Eigen/src/Eigenvalues/MatrixBaseEigenvalues.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008 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_MATRIXBASEEIGENVALUES_H
 #define EIGEN_MATRIXBASEEIGENVALUES_H

 namespace Eigen {

 namespace internal {

 template<typename Derived, bool IsComplex>
 struct eigenvalues_selector
 {
   // this is the implementation for the case IsComplex = true
   static inline typename MatrixBase<Derived>::EigenvaluesReturnType const
   run(const MatrixBase<Derived>& m)
   {
     typedef typename Derived::PlainObject PlainObject;
     PlainObject m_eval(m);
     return ComplexEigenSolver<PlainObject>(m_eval, false).eigenvalues();
   }
 };

 template<typename Derived>
 struct eigenvalues_selector<Derived, false>
 {
   static inline typename MatrixBase<Derived>::EigenvaluesReturnType const
   run(const MatrixBase<Derived>& m)
   {
     typedef typename Derived::PlainObject PlainObject;
     PlainObject m_eval(m);
     return EigenSolver<PlainObject>(m_eval, false).eigenvalues();
   }
 };

 } // end namespace internal

 /** \brief Computes the eigenvalues of a matrix
   * \returns Column vector containing the eigenvalues.
   *
   * \eigenvalues_module
   * This function computes the eigenvalues with the help of the EigenSolver
   * class (for real matrices) or the ComplexEigenSolver class (for complex
   * matrices).
   *
   * The eigenvalues are repeated according to their algebraic multiplicity,
   * so there are as many eigenvalues as rows in the matrix.
   *
   * The SelfAdjointView class provides a better algorithm for selfadjoint
   * matrices.
   *
   * Example: \include MatrixBase_eigenvalues.cpp
   * Output: \verbinclude MatrixBase_eigenvalues.out
   *
   * \sa EigenSolver::eigenvalues(), ComplexEigenSolver::eigenvalues(),
   *     SelfAdjointView::eigenvalues()
   */
 template<typename Derived>
 inline typename MatrixBase<Derived>::EigenvaluesReturnType
 MatrixBase<Derived>::eigenvalues() const
 {
   return internal::eigenvalues_selector<Derived, NumTraits<Scalar>::IsComplex>::run(derived());
 }

 /** \brief Computes the eigenvalues of a matrix
   * \returns Column vector containing the eigenvalues.
   *
   * \eigenvalues_module
   * This function computes the eigenvalues with the help of the
   * SelfAdjointEigenSolver class.  The eigenvalues are repeated according to
   * their algebraic multiplicity, so there are as many eigenvalues as rows in
   * the matrix.
   *
   * Example: \include SelfAdjointView_eigenvalues.cpp
   * Output: \verbinclude SelfAdjointView_eigenvalues.out
   *
   * \sa SelfAdjointEigenSolver::eigenvalues(), MatrixBase::eigenvalues()
   */
 template<typename MatrixType, unsigned int UpLo>
 inline typename SelfAdjointView<MatrixType, UpLo>::EigenvaluesReturnType
 SelfAdjointView<MatrixType, UpLo>::eigenvalues() const
 {
   PlainObject thisAsMatrix(*this);
   return SelfAdjointEigenSolver<PlainObject>(thisAsMatrix, false).eigenvalues();
 }


 /** \brief Computes the L2 operator norm
   * \returns Operator norm of the matrix.
   *
   * \eigenvalues_module
   * This function computes the L2 operator norm of a matrix, which is also
   * known as the spectral norm. The norm of a matrix \f$ A \f$ is defined to be
   * \f[ \|A\|_2 = \max_x \frac{\|Ax\|_2}{\|x\|_2} \f]
   * where the maximum is over all vectors and the norm on the right is the
   * Euclidean vector norm. The norm equals the largest singular value, which is
   * the square root of the largest eigenvalue of the positive semi-definite
   * matrix \f$ A^*A \f$.
   *
   * The current implementation uses the eigenvalues of \f$ A^*A \f$, as computed
   * by SelfAdjointView::eigenvalues(), to compute the operator norm of a
   * matrix.  The SelfAdjointView class provides a better algorithm for
   * selfadjoint matrices.
   *
   * Example: \include MatrixBase_operatorNorm.cpp
   * Output: \verbinclude MatrixBase_operatorNorm.out
   *
   * \sa SelfAdjointView::eigenvalues(), SelfAdjointView::operatorNorm()
   */
 template<typename Derived>
 inline typename MatrixBase<Derived>::RealScalar
 MatrixBase<Derived>::operatorNorm() const
 {
   using std::sqrt;
   typename Derived::PlainObject m_eval(derived());
   // FIXME if it is really guaranteed that the eigenvalues are already sorted,
   // then we don't need to compute a maxCoeff() here, comparing the 1st and last ones is enough.
   return sqrt((m_eval*m_eval.adjoint())
                  .eval()
 		 .template selfadjointView<Lower>()
 		 .eigenvalues()
 		 .maxCoeff()
 		 );
 }

 /** \brief Computes the L2 operator norm
   * \returns Operator norm of the matrix.
   *
   * \eigenvalues_module
   * This function computes the L2 operator norm of a self-adjoint matrix. For a
   * self-adjoint matrix, the operator norm is the largest eigenvalue.
   *
   * The current implementation uses the eigenvalues of the matrix, as computed
   * by eigenvalues(), to compute the operator norm of the matrix.
   *
   * Example: \include SelfAdjointView_operatorNorm.cpp
   * Output: \verbinclude SelfAdjointView_operatorNorm.out
   *
   * \sa eigenvalues(), MatrixBase::operatorNorm()
   */
 template<typename MatrixType, unsigned int UpLo>
 inline typename SelfAdjointView<MatrixType, UpLo>::RealScalar
 SelfAdjointView<MatrixType, UpLo>::operatorNorm() const
 {
   return eigenvalues().cwiseAbs().maxCoeff();
 }

 } // end namespace Eigen

 #endif
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008 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_MATRIXBASEEIGENVALUES_H
	#define EIGEN_MATRIXBASEEIGENVALUES_H

	namespace Eigen {

	namespace internal {

	template<typename Derived, bool IsComplex>
	struct eigenvalues_selector
	{
	// this is the implementation for the case IsComplex = true
	static inline typename MatrixBase<Derived>::EigenvaluesReturnType const
	run(const MatrixBase<Derived>& m)
	{
	typedef typename Derived::PlainObject PlainObject;
	PlainObject m_eval(m);
	return ComplexEigenSolver<PlainObject>(m_eval, false).eigenvalues();
	}
	};

	template<typename Derived>
	struct eigenvalues_selector<Derived, false>
	{
	static inline typename MatrixBase<Derived>::EigenvaluesReturnType const
	run(const MatrixBase<Derived>& m)
	{
	typedef typename Derived::PlainObject PlainObject;
	PlainObject m_eval(m);
	return EigenSolver<PlainObject>(m_eval, false).eigenvalues();
	}
	};

	} // end namespace internal

	/** \brief Computes the eigenvalues of a matrix
	* \returns Column vector containing the eigenvalues.
	*
	* \eigenvalues_module
	* This function computes the eigenvalues with the help of the EigenSolver
	* class (for real matrices) or the ComplexEigenSolver class (for complex
	* matrices).
	*
	* The eigenvalues are repeated according to their algebraic multiplicity,
	* so there are as many eigenvalues as rows in the matrix.
	*
	* The SelfAdjointView class provides a better algorithm for selfadjoint
	* matrices.
	*
	* Example: \include MatrixBase_eigenvalues.cpp
	* Output: \verbinclude MatrixBase_eigenvalues.out
	*
	* \sa EigenSolver::eigenvalues(), ComplexEigenSolver::eigenvalues(),
	* SelfAdjointView::eigenvalues()
	*/
	template<typename Derived>
	inline typename MatrixBase<Derived>::EigenvaluesReturnType
	MatrixBase<Derived>::eigenvalues() const
	{
	return internal::eigenvalues_selector<Derived, NumTraits<Scalar>::IsComplex>::run(derived());
	}

	/** \brief Computes the eigenvalues of a matrix
	* \returns Column vector containing the eigenvalues.
	*
	* \eigenvalues_module
	* This function computes the eigenvalues with the help of the
	* SelfAdjointEigenSolver class. The eigenvalues are repeated according to
	* their algebraic multiplicity, so there are as many eigenvalues as rows in
	* the matrix.
	*
	* Example: \include SelfAdjointView_eigenvalues.cpp
	* Output: \verbinclude SelfAdjointView_eigenvalues.out
	*
	* \sa SelfAdjointEigenSolver::eigenvalues(), MatrixBase::eigenvalues()
	*/
	template<typename MatrixType, unsigned int UpLo>
	inline typename SelfAdjointView<MatrixType, UpLo>::EigenvaluesReturnType
	SelfAdjointView<MatrixType, UpLo>::eigenvalues() const
	{
	PlainObject thisAsMatrix(*this);
	return SelfAdjointEigenSolver<PlainObject>(thisAsMatrix, false).eigenvalues();
	}



	/** \brief Computes the L2 operator norm
	* \returns Operator norm of the matrix.
	*
	* \eigenvalues_module
	* This function computes the L2 operator norm of a matrix, which is also
	* known as the spectral norm. The norm of a matrix \f$ A \f$ is defined to be
	* \f[ \\|A\\|_2 = \max_x \frac{\\|Ax\\|_2}{\\|x\\|_2} \f]
	* where the maximum is over all vectors and the norm on the right is the
	* Euclidean vector norm. The norm equals the largest singular value, which is
	* the square root of the largest eigenvalue of the positive semi-definite
	* matrix \f$ A^*A \f$.
	*
	* The current implementation uses the eigenvalues of \f$ A^*A \f$, as computed
	* by SelfAdjointView::eigenvalues(), to compute the operator norm of a
	* matrix. The SelfAdjointView class provides a better algorithm for
	* selfadjoint matrices.
	*
	* Example: \include MatrixBase_operatorNorm.cpp
	* Output: \verbinclude MatrixBase_operatorNorm.out
	*
	* \sa SelfAdjointView::eigenvalues(), SelfAdjointView::operatorNorm()
	*/
	template<typename Derived>
	inline typename MatrixBase<Derived>::RealScalar
	MatrixBase<Derived>::operatorNorm() const
	{
	using std::sqrt;
	typename Derived::PlainObject m_eval(derived());
	// FIXME if it is really guaranteed that the eigenvalues are already sorted,
	// then we don't need to compute a maxCoeff() here, comparing the 1st and last ones is enough.
	return sqrt((m_eval*m_eval.adjoint())
	.eval()
	.template selfadjointView<Lower>()
	.eigenvalues()
	.maxCoeff()
	);
	}

	/** \brief Computes the L2 operator norm
	* \returns Operator norm of the matrix.
	*
	* \eigenvalues_module
	* This function computes the L2 operator norm of a self-adjoint matrix. For a
	* self-adjoint matrix, the operator norm is the largest eigenvalue.
	*
	* The current implementation uses the eigenvalues of the matrix, as computed
	* by eigenvalues(), to compute the operator norm of the matrix.
	*
	* Example: \include SelfAdjointView_operatorNorm.cpp
	* Output: \verbinclude SelfAdjointView_operatorNorm.out
	*
	* \sa eigenvalues(), MatrixBase::operatorNorm()
	*/
	template<typename MatrixType, unsigned int UpLo>
	inline typename SelfAdjointView<MatrixType, UpLo>::RealScalar
	SelfAdjointView<MatrixType, UpLo>::operatorNorm() const
	{
	return eigenvalues().cwiseAbs().maxCoeff();
	}

	} // end namespace Eigen

	#endif