type == 0) type = Ax_lBx;

   if (type == Ax_lBx) {
     // compute C = inv(L) A inv(L')
     MatrixType matC = matA.template selfadjointView<Lower>();
     cholB.matrixL().template solveInPlace<OnTheLeft>(matC);
     cholB.matrixU().template solveInPlace<OnTheRight>(matC);

     Base::compute(matC, computeEigVecs ? ComputeEigenvectors : EigenvaluesOnly);

     // transform back the eigen vectors: evecs = inv(U) * evecs
     if (computeEigVecs) cholB.matrixU().solveInPlace(Base::m_eivec);
   } else if (type == ABx_lx) {
     // compute C = L' A L
     MatrixType matC = matA.template selfadjointView<Lower>();
     matC = matC * cholB.matrixL();
     matC = cholB.matrixU() * matC;

     Base::compute(matC, computeEigVecs ? ComputeEigenvectors : EigenvaluesOnly);

     // transform back the eigen vectors: evecs = inv(U) * evecs
     if (computeEigVecs) cholB.matrixU().solveInPlace(Base::m_eivec);
   } else if (type == BAx_lx) {
     // compute C = L' A L
     MatrixType matC = matA.template selfadjointView<Lower>();
     matC = matC * cholB.matrixL();
     matC = cholB.matrixU() * matC;

     Base::compute(matC, computeEigVecs ? ComputeEigenvectors : EigenvaluesOnly);

     // transform back the eigen vectors: evecs = L * evecs
     if (computeEigVecs) Base::m_eivec = cholB.matrixL() * Base::m_eivec;
   }

   return *this;
 }

 }  // end namespace Eigen

 #endif  // EIGEN_GENERALIZEDSELFADJOINTEIGENSOLVER_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008-2010 Gael Guennebaud <gael.guennebaud@inria.fr>
	// Copyright (C) 2010 Jitse Niesen <jitse@maths.leeds.ac.uk>
	//
	// 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_GENERALIZEDSELFADJOINTEIGENSOLVER_H
	#define EIGEN_GENERALIZEDSELFADJOINTEIGENSOLVER_H

	#include "./Tridiagonalization.h"

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

	namespace Eigen {

	/** \eigenvalues_module \ingroup Eigenvalues_Module
	*
	*
	* \class GeneralizedSelfAdjointEigenSolver
	*
	* \brief Computes eigenvalues and eigenvectors of the generalized selfadjoint eigen problem
	*
	* \tparam MatrixType_ the type of the matrix of which we are computing the
	* eigendecomposition; this is expected to be an instantiation of the Matrix
	* class template.
	*
	* This class solves the generalized eigenvalue problem
	* \f$ Av = \lambda Bv \f$. In this case, the matrix \f$ A \f$ should be
	* selfadjoint and the matrix \f$ B \f$ should be positive definite.
	*
	* Only the \b lower \b triangular \b part of the input matrix is referenced.
	*
	* Call the function compute() to compute the eigenvalues and eigenvectors of
	* a given matrix. Alternatively, you can use the
	* GeneralizedSelfAdjointEigenSolver(const MatrixType&, const MatrixType&, int)
	* constructor which computes the eigenvalues and eigenvectors at construction time.
	* Once the eigenvalue and eigenvectors are computed, they can be retrieved with the eigenvalues()
	* and eigenvectors() functions.
	*
	* The documentation for GeneralizedSelfAdjointEigenSolver(const MatrixType&, const MatrixType&, int)
	* contains an example of the typical use of this class.
	*
	* \sa class SelfAdjointEigenSolver, class EigenSolver, class ComplexEigenSolver
	*/
	template <typename MatrixType_>
	class GeneralizedSelfAdjointEigenSolver : public SelfAdjointEigenSolver<MatrixType_> {
	typedef SelfAdjointEigenSolver<MatrixType_> Base;

	public:
	typedef MatrixType_ MatrixType;

	/** \brief Default constructor for fixed-size matrices.
	*
	* The default constructor is useful in cases in which the user intends to
	* perform decompositions via compute(). This constructor
	* can only be used if \p MatrixType_ is a fixed-size matrix; use
	* GeneralizedSelfAdjointEigenSolver(Index) for dynamic-size matrices.
	*/
	GeneralizedSelfAdjointEigenSolver() : Base() {}

	/** \brief Constructor, pre-allocates memory for dynamic-size matrices.
	*
	* \param [in] size Positive integer, size of the matrix whose
	* eigenvalues and eigenvectors will be computed.
	*
	* This constructor is useful for dynamic-size matrices, when the user
	* intends to perform decompositions via compute(). The \p size
	* parameter is only used as a hint. It is not an error to give a wrong
	* \p size, but it may impair performance.
	*
	* \sa compute() for an example
	*/
	explicit GeneralizedSelfAdjointEigenSolver(Index size) : Base(size) {}

	/** \brief Constructor; computes generalized eigendecomposition of given matrix pencil.
	*
	* \param[in] matA Selfadjoint matrix in matrix pencil.
	* Only the lower triangular part of the matrix is referenced.
	* \param[in] matB Positive-definite matrix in matrix pencil.
	* Only the lower triangular part of the matrix is referenced.
	* \param[in] options A or-ed set of flags {#ComputeEigenvectors,#EigenvaluesOnly} \| {#Ax_lBx,#ABx_lx,#BAx_lx}.
	* Default is #ComputeEigenvectors\|#Ax_lBx.
	*
	* This constructor calls compute(const MatrixType&, const MatrixType&, int)
	* to compute the eigenvalues and (if requested) the eigenvectors of the
	* generalized eigenproblem \f$ Ax = \lambda B x \f$ with \a matA the
	* selfadjoint matrix \f$ A \f$ and \a matB the positive definite matrix
	* \f$ B \f$. Each eigenvector \f$ x \f$ satisfies the property
	* \f$ x^* B x = 1 \f$. The eigenvectors are computed if
	* \a options contains ComputeEigenvectors.
	*
	* In addition, the two following variants can be solved via \p options:
	* - \c ABx_lx: \f$ ABx = \lambda x \f$
	* - \c BAx_lx: \f$ BAx = \lambda x \f$
	*
	* Example: \include SelfAdjointEigenSolver_SelfAdjointEigenSolver_MatrixType2.cpp
	* Output: \verbinclude SelfAdjointEigenSolver_SelfAdjointEigenSolver_MatrixType2.out
	*
	* \sa compute(const MatrixType&, const MatrixType&, int)
	*/
	GeneralizedSelfAdjointEigenSolver(const MatrixType& matA, const MatrixType& matB,
	int options = ComputeEigenvectors \| Ax_lBx)
	: Base(matA.cols()) {
	compute(matA, matB, options);
	}

	/** \brief Computes generalized eigendecomposition of given matrix pencil.
	*
	* \param[in] matA Selfadjoint matrix in matrix pencil.
	* Only the lower triangular part of the matrix is referenced.
	* \param[in] matB Positive-definite matrix in matrix pencil.
	* Only the lower triangular part of the matrix is referenced.
	* \param[in] options A or-ed set of flags {#ComputeEigenvectors,#EigenvaluesOnly} \| {#Ax_lBx,#ABx_lx,#BAx_lx}.
	* Default is #ComputeEigenvectors\|#Ax_lBx.
	*
	* \returns Reference to \c *this
	*
	* According to \p options, this function computes eigenvalues and (if requested)
	* the eigenvectors of one of the following three generalized eigenproblems:
	* - \c Ax_lBx: \f$ Ax = \lambda B x \f$
	* - \c ABx_lx: \f$ ABx = \lambda x \f$
	* - \c BAx_lx: \f$ BAx = \lambda x \f$
	* with \a matA the selfadjoint matrix \f$ A \f$ and \a matB the positive definite
	* matrix \f$ B \f$.
	* In addition, each eigenvector \f$ x \f$ satisfies the property \f$ x^* B x = 1 \f$.
	*
	* The eigenvalues() function can be used to retrieve
	* the eigenvalues. If \p options contains ComputeEigenvectors, then the
	* eigenvectors are also computed and can be retrieved by calling
	* eigenvectors().
	*
	* The implementation uses LLT to compute the Cholesky decomposition
	* \f$ B = LL^* \f$ and computes the classical eigendecomposition
	* of the selfadjoint matrix \f$ L^{-1} A (L^*)^{-1} \f$ if \p options contains Ax_lBx
	* and of \f$ L^{*} A L \f$ otherwise. This solves the
	* generalized eigenproblem, because any solution of the generalized
	* eigenproblem \f$ Ax = \lambda B x \f$ corresponds to a solution
	* \f$ L^{-1} A (L^)^{-1} (L^ x) = \lambda (L^* x) \f$ of the
	* eigenproblem for \f$ L^{-1} A (L^*)^{-1} \f$. Similar statements
	* can be made for the two other variants.
	*
	* Example: \include SelfAdjointEigenSolver_compute_MatrixType2.cpp
	* Output: \verbinclude SelfAdjointEigenSolver_compute_MatrixType2.out
	*
	* \sa GeneralizedSelfAdjointEigenSolver(const MatrixType&, const MatrixType&, int)
	*/
	GeneralizedSelfAdjointEigenSolver& compute(const MatrixType& matA, const MatrixType& matB,
	int options = ComputeEigenvectors \| Ax_lBx);

	protected:
	};

	template <typename MatrixType>
	GeneralizedSelfAdjointEigenSolver<MatrixType>& GeneralizedSelfAdjointEigenSolver<MatrixType>::compute(
	const MatrixType& matA, const MatrixType& matB, int options) {
	eigen_assert(matA.cols() == matA.rows() && matB.rows() == matA.rows() && matB.cols() == matB.rows());
	eigen_assert((options & ~(EigVecMask \| GenEigMask)) == 0 && (options & EigVecMask) != EigVecMask &&
	((options & GenEigMask) == 0 \|\| (options & GenEigMask) == Ax_lBx \|\| (options & GenEigMask) == ABx_lx \|\|
	(options & GenEigMask) == BAx_lx) &&
	"invalid option parameter");

	bool computeEigVecs = ((options & EigVecMask) == 0) \|\| ((options & EigVecMask) == ComputeEigenvectors);

	// Compute the cholesky decomposition of matB = L L' = U'U
	LLT<MatrixType> cholB(matB);

	int type = (options & GenEigMask);
	if (type == 0) type = Ax_lBx;

	if (type == Ax_lBx) {
	// compute C = inv(L) A inv(L')
	MatrixType matC = matA.template selfadjointView<Lower>();
	cholB.matrixL().template solveInPlace<OnTheLeft>(matC);
	cholB.matrixU().template solveInPlace<OnTheRight>(matC);

	Base::compute(matC, computeEigVecs ? ComputeEigenvectors : EigenvaluesOnly);

	// transform back the eigen vectors: evecs = inv(U) * evecs
	if (computeEigVecs) cholB.matrixU().solveInPlace(Base::m_eivec);
	} else if (type == ABx_lx) {
	// compute C = L' A L
	MatrixType matC = matA.template selfadjointView<Lower>();
	matC = matC * cholB.matrixL();
	matC = cholB.matrixU() * matC;

	Base::compute(matC, computeEigVecs ? ComputeEigenvectors : EigenvaluesOnly);

	// transform back the eigen vectors: evecs = inv(U) * evecs
	if (computeEigVecs) cholB.matrixU().solveInPlace(Base::m_eivec);
	} else if (type == BAx_lx) {
	// compute C = L' A L
	MatrixType matC = matA.template selfadjointView<Lower>();
	matC = matC * cholB.matrixL();
	matC = cholB.matrixU() * matC;

	Base::compute(matC, computeEigVecs ? ComputeEigenvectors : EigenvaluesOnly);

	// transform back the eigen vectors: evecs = L * evecs
	if (computeEigVecs) Base::m_eivec = cholB.matrixL() * Base::m_eivec;
	}

	return *this;
	}

	} // end namespace Eigen

	#endif // EIGEN_GENERALIZEDSELFADJOINTEIGENSOLVER_H