// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2006-2009 Benoit Jacob // Copyright (C) 2009 Gael Guennebaud // // 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_PARTIALLU_H #define EIGEN_PARTIALLU_H // IWYU pragma: private #include "./InternalHeaderCheck.h" namespace Eigen { namespace internal { template struct traits > : traits { typedef MatrixXpr XprKind; typedef SolverStorage StorageKind; typedef PermutationIndex_ StorageIndex; typedef traits BaseTraits; enum { Flags = BaseTraits::Flags & RowMajorBit, CoeffReadCost = Dynamic }; }; template struct enable_if_ref; // { // typedef Derived type; // }; template struct enable_if_ref, Derived> { typedef Derived type; }; } // end namespace internal /** \ingroup LU_Module * * \class PartialPivLU * * \brief LU decomposition of a matrix with partial pivoting, and related features * * \tparam MatrixType_ the type of the matrix of which we are computing the LU decomposition * * This class represents a LU decomposition of a \b square \b invertible matrix, with partial pivoting: the matrix A * is decomposed as A = PLU where L is unit-lower-triangular, U is upper-triangular, and P * is a permutation matrix. * * Typically, partial pivoting LU decomposition is only considered numerically stable for square invertible * matrices. Thus LAPACK's dgesv and dgesvx require the matrix to be square and invertible. The present class * does the same. It will assert that the matrix is square, but it won't (actually it can't) check that the * matrix is invertible: it is your task to check that you only use this decomposition on invertible matrices. * * The guaranteed safe alternative, working for all matrices, is the full pivoting LU decomposition, provided * by class FullPivLU. * * This is \b not a rank-revealing LU decomposition. Many features are intentionally absent from this class, * such as rank computation. If you need these features, use class FullPivLU. * * This LU decomposition is suitable to invert invertible matrices. It is what MatrixBase::inverse() uses * in the general case. * On the other hand, it is \b not suitable to determine whether a given matrix is invertible. * * The data of the LU decomposition can be directly accessed through the methods matrixLU(), permutationP(). * * This class supports the \link InplaceDecomposition inplace decomposition \endlink mechanism. * * \sa MatrixBase::partialPivLu(), MatrixBase::determinant(), MatrixBase::inverse(), MatrixBase::computeInverse(), class * FullPivLU */ template class PartialPivLU : public SolverBase > { public: typedef MatrixType_ MatrixType; typedef SolverBase Base; friend class SolverBase; EIGEN_GENERIC_PUBLIC_INTERFACE(PartialPivLU) enum { MaxRowsAtCompileTime = MatrixType::MaxRowsAtCompileTime, MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime }; using PermutationIndex = PermutationIndex_; typedef PermutationMatrix PermutationType; typedef Transpositions TranspositionType; typedef typename MatrixType::PlainObject PlainObject; /** * \brief Default Constructor. * * The default constructor is useful in cases in which the user intends to * perform decompositions via PartialPivLU::compute(const MatrixType&). */ PartialPivLU(); /** \brief Default Constructor with memory preallocation * * Like the default constructor but with preallocation of the internal data * according to the specified problem \a size. * \sa PartialPivLU() */ explicit PartialPivLU(Index size); /** Constructor. * * \param matrix the matrix of which to compute the LU decomposition. * * \warning The matrix should have full rank (e.g. if it's square, it should be invertible). * If you need to deal with non-full rank, use class FullPivLU instead. */ template explicit PartialPivLU(const EigenBase& matrix); /** Constructor for \link InplaceDecomposition inplace decomposition \endlink * * \param matrix the matrix of which to compute the LU decomposition. * * \warning The matrix should have full rank (e.g. if it's square, it should be invertible). * If you need to deal with non-full rank, use class FullPivLU instead. */ template explicit PartialPivLU(EigenBase& matrix); template PartialPivLU& compute(const EigenBase& matrix) { m_lu = matrix.derived(); compute(); return *this; } /** \returns the LU decomposition matrix: the upper-triangular part is U, the * unit-lower-triangular part is L (at least for square matrices; in the non-square * case, special care is needed, see the documentation of class FullPivLU). * * \sa matrixL(), matrixU() */ inline const MatrixType& matrixLU() const { eigen_assert(m_isInitialized && "PartialPivLU is not initialized."); return m_lu; } /** \returns the permutation matrix P. */ inline const PermutationType& permutationP() const { eigen_assert(m_isInitialized && "PartialPivLU is not initialized."); return m_p; } #ifdef EIGEN_PARSED_BY_DOXYGEN /** This method returns the solution x to the equation Ax=b, where A is the matrix of which * *this is the LU decomposition. * * \param b the right-hand-side of the equation to solve. Can be a vector or a matrix, * the only requirement in order for the equation to make sense is that * b.rows()==A.rows(), where A is the matrix of which *this is the LU decomposition. * * \returns the solution. * * Example: \include PartialPivLU_solve.cpp * Output: \verbinclude PartialPivLU_solve.out * * Since this PartialPivLU class assumes anyway that the matrix A is invertible, the solution * theoretically exists and is unique regardless of b. * * \sa TriangularView::solve(), inverse(), computeInverse() */ template inline const Solve solve(const MatrixBase& b) const; #endif /** \returns an estimate of the reciprocal condition number of the matrix of which \c *this is the LU decomposition. */ inline RealScalar rcond() const { eigen_assert(m_isInitialized && "PartialPivLU is not initialized."); return internal::rcond_estimate_helper(m_l1_norm, *this); } /** \returns the inverse of the matrix of which *this is the LU decomposition. * * \warning The matrix being decomposed here is assumed to be invertible. If you need to check for * invertibility, use class FullPivLU instead. * * \sa MatrixBase::inverse(), LU::inverse() */ inline const Inverse inverse() const { eigen_assert(m_isInitialized && "PartialPivLU is not initialized."); return Inverse(*this); } /** \returns the determinant of the matrix of which * *this is the LU decomposition. It has only linear complexity * (that is, O(n) where n is the dimension of the square matrix) * as the LU decomposition has already been computed. * * \note For fixed-size matrices of size up to 4, MatrixBase::determinant() offers * optimized paths. * * \warning a determinant can be very big or small, so for matrices * of large enough dimension, there is a risk of overflow/underflow. * * \sa MatrixBase::determinant() */ Scalar determinant() const; MatrixType reconstructedMatrix() const; EIGEN_CONSTEXPR inline Index rows() const EIGEN_NOEXCEPT { return m_lu.rows(); } EIGEN_CONSTEXPR inline Index cols() const EIGEN_NOEXCEPT { return m_lu.cols(); } #ifndef EIGEN_PARSED_BY_DOXYGEN template EIGEN_DEVICE_FUNC void _solve_impl(const RhsType& rhs, DstType& dst) const { /* The decomposition PA = LU can be rewritten as A = P^{-1} L U. * So we proceed as follows: * Step 1: compute c = Pb. * Step 2: replace c by the solution x to Lx = c. * Step 3: replace c by the solution x to Ux = c. */ // Step 1 dst = permutationP() * rhs; // Step 2 m_lu.template triangularView().solveInPlace(dst); // Step 3 m_lu.template triangularView().solveInPlace(dst); } template EIGEN_DEVICE_FUNC void _solve_impl_transposed(const RhsType& rhs, DstType& dst) const { /* The decomposition PA = LU can be rewritten as A^T = U^T L^T P. * So we proceed as follows: * Step 1: compute c as the solution to L^T c = b * Step 2: replace c by the solution x to U^T x = c. * Step 3: update c = P^-1 c. */ eigen_assert(rhs.rows() == m_lu.cols()); // Step 1 dst = m_lu.template triangularView().transpose().template conjugateIf().solve(rhs); // Step 2 m_lu.template triangularView().transpose().template conjugateIf().solveInPlace(dst); // Step 3 dst = permutationP().transpose() * dst; } #endif protected: EIGEN_STATIC_ASSERT_NON_INTEGER(Scalar) void compute(); MatrixType m_lu; PermutationType m_p; TranspositionType m_rowsTranspositions; RealScalar m_l1_norm; signed char m_det_p; bool m_isInitialized; }; template PartialPivLU::PartialPivLU() : m_lu(), m_p(), m_rowsTranspositions(), m_l1_norm(0), m_det_p(0), m_isInitialized(false) {} template PartialPivLU::PartialPivLU(Index size) : m_lu(size, size), m_p(size), m_rowsTranspositions(size), m_l1_norm(0), m_det_p(0), m_isInitialized(false) {} template template PartialPivLU::PartialPivLU(const EigenBase& matrix) : m_lu(matrix.rows(), matrix.cols()), m_p(matrix.rows()), m_rowsTranspositions(matrix.rows()), m_l1_norm(0), m_det_p(0), m_isInitialized(false) { compute(matrix.derived()); } template template PartialPivLU::PartialPivLU(EigenBase& matrix) : m_lu(matrix.derived()), m_p(matrix.rows()), m_rowsTranspositions(matrix.rows()), m_l1_norm(0), m_det_p(0), m_isInitialized(false) { compute(); } namespace internal { /** \internal This is the blocked version of fullpivlu_unblocked() */ template struct partial_lu_impl { static constexpr int UnBlockedBound = 16; static constexpr bool UnBlockedAtCompileTime = SizeAtCompileTime != Dynamic && SizeAtCompileTime <= UnBlockedBound; static constexpr int ActualSizeAtCompileTime = UnBlockedAtCompileTime ? SizeAtCompileTime : Dynamic; // Remaining rows and columns at compile-time: static constexpr int RRows = SizeAtCompileTime == 2 ? 1 : Dynamic; static constexpr int RCols = SizeAtCompileTime == 2 ? 1 : Dynamic; typedef Matrix MatrixType; typedef Ref MatrixTypeRef; typedef Ref > BlockType; typedef typename MatrixType::RealScalar RealScalar; /** \internal performs the LU decomposition in-place of the matrix \a lu * using an unblocked algorithm. * * In addition, this function returns the row transpositions in the * vector \a row_transpositions which must have a size equal to the number * of columns of the matrix \a lu, and an integer \a nb_transpositions * which returns the actual number of transpositions. * * \returns The index of the first pivot which is exactly zero if any, or a negative number otherwise. */ static Index unblocked_lu(MatrixTypeRef& lu, PivIndex* row_transpositions, PivIndex& nb_transpositions) { typedef scalar_score_coeff_op Scoring; typedef typename Scoring::result_type Score; const Index rows = lu.rows(); const Index cols = lu.cols(); const Index size = (std::min)(rows, cols); // For small compile-time matrices it is worth processing the last row separately: // speedup: +100% for 2x2, +10% for others. const Index endk = UnBlockedAtCompileTime ? size - 1 : size; nb_transpositions = 0; Index first_zero_pivot = -1; for (Index k = 0; k < endk; ++k) { int rrows = internal::convert_index(rows - k - 1); int rcols = internal::convert_index(cols - k - 1); Index row_of_biggest_in_col; Score biggest_in_corner = lu.col(k).tail(rows - k).unaryExpr(Scoring()).maxCoeff(&row_of_biggest_in_col); row_of_biggest_in_col += k; row_transpositions[k] = PivIndex(row_of_biggest_in_col); if (!numext::is_exactly_zero(biggest_in_corner)) { if (k != row_of_biggest_in_col) { lu.row(k).swap(lu.row(row_of_biggest_in_col)); ++nb_transpositions; } lu.col(k).tail(fix(rrows)) /= lu.coeff(k, k); } else if (first_zero_pivot == -1) { // the pivot is exactly zero, we record the index of the first pivot which is exactly 0, // and continue the factorization such we still have A = PLU first_zero_pivot = k; } if (k < rows - 1) lu.bottomRightCorner(fix(rrows), fix(rcols)).noalias() -= lu.col(k).tail(fix(rrows)) * lu.row(k).tail(fix(rcols)); } // special handling of the last entry if (UnBlockedAtCompileTime) { Index k = endk; row_transpositions[k] = PivIndex(k); if (numext::is_exactly_zero(Scoring()(lu(k, k))) && first_zero_pivot == -1) first_zero_pivot = k; } return first_zero_pivot; } /** \internal performs the LU decomposition in-place of the matrix represented * by the variables \a rows, \a cols, \a lu_data, and \a lu_stride using a * recursive, blocked algorithm. * * In addition, this function returns the row transpositions in the * vector \a row_transpositions which must have a size equal to the number * of columns of the matrix \a lu, and an integer \a nb_transpositions * which returns the actual number of transpositions. * * \returns The index of the first pivot which is exactly zero if any, or a negative number otherwise. * * \note This very low level interface using pointers, etc. is to: * 1 - reduce the number of instantiations to the strict minimum * 2 - avoid infinite recursion of the instantiations with Block > > */ static Index blocked_lu(Index rows, Index cols, Scalar* lu_data, Index luStride, PivIndex* row_transpositions, PivIndex& nb_transpositions, Index maxBlockSize = 256) { MatrixTypeRef lu = MatrixType::Map(lu_data, rows, cols, OuterStride<>(luStride)); const Index size = (std::min)(rows, cols); // if the matrix is too small, no blocking: if (UnBlockedAtCompileTime || size <= UnBlockedBound) { return unblocked_lu(lu, row_transpositions, nb_transpositions); } // automatically adjust the number of subdivisions to the size // of the matrix so that there is enough sub blocks: Index blockSize; { blockSize = size / 8; blockSize = (blockSize / 16) * 16; blockSize = (std::min)((std::max)(blockSize, Index(8)), maxBlockSize); } nb_transpositions = 0; Index first_zero_pivot = -1; for (Index k = 0; k < size; k += blockSize) { Index bs = (std::min)(size - k, blockSize); // actual size of the block Index trows = rows - k - bs; // trailing rows Index tsize = size - k - bs; // trailing size // partition the matrix: // A00 | A01 | A02 // lu = A_0 | A_1 | A_2 = A10 | A11 | A12 // A20 | A21 | A22 BlockType A_0 = lu.block(0, 0, rows, k); BlockType A_2 = lu.block(0, k + bs, rows, tsize); BlockType A11 = lu.block(k, k, bs, bs); BlockType A12 = lu.block(k, k + bs, bs, tsize); BlockType A21 = lu.block(k + bs, k, trows, bs); BlockType A22 = lu.block(k + bs, k + bs, trows, tsize); PivIndex nb_transpositions_in_panel; // recursively call the blocked LU algorithm on [A11^T A21^T]^T // with a very small blocking size: Index ret = blocked_lu(trows + bs, bs, &lu.coeffRef(k, k), luStride, row_transpositions + k, nb_transpositions_in_panel, 16); if (ret >= 0 && first_zero_pivot == -1) first_zero_pivot = k + ret; nb_transpositions += nb_transpositions_in_panel; // update permutations and apply them to A_0 for (Index i = k; i < k + bs; ++i) { Index piv = (row_transpositions[i] += internal::convert_index(k)); A_0.row(i).swap(A_0.row(piv)); } if (trows) { // apply permutations to A_2 for (Index i = k; i < k + bs; ++i) A_2.row(i).swap(A_2.row(row_transpositions[i])); // A12 = A11^-1 A12 A11.template triangularView().solveInPlace(A12); A22.noalias() -= A21 * A12; } } return first_zero_pivot; } }; /** \internal performs the LU decomposition with partial pivoting in-place. */ template void partial_lu_inplace(MatrixType& lu, TranspositionType& row_transpositions, typename TranspositionType::StorageIndex& nb_transpositions) { // Special-case of zero matrix. if (lu.rows() == 0 || lu.cols() == 0) { nb_transpositions = 0; return; } eigen_assert(lu.cols() == row_transpositions.size()); eigen_assert(row_transpositions.size() < 2 || (&row_transpositions.coeffRef(1) - &row_transpositions.coeffRef(0)) == 1); partial_lu_impl:: blocked_lu(lu.rows(), lu.cols(), &lu.coeffRef(0, 0), lu.outerStride(), &row_transpositions.coeffRef(0), nb_transpositions); } } // end namespace internal template void PartialPivLU::compute() { eigen_assert(m_lu.rows() < NumTraits::highest()); if (m_lu.cols() > 0) m_l1_norm = m_lu.cwiseAbs().colwise().sum().maxCoeff(); else m_l1_norm = RealScalar(0); eigen_assert(m_lu.rows() == m_lu.cols() && "PartialPivLU is only for square (and moreover invertible) matrices"); const Index size = m_lu.rows(); m_rowsTranspositions.resize(size); typename TranspositionType::StorageIndex nb_transpositions; internal::partial_lu_inplace(m_lu, m_rowsTranspositions, nb_transpositions); m_det_p = (nb_transpositions % 2) ? -1 : 1; m_p = m_rowsTranspositions; m_isInitialized = true; } template typename PartialPivLU::Scalar PartialPivLU::determinant() const { eigen_assert(m_isInitialized && "PartialPivLU is not initialized."); return Scalar(m_det_p) * m_lu.diagonal().prod(); } /** \returns the matrix represented by the decomposition, * i.e., it returns the product: P^{-1} L U. * This function is provided for debug purpose. */ template MatrixType PartialPivLU::reconstructedMatrix() const { eigen_assert(m_isInitialized && "LU is not initialized."); // LU MatrixType res = m_lu.template triangularView().toDenseMatrix() * m_lu.template triangularView(); // P^{-1}(LU) res = m_p.inverse() * res; return res; } /***** Implementation details *****************************************************/ namespace internal { /***** Implementation of inverse() *****************************************************/ template struct Assignment< DstXprType, Inverse >, internal::assign_op::Scalar>, Dense2Dense> { typedef PartialPivLU LuType; typedef Inverse SrcXprType; static void run(DstXprType& dst, const SrcXprType& src, const internal::assign_op&) { dst = src.nestedExpression().solve(MatrixType::Identity(src.rows(), src.cols())); } }; } // end namespace internal /******** MatrixBase methods *******/ /** \lu_module * * \return the partial-pivoting LU decomposition of \c *this. * * \sa class PartialPivLU */ template template inline const PartialPivLU::PlainObject, PermutationIndex> MatrixBase::partialPivLu() const { return PartialPivLU(eval()); } /** \lu_module * * Synonym of partialPivLu(). * * \return the partial-pivoting LU decomposition of \c *this. * * \sa class PartialPivLU */ template template inline const PartialPivLU::PlainObject, PermutationIndex> MatrixBase::lu() const { return PartialPivLU(eval()); } } // end namespace Eigen #endif // EIGEN_PARTIALLU_H