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Diffstat (limited to 'extern/Eigen2/Eigen/src/Cholesky/LLT.h')
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diff --git a/extern/Eigen2/Eigen/src/Cholesky/LLT.h b/extern/Eigen2/Eigen/src/Cholesky/LLT.h new file mode 100644 index 00000000000..42c959f83a2 --- /dev/null +++ b/extern/Eigen2/Eigen/src/Cholesky/LLT.h @@ -0,0 +1,219 @@ +// This file is part of Eigen, a lightweight C++ template library +// for linear algebra. +// +// Copyright (C) 2008 Gael Guennebaud <g.gael@free.fr> +// +// Eigen is free software; you can redistribute it and/or +// modify it under the terms of the GNU Lesser General Public +// License as published by the Free Software Foundation; either +// version 3 of the License, or (at your option) any later version. +// +// Alternatively, you can redistribute it and/or +// modify it under the terms of the GNU General Public License as +// published by the Free Software Foundation; either version 2 of +// the License, or (at your option) any later version. +// +// Eigen is distributed in the hope that it will be useful, but WITHOUT ANY +// WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS +// FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License or the +// GNU General Public License for more details. +// +// You should have received a copy of the GNU Lesser General Public +// License and a copy of the GNU General Public License along with +// Eigen. If not, see <http://www.gnu.org/licenses/>. + +#ifndef EIGEN_LLT_H +#define EIGEN_LLT_H + +/** \ingroup cholesky_Module + * + * \class LLT + * + * \brief Standard Cholesky decomposition (LL^T) of a matrix and associated features + * + * \param MatrixType the type of the matrix of which we are computing the LL^T Cholesky decomposition + * + * This class performs a LL^T Cholesky decomposition of a symmetric, positive definite + * matrix A such that A = LL^* = U^*U, where L is lower triangular. + * + * While the Cholesky decomposition is particularly useful to solve selfadjoint problems like D^*D x = b, + * for that purpose, we recommend the Cholesky decomposition without square root which is more stable + * and even faster. Nevertheless, this standard Cholesky decomposition remains useful in many other + * situations like generalised eigen problems with hermitian matrices. + * + * Remember that Cholesky decompositions are not rank-revealing. This LLT decomposition is only stable on positive definite matrices, + * use LDLT instead for the semidefinite case. Also, do not use a Cholesky decomposition to determine whether a system of equations + * has a solution. + * + * \sa MatrixBase::llt(), class LDLT + */ + /* HEY THIS DOX IS DISABLED BECAUSE THERE's A BUG EITHER HERE OR IN LDLT ABOUT THAT (OR BOTH) + * Note that during the decomposition, only the upper triangular part of A is considered. Therefore, + * the strict lower part does not have to store correct values. + */ +template<typename MatrixType> class LLT +{ + private: + typedef typename MatrixType::Scalar Scalar; + typedef typename NumTraits<typename MatrixType::Scalar>::Real RealScalar; + typedef Matrix<Scalar, MatrixType::ColsAtCompileTime, 1> VectorType; + + enum { + PacketSize = ei_packet_traits<Scalar>::size, + AlignmentMask = int(PacketSize)-1 + }; + + public: + + /** + * \brief Default Constructor. + * + * The default constructor is useful in cases in which the user intends to + * perform decompositions via LLT::compute(const MatrixType&). + */ + LLT() : m_matrix(), m_isInitialized(false) {} + + LLT(const MatrixType& matrix) + : m_matrix(matrix.rows(), matrix.cols()), + m_isInitialized(false) + { + compute(matrix); + } + + /** \returns the lower triangular matrix L */ + inline Part<MatrixType, LowerTriangular> matrixL(void) const + { + ei_assert(m_isInitialized && "LLT is not initialized."); + return m_matrix; + } + + /** \deprecated */ + inline bool isPositiveDefinite(void) const { return m_isInitialized && m_isPositiveDefinite; } + + template<typename RhsDerived, typename ResultType> + bool solve(const MatrixBase<RhsDerived> &b, ResultType *result) const; + + template<typename Derived> + bool solveInPlace(MatrixBase<Derived> &bAndX) const; + + void compute(const MatrixType& matrix); + + protected: + /** \internal + * Used to compute and store L + * The strict upper part is not used and even not initialized. + */ + MatrixType m_matrix; + bool m_isInitialized; + bool m_isPositiveDefinite; +}; + +/** Computes / recomputes the Cholesky decomposition A = LL^* = U^*U of \a matrix + */ +template<typename MatrixType> +void LLT<MatrixType>::compute(const MatrixType& a) +{ + assert(a.rows()==a.cols()); + m_isPositiveDefinite = true; + const int size = a.rows(); + m_matrix.resize(size, size); + // The biggest overall is the point of reference to which further diagonals + // are compared; if any diagonal is negligible compared + // to the largest overall, the algorithm bails. This cutoff is suggested + // in "Analysis of the Cholesky Decomposition of a Semi-definite Matrix" by + // Nicholas J. Higham. Also see "Accuracy and Stability of Numerical + // Algorithms" page 217, also by Higham. + const RealScalar cutoff = machine_epsilon<Scalar>() * size * a.diagonal().cwise().abs().maxCoeff(); + RealScalar x; + x = ei_real(a.coeff(0,0)); + m_matrix.coeffRef(0,0) = ei_sqrt(x); + if(size==1) + { + m_isInitialized = true; + return; + } + m_matrix.col(0).end(size-1) = a.row(0).end(size-1).adjoint() / ei_real(m_matrix.coeff(0,0)); + for (int j = 1; j < size; ++j) + { + x = ei_real(a.coeff(j,j)) - m_matrix.row(j).start(j).squaredNorm(); + if (x < cutoff) + { + m_isPositiveDefinite = false; + continue; + } + + m_matrix.coeffRef(j,j) = x = ei_sqrt(x); + + int endSize = size-j-1; + if (endSize>0) { + // Note that when all matrix columns have good alignment, then the following + // product is guaranteed to be optimal with respect to alignment. + m_matrix.col(j).end(endSize) = + (m_matrix.block(j+1, 0, endSize, j) * m_matrix.row(j).start(j).adjoint()).lazy(); + + // FIXME could use a.col instead of a.row + m_matrix.col(j).end(endSize) = (a.row(j).end(endSize).adjoint() + - m_matrix.col(j).end(endSize) ) / x; + } + } + + m_isInitialized = true; +} + +/** Computes the solution x of \f$ A x = b \f$ using the current decomposition of A. + * The result is stored in \a result + * + * \returns true always! If you need to check for existence of solutions, use another decomposition like LU, QR, or SVD. + * + * In other words, it computes \f$ b = A^{-1} b \f$ with + * \f$ {L^{*}}^{-1} L^{-1} b \f$ from right to left. + * + * Example: \include LLT_solve.cpp + * Output: \verbinclude LLT_solve.out + * + * \sa LLT::solveInPlace(), MatrixBase::llt() + */ +template<typename MatrixType> +template<typename RhsDerived, typename ResultType> +bool LLT<MatrixType>::solve(const MatrixBase<RhsDerived> &b, ResultType *result) const +{ + ei_assert(m_isInitialized && "LLT is not initialized."); + const int size = m_matrix.rows(); + ei_assert(size==b.rows() && "LLT::solve(): invalid number of rows of the right hand side matrix b"); + return solveInPlace((*result) = b); +} + +/** This is the \em in-place version of solve(). + * + * \param bAndX represents both the right-hand side matrix b and result x. + * + * \returns true always! If you need to check for existence of solutions, use another decomposition like LU, QR, or SVD. + * + * This version avoids a copy when the right hand side matrix b is not + * needed anymore. + * + * \sa LLT::solve(), MatrixBase::llt() + */ +template<typename MatrixType> +template<typename Derived> +bool LLT<MatrixType>::solveInPlace(MatrixBase<Derived> &bAndX) const +{ + ei_assert(m_isInitialized && "LLT is not initialized."); + const int size = m_matrix.rows(); + ei_assert(size==bAndX.rows()); + matrixL().solveTriangularInPlace(bAndX); + m_matrix.adjoint().template part<UpperTriangular>().solveTriangularInPlace(bAndX); + return true; +} + +/** \cholesky_module + * \returns the LLT decomposition of \c *this + */ +template<typename Derived> +inline const LLT<typename MatrixBase<Derived>::PlainMatrixType> +MatrixBase<Derived>::llt() const +{ + return LLT<PlainMatrixType>(derived()); +} + +#endif // EIGEN_LLT_H |