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517 lines
18 KiB
C++
517 lines
18 KiB
C++
// This file is part of Eigen, a lightweight C++ template library
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// for linear algebra.
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//
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// Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>
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//
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// This Source Code Form is subject to the terms of the Mozilla
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// Public License v. 2.0. If a copy of the MPL was not distributed
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// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
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#ifndef EIGEN_LLT_H
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#define EIGEN_LLT_H
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// IWYU pragma: private
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#include "./InternalHeaderCheck.h"
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namespace Eigen {
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namespace internal {
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template <typename MatrixType_, int UpLo_>
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struct traits<LLT<MatrixType_, UpLo_> > : traits<MatrixType_> {
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typedef MatrixXpr XprKind;
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typedef SolverStorage StorageKind;
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typedef int StorageIndex;
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enum { Flags = 0 };
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};
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template <typename MatrixType, int UpLo>
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struct LLT_Traits;
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} // namespace internal
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/** \ingroup Cholesky_Module
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*
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* \class LLT
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*
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* \brief Standard Cholesky decomposition (LL^T) of a matrix and associated features
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*
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* \tparam MatrixType_ the type of the matrix of which we are computing the LL^T Cholesky decomposition
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* \tparam UpLo_ the triangular part that will be used for the decomposition: Lower (default) or Upper.
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* The other triangular part won't be read.
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*
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* This class performs a LL^T Cholesky decomposition of a symmetric, positive definite
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* matrix A such that A = LL^* = U^*U, where L is lower triangular.
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*
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* While the Cholesky decomposition is particularly useful to solve selfadjoint problems like D^*D x = b,
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* for that purpose, we recommend the Cholesky decomposition without square root which is more stable
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* and even faster. Nevertheless, this standard Cholesky decomposition remains useful in many other
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* situations like generalised eigen problems with hermitian matrices.
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*
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* Remember that Cholesky decompositions are not rank-revealing. This LLT decomposition is only stable on positive
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* definite matrices, use LDLT instead for the semidefinite case. Also, do not use a Cholesky decomposition to determine
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* whether a system of equations has a solution.
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*
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* Example: \include LLT_example.cpp
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* Output: \verbinclude LLT_example.out
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*
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* \b Performance: for best performance, it is recommended to use a column-major storage format
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* with the Lower triangular part (the default), or, equivalently, a row-major storage format
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* with the Upper triangular part. Otherwise, you might get a 20% slowdown for the full factorization
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* step, and rank-updates can be up to 3 times slower.
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*
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* This class supports the \link InplaceDecomposition inplace decomposition \endlink mechanism.
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*
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* Note that during the decomposition, only the lower (or upper, as defined by UpLo_) triangular part of A is
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* considered. Therefore, the strict lower part does not have to store correct values.
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*
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* \sa MatrixBase::llt(), SelfAdjointView::llt(), class LDLT
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*/
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template <typename MatrixType_, int UpLo_>
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class LLT : public SolverBase<LLT<MatrixType_, UpLo_> > {
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public:
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typedef MatrixType_ MatrixType;
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typedef SolverBase<LLT> Base;
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friend class SolverBase<LLT>;
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EIGEN_GENERIC_PUBLIC_INTERFACE(LLT)
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enum { MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime };
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enum { PacketSize = internal::packet_traits<Scalar>::size, AlignmentMask = int(PacketSize) - 1, UpLo = UpLo_ };
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typedef internal::LLT_Traits<MatrixType, UpLo> Traits;
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/**
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* \brief Default Constructor.
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*
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* The default constructor is useful in cases in which the user intends to
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* perform decompositions via LLT::compute(const MatrixType&).
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*/
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LLT() : m_matrix(), m_l1_norm(0), m_isInitialized(false), m_info(InvalidInput) {}
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/** \brief Default Constructor with memory preallocation
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*
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* Like the default constructor but with preallocation of the internal data
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* according to the specified problem \a size.
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* \sa LLT()
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*/
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explicit LLT(Index size) : m_matrix(size, size), m_l1_norm(0), m_isInitialized(false), m_info(InvalidInput) {}
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template <typename InputType>
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explicit LLT(const EigenBase<InputType>& matrix)
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: m_matrix(matrix.rows(), matrix.cols()), m_l1_norm(0), m_isInitialized(false), m_info(InvalidInput) {
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compute(matrix.derived());
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}
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/** \brief Constructs a LLT factorization from a given matrix
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*
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* This overloaded constructor is provided for \link InplaceDecomposition inplace decomposition \endlink when
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* \c MatrixType is a Eigen::Ref.
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*
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* \sa LLT(const EigenBase&)
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*/
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template <typename InputType>
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explicit LLT(EigenBase<InputType>& matrix)
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: m_matrix(matrix.derived()), m_l1_norm(0), m_isInitialized(false), m_info(InvalidInput) {
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compute(matrix.derived());
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}
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/** \returns a view of the upper triangular matrix U */
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inline typename Traits::MatrixU matrixU() const {
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eigen_assert(m_isInitialized && "LLT is not initialized.");
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return Traits::getU(m_matrix);
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}
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/** \returns a view of the lower triangular matrix L */
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inline typename Traits::MatrixL matrixL() const {
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eigen_assert(m_isInitialized && "LLT is not initialized.");
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return Traits::getL(m_matrix);
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}
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#ifdef EIGEN_PARSED_BY_DOXYGEN
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/** \returns the solution x of \f$ A x = b \f$ using the current decomposition of A.
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*
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* Since this LLT class assumes anyway that the matrix A is invertible, the solution
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* theoretically exists and is unique regardless of b.
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*
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* Example: \include LLT_solve.cpp
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* Output: \verbinclude LLT_solve.out
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*
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* \sa solveInPlace(), MatrixBase::llt(), SelfAdjointView::llt()
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*/
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template <typename Rhs>
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inline Solve<LLT, Rhs> solve(const MatrixBase<Rhs>& b) const;
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#endif
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template <typename Derived>
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void solveInPlace(const MatrixBase<Derived>& bAndX) const;
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template <typename InputType>
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LLT& compute(const EigenBase<InputType>& matrix);
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/** \returns an estimate of the reciprocal condition number of the matrix of
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* which \c *this is the Cholesky decomposition.
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*/
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RealScalar rcond() const {
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eigen_assert(m_isInitialized && "LLT is not initialized.");
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eigen_assert(m_info == Success && "LLT failed because matrix appears to be negative");
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return internal::rcond_estimate_helper(m_l1_norm, *this);
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}
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/** \returns the LLT decomposition matrix
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*
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* TODO: document the storage layout
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*/
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inline const MatrixType& matrixLLT() const {
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eigen_assert(m_isInitialized && "LLT is not initialized.");
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return m_matrix;
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}
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MatrixType reconstructedMatrix() const;
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/** \brief Reports whether previous computation was successful.
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*
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* \returns \c Success if computation was successful,
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* \c NumericalIssue if the matrix.appears not to be positive definite.
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*/
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ComputationInfo info() const {
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eigen_assert(m_isInitialized && "LLT is not initialized.");
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return m_info;
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}
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/** \returns the adjoint of \c *this, that is, a const reference to the decomposition itself as the underlying matrix
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* is self-adjoint.
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*
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* This method is provided for compatibility with other matrix decompositions, thus enabling generic code such as:
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* \code x = decomposition.adjoint().solve(b) \endcode
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*/
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const LLT& adjoint() const noexcept { return *this; }
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constexpr Index rows() const noexcept { return m_matrix.rows(); }
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constexpr Index cols() const noexcept { return m_matrix.cols(); }
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template <typename VectorType>
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LLT& rankUpdate(const VectorType& vec, const RealScalar& sigma = 1);
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#ifndef EIGEN_PARSED_BY_DOXYGEN
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template <typename RhsType, typename DstType>
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void _solve_impl(const RhsType& rhs, DstType& dst) const;
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template <bool Conjugate, typename RhsType, typename DstType>
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void _solve_impl_transposed(const RhsType& rhs, DstType& dst) const;
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#endif
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protected:
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EIGEN_STATIC_ASSERT_NON_INTEGER(Scalar)
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/** \internal
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* Used to compute and store L
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* The strict upper part is not used and even not initialized.
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*/
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MatrixType m_matrix;
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RealScalar m_l1_norm;
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bool m_isInitialized;
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ComputationInfo m_info;
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};
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namespace internal {
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template <typename Scalar, int UpLo>
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struct llt_inplace;
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template <typename MatrixType, typename VectorType>
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static Index llt_rank_update_lower(MatrixType& mat, const VectorType& vec,
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const typename MatrixType::RealScalar& sigma) {
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using std::sqrt;
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typedef typename MatrixType::Scalar Scalar;
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typedef typename MatrixType::RealScalar RealScalar;
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typedef typename MatrixType::ColXpr ColXpr;
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typedef internal::remove_all_t<ColXpr> ColXprCleaned;
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typedef typename ColXprCleaned::SegmentReturnType ColXprSegment;
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typedef Matrix<Scalar, Dynamic, 1> TempVectorType;
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typedef typename TempVectorType::SegmentReturnType TempVecSegment;
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Index n = mat.cols();
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eigen_assert(mat.rows() == n && vec.size() == n);
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TempVectorType temp;
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if (sigma > 0) {
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// This version is based on Givens rotations.
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// It is faster than the other one below, but only works for updates,
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// i.e., for sigma > 0
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temp = sqrt(sigma) * vec;
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for (Index i = 0; i < n; ++i) {
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JacobiRotation<Scalar> g;
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g.makeGivens(mat(i, i), -temp(i), &mat(i, i));
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Index rs = n - i - 1;
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if (rs > 0) {
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ColXprSegment x(mat.col(i).tail(rs));
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TempVecSegment y(temp.tail(rs));
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apply_rotation_in_the_plane(x, y, g);
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}
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}
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} else {
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temp = vec;
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RealScalar beta = 1;
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for (Index j = 0; j < n; ++j) {
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RealScalar Ljj = numext::real(mat.coeff(j, j));
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RealScalar dj = numext::abs2(Ljj);
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Scalar wj = temp.coeff(j);
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RealScalar swj2 = sigma * numext::abs2(wj);
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RealScalar gamma = dj * beta + swj2;
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RealScalar x = dj + swj2 / beta;
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if (x <= RealScalar(0)) return j;
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RealScalar nLjj = sqrt(x);
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mat.coeffRef(j, j) = nLjj;
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beta += swj2 / dj;
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// Update the terms of L
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Index rs = n - j - 1;
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if (rs) {
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temp.tail(rs) -= (wj / Ljj) * mat.col(j).tail(rs);
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if (!numext::is_exactly_zero(gamma))
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mat.col(j).tail(rs) =
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(nLjj / Ljj) * mat.col(j).tail(rs) + (nLjj * sigma * numext::conj(wj) / gamma) * temp.tail(rs);
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}
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}
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}
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return -1;
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}
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template <typename Scalar>
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struct llt_inplace<Scalar, Lower> {
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typedef typename NumTraits<Scalar>::Real RealScalar;
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template <typename MatrixType>
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static Index unblocked(MatrixType& mat) {
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using std::sqrt;
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eigen_assert(mat.rows() == mat.cols());
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const Index size = mat.rows();
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for (Index k = 0; k < size; ++k) {
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Index rs = size - k - 1; // remaining size
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Block<MatrixType, Dynamic, 1> A21(mat, k + 1, k, rs, 1);
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Block<MatrixType, 1, Dynamic> A10(mat, k, 0, 1, k);
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Block<MatrixType, Dynamic, Dynamic> A20(mat, k + 1, 0, rs, k);
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RealScalar x = numext::real(mat.coeff(k, k));
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if (k > 0) x -= A10.squaredNorm();
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if (x <= RealScalar(0)) return k;
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mat.coeffRef(k, k) = x = sqrt(x);
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if (k > 0 && rs > 0) A21.noalias() -= A20 * A10.adjoint();
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if (rs > 0) A21 /= x;
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}
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return -1;
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}
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template <typename MatrixType>
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static Index blocked(MatrixType& m) {
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eigen_assert(m.rows() == m.cols());
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Index size = m.rows();
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if (size < 32) return unblocked(m);
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Index blockSize = size / 8;
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blockSize = (blockSize / 16) * 16;
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blockSize = (std::min)((std::max)(blockSize, Index(8)), Index(128));
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for (Index k = 0; k < size; k += blockSize) {
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// partition the matrix:
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// A00 | - | -
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// lu = A10 | A11 | -
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// A20 | A21 | A22
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Index bs = (std::min)(blockSize, size - k);
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Index rs = size - k - bs;
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Block<MatrixType, Dynamic, Dynamic> A11(m, k, k, bs, bs);
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Block<MatrixType, Dynamic, Dynamic> A21(m, k + bs, k, rs, bs);
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Block<MatrixType, Dynamic, Dynamic> A22(m, k + bs, k + bs, rs, rs);
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Index ret;
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if ((ret = unblocked(A11)) >= 0) return k + ret;
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if (rs > 0) A11.adjoint().template triangularView<Upper>().template solveInPlace<OnTheRight>(A21);
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if (rs > 0)
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A22.template selfadjointView<Lower>().rankUpdate(A21,
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typename NumTraits<RealScalar>::Literal(-1)); // bottleneck
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}
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return -1;
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}
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template <typename MatrixType, typename VectorType>
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static Index rankUpdate(MatrixType& mat, const VectorType& vec, const RealScalar& sigma) {
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return Eigen::internal::llt_rank_update_lower(mat, vec, sigma);
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}
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};
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template <typename Scalar>
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struct llt_inplace<Scalar, Upper> {
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typedef typename NumTraits<Scalar>::Real RealScalar;
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template <typename MatrixType>
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static EIGEN_STRONG_INLINE Index unblocked(MatrixType& mat) {
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Transpose<MatrixType> matt(mat);
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return llt_inplace<Scalar, Lower>::unblocked(matt);
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}
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template <typename MatrixType>
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static EIGEN_STRONG_INLINE Index blocked(MatrixType& mat) {
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Transpose<MatrixType> matt(mat);
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return llt_inplace<Scalar, Lower>::blocked(matt);
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}
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template <typename MatrixType, typename VectorType>
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static Index rankUpdate(MatrixType& mat, const VectorType& vec, const RealScalar& sigma) {
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Transpose<MatrixType> matt(mat);
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return llt_inplace<Scalar, Lower>::rankUpdate(matt, vec.conjugate(), sigma);
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}
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};
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template <typename MatrixType>
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struct LLT_Traits<MatrixType, Lower> {
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typedef const TriangularView<const MatrixType, Lower> MatrixL;
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typedef const TriangularView<const typename MatrixType::AdjointReturnType, Upper> MatrixU;
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static inline MatrixL getL(const MatrixType& m) { return MatrixL(m); }
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static inline MatrixU getU(const MatrixType& m) { return MatrixU(m.adjoint()); }
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static bool inplace_decomposition(MatrixType& m) {
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return llt_inplace<typename MatrixType::Scalar, Lower>::blocked(m) == -1;
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}
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};
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template <typename MatrixType>
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struct LLT_Traits<MatrixType, Upper> {
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typedef const TriangularView<const typename MatrixType::AdjointReturnType, Lower> MatrixL;
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typedef const TriangularView<const MatrixType, Upper> MatrixU;
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static inline MatrixL getL(const MatrixType& m) { return MatrixL(m.adjoint()); }
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static inline MatrixU getU(const MatrixType& m) { return MatrixU(m); }
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static bool inplace_decomposition(MatrixType& m) {
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return llt_inplace<typename MatrixType::Scalar, Upper>::blocked(m) == -1;
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}
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};
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} // end namespace internal
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/** Computes / recomputes the Cholesky decomposition A = LL^* = U^*U of \a matrix
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*
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* \returns a reference to *this
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*
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* Example: \include TutorialLinAlgComputeTwice.cpp
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* Output: \verbinclude TutorialLinAlgComputeTwice.out
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*/
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template <typename MatrixType, int UpLo_>
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template <typename InputType>
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LLT<MatrixType, UpLo_>& LLT<MatrixType, UpLo_>::compute(const EigenBase<InputType>& a) {
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eigen_assert(a.rows() == a.cols());
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const Index size = a.rows();
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m_matrix.resize(size, size);
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if (!internal::is_same_dense(m_matrix, a.derived())) m_matrix = a.derived();
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// Compute matrix L1 norm = max abs column sum.
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m_l1_norm = RealScalar(0);
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// TODO: move this code to SelfAdjointView
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for (Index col = 0; col < size; ++col) {
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RealScalar abs_col_sum;
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if (UpLo_ == Lower)
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abs_col_sum =
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m_matrix.col(col).tail(size - col).template lpNorm<1>() + m_matrix.row(col).head(col).template lpNorm<1>();
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else
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abs_col_sum =
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m_matrix.col(col).head(col).template lpNorm<1>() + m_matrix.row(col).tail(size - col).template lpNorm<1>();
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if (abs_col_sum > m_l1_norm) m_l1_norm = abs_col_sum;
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}
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m_isInitialized = true;
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bool ok = Traits::inplace_decomposition(m_matrix);
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m_info = ok ? Success : NumericalIssue;
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return *this;
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}
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/** Performs a rank one update (or dowdate) of the current decomposition.
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* If A = LL^* before the rank one update,
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* then after it we have LL^* = A + sigma * v v^* where \a v must be a vector
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* of same dimension.
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*/
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template <typename MatrixType_, int UpLo_>
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template <typename VectorType>
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LLT<MatrixType_, UpLo_>& LLT<MatrixType_, UpLo_>::rankUpdate(const VectorType& v, const RealScalar& sigma) {
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EIGEN_STATIC_ASSERT_VECTOR_ONLY(VectorType);
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eigen_assert(v.size() == m_matrix.cols());
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eigen_assert(m_isInitialized);
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if (internal::llt_inplace<typename MatrixType::Scalar, UpLo>::rankUpdate(m_matrix, v, sigma) >= 0)
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m_info = NumericalIssue;
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else
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m_info = Success;
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return *this;
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}
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#ifndef EIGEN_PARSED_BY_DOXYGEN
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template <typename MatrixType_, int UpLo_>
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template <typename RhsType, typename DstType>
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void LLT<MatrixType_, UpLo_>::_solve_impl(const RhsType& rhs, DstType& dst) const {
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_solve_impl_transposed<true>(rhs, dst);
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}
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template <typename MatrixType_, int UpLo_>
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template <bool Conjugate, typename RhsType, typename DstType>
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void LLT<MatrixType_, UpLo_>::_solve_impl_transposed(const RhsType& rhs, DstType& dst) const {
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dst = rhs;
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matrixL().template conjugateIf<!Conjugate>().solveInPlace(dst);
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matrixU().template conjugateIf<!Conjugate>().solveInPlace(dst);
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}
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#endif
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|
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/** \internal use x = llt_object.solve(x);
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*
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|
* This is the \em in-place version of solve().
|
|
*
|
|
* \param bAndX represents both the right-hand side matrix b and result x.
|
|
*
|
|
* This version avoids a copy when the right hand side matrix b is not needed anymore.
|
|
*
|
|
* \warning The parameter is only marked 'const' to make the C++ compiler accept a temporary expression here.
|
|
* This function will const_cast it, so constness isn't honored here.
|
|
*
|
|
* \sa LLT::solve(), MatrixBase::llt()
|
|
*/
|
|
template <typename MatrixType, int UpLo_>
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|
template <typename Derived>
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|
void LLT<MatrixType, UpLo_>::solveInPlace(const MatrixBase<Derived>& bAndX) const {
|
|
eigen_assert(m_isInitialized && "LLT is not initialized.");
|
|
eigen_assert(m_matrix.rows() == bAndX.rows());
|
|
matrixL().solveInPlace(bAndX);
|
|
matrixU().solveInPlace(bAndX);
|
|
}
|
|
|
|
/** \returns the matrix represented by the decomposition,
|
|
* i.e., it returns the product: L L^*.
|
|
* This function is provided for debug purpose. */
|
|
template <typename MatrixType, int UpLo_>
|
|
MatrixType LLT<MatrixType, UpLo_>::reconstructedMatrix() const {
|
|
eigen_assert(m_isInitialized && "LLT is not initialized.");
|
|
return matrixL() * matrixL().adjoint().toDenseMatrix();
|
|
}
|
|
|
|
/** \cholesky_module
|
|
* \returns the LLT decomposition of \c *this
|
|
* \sa SelfAdjointView::llt()
|
|
*/
|
|
template <typename Derived>
|
|
inline LLT<typename MatrixBase<Derived>::PlainObject> MatrixBase<Derived>::llt() const {
|
|
return LLT<PlainObject>(derived());
|
|
}
|
|
|
|
/** \cholesky_module
|
|
* \returns the LLT decomposition of \c *this
|
|
* \sa SelfAdjointView::llt()
|
|
*/
|
|
template <typename MatrixType, unsigned int UpLo>
|
|
inline LLT<typename SelfAdjointView<MatrixType, UpLo>::PlainObject, UpLo> SelfAdjointView<MatrixType, UpLo>::llt()
|
|
const {
|
|
return LLT<PlainObject, UpLo>(m_matrix);
|
|
}
|
|
|
|
} // end namespace Eigen
|
|
|
|
#endif // EIGEN_LLT_H
|