// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2009 Gael Guennebaud // Copyright (C) 2010 Benoit Jacob // // 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_HOUSEHOLDER_SEQUENCE_H #define EIGEN_HOUSEHOLDER_SEQUENCE_H // IWYU pragma: private #include "./InternalHeaderCheck.h" namespace Eigen { /** \ingroup Householder_Module * \householder_module * \class HouseholderSequence * \brief Sequence of Householder reflections acting on subspaces with decreasing size * \tparam VectorsType type of matrix containing the Householder vectors * \tparam CoeffsType type of vector containing the Householder coefficients * \tparam Side either OnTheLeft (the default) or OnTheRight * * This class represents a product sequence of Householder reflections where the first Householder reflection * acts on the whole space, the second Householder reflection leaves the one-dimensional subspace spanned by * the first unit vector invariant, the third Householder reflection leaves the two-dimensional subspace * spanned by the first two unit vectors invariant, and so on up to the last reflection which leaves all but * one dimensions invariant and acts only on the last dimension. Such sequences of Householder reflections * are used in several algorithms to zero out certain parts of a matrix. Indeed, the methods * HessenbergDecomposition::matrixQ(), Tridiagonalization::matrixQ(), HouseholderQR::householderQ(), * and ColPivHouseholderQR::householderQ() all return a %HouseholderSequence. * * More precisely, the class %HouseholderSequence represents an \f$ n \times n \f$ matrix \f$ H \f$ of the * form \f$ H = \prod_{i=0}^{n-1} H_i \f$ where the i-th Householder reflection is \f$ H_i = I - h_i v_i * v_i^* \f$. The i-th Householder coefficient \f$ h_i \f$ is a scalar and the i-th Householder vector \f$ * v_i \f$ is a vector of the form * \f[ * v_i = [\underbrace{0, \ldots, 0}_{i-1\mbox{ zeros}}, 1, \underbrace{*, \ldots,*}_{n-i\mbox{ arbitrary entries}} ]. * \f] * The last \f$ n-i \f$ entries of \f$ v_i \f$ are called the essential part of the Householder vector. * * Typical usages are listed below, where H is a HouseholderSequence: * \code * A.applyOnTheRight(H); // A = A * H * A.applyOnTheLeft(H); // A = H * A * A.applyOnTheRight(H.adjoint()); // A = A * H^* * A.applyOnTheLeft(H.adjoint()); // A = H^* * A * MatrixXd Q = H; // conversion to a dense matrix * \endcode * In addition to the adjoint, you can also apply the inverse (=adjoint), the transpose, and the conjugate operators. * * See the documentation for HouseholderSequence(const VectorsType&, const CoeffsType&) for an example. * * \sa MatrixBase::applyOnTheLeft(), MatrixBase::applyOnTheRight() */ namespace internal { template struct traits > { typedef typename VectorsType::Scalar Scalar; typedef typename VectorsType::StorageIndex StorageIndex; typedef typename VectorsType::StorageKind StorageKind; enum { RowsAtCompileTime = Side == OnTheLeft ? traits::RowsAtCompileTime : traits::ColsAtCompileTime, ColsAtCompileTime = RowsAtCompileTime, MaxRowsAtCompileTime = Side == OnTheLeft ? traits::MaxRowsAtCompileTime : traits::MaxColsAtCompileTime, MaxColsAtCompileTime = MaxRowsAtCompileTime, Flags = 0 }; }; struct HouseholderSequenceShape {}; template struct evaluator_traits > : public evaluator_traits_base > { typedef HouseholderSequenceShape Shape; }; template struct hseq_side_dependent_impl { typedef Block EssentialVectorType; typedef HouseholderSequence HouseholderSequenceType; static EIGEN_DEVICE_FUNC inline const EssentialVectorType essentialVector(const HouseholderSequenceType& h, Index k) { Index start = k + 1 + h.m_shift; return Block(h.m_vectors, start, k, h.rows() - start, 1); } }; template struct hseq_side_dependent_impl { typedef Transpose > EssentialVectorType; typedef HouseholderSequence HouseholderSequenceType; static inline const EssentialVectorType essentialVector(const HouseholderSequenceType& h, Index k) { Index start = k + 1 + h.m_shift; return Block(h.m_vectors, k, start, 1, h.rows() - start).transpose(); } }; template struct matrix_type_times_scalar_type { typedef typename ScalarBinaryOpTraits::ReturnType ResultScalar; typedef Matrix Type; }; } // end namespace internal template class HouseholderSequence : public EigenBase > { typedef typename internal::hseq_side_dependent_impl::EssentialVectorType EssentialVectorType; public: enum { RowsAtCompileTime = internal::traits::RowsAtCompileTime, ColsAtCompileTime = internal::traits::ColsAtCompileTime, MaxRowsAtCompileTime = internal::traits::MaxRowsAtCompileTime, MaxColsAtCompileTime = internal::traits::MaxColsAtCompileTime }; typedef typename internal::traits::Scalar Scalar; typedef HouseholderSequence< std::conditional_t::IsComplex, internal::remove_all_t, VectorsType>, std::conditional_t::IsComplex, internal::remove_all_t, CoeffsType>, Side> ConjugateReturnType; typedef HouseholderSequence< VectorsType, std::conditional_t::IsComplex, internal::remove_all_t, CoeffsType>, Side> AdjointReturnType; typedef HouseholderSequence< std::conditional_t::IsComplex, internal::remove_all_t, VectorsType>, CoeffsType, Side> TransposeReturnType; typedef HouseholderSequence, std::add_const_t, Side> ConstHouseholderSequence; /** \brief Constructor. * \param[in] v %Matrix containing the essential parts of the Householder vectors * \param[in] h Vector containing the Householder coefficients * * Constructs the Householder sequence with coefficients given by \p h and vectors given by \p v. The * i-th Householder coefficient \f$ h_i \f$ is given by \p h(i) and the essential part of the i-th * Householder vector \f$ v_i \f$ is given by \p v(k,i) with \p k > \p i (the subdiagonal part of the * i-th column). If \p v has fewer columns than rows, then the Householder sequence contains as many * Householder reflections as there are columns. * * \note The %HouseholderSequence object stores \p v and \p h by reference. * * Example: \include HouseholderSequence_HouseholderSequence.cpp * Output: \verbinclude HouseholderSequence_HouseholderSequence.out * * \sa setLength(), setShift() */ EIGEN_DEVICE_FUNC HouseholderSequence(const VectorsType& v, const CoeffsType& h) : m_vectors(v), m_coeffs(h), m_reverse(false), m_length(v.diagonalSize()), m_shift(0) {} /** \brief Copy constructor. */ EIGEN_DEVICE_FUNC HouseholderSequence(const HouseholderSequence& other) : m_vectors(other.m_vectors), m_coeffs(other.m_coeffs), m_reverse(other.m_reverse), m_length(other.m_length), m_shift(other.m_shift) {} /** \brief Number of rows of transformation viewed as a matrix. * \returns Number of rows * \details This equals the dimension of the space that the transformation acts on. */ EIGEN_DEVICE_FUNC EIGEN_CONSTEXPR Index rows() const EIGEN_NOEXCEPT { return Side == OnTheLeft ? m_vectors.rows() : m_vectors.cols(); } /** \brief Number of columns of transformation viewed as a matrix. * \returns Number of columns * \details This equals the dimension of the space that the transformation acts on. */ EIGEN_DEVICE_FUNC EIGEN_CONSTEXPR Index cols() const EIGEN_NOEXCEPT { return rows(); } /** \brief Essential part of a Householder vector. * \param[in] k Index of Householder reflection * \returns Vector containing non-trivial entries of k-th Householder vector * * This function returns the essential part of the Householder vector \f$ v_i \f$. This is a vector of * length \f$ n-i \f$ containing the last \f$ n-i \f$ entries of the vector * \f[ * v_i = [\underbrace{0, \ldots, 0}_{i-1\mbox{ zeros}}, 1, \underbrace{*, \ldots,*}_{n-i\mbox{ arbitrary entries}} ]. * \f] * The index \f$ i \f$ equals \p k + shift(), corresponding to the k-th column of the matrix \p v * passed to the constructor. * * \sa setShift(), shift() */ EIGEN_DEVICE_FUNC const EssentialVectorType essentialVector(Index k) const { eigen_assert(k >= 0 && k < m_length); return internal::hseq_side_dependent_impl::essentialVector(*this, k); } /** \brief %Transpose of the Householder sequence. */ TransposeReturnType transpose() const { return TransposeReturnType(m_vectors.conjugate(), m_coeffs) .setReverseFlag(!m_reverse) .setLength(m_length) .setShift(m_shift); } /** \brief Complex conjugate of the Householder sequence. */ ConjugateReturnType conjugate() const { return ConjugateReturnType(m_vectors.conjugate(), m_coeffs.conjugate()) .setReverseFlag(m_reverse) .setLength(m_length) .setShift(m_shift); } /** \returns an expression of the complex conjugate of \c *this if Cond==true, * returns \c *this otherwise. */ template EIGEN_DEVICE_FUNC inline std::conditional_t conjugateIf() const { typedef std::conditional_t ReturnType; return ReturnType(m_vectors.template conjugateIf(), m_coeffs.template conjugateIf()); } /** \brief Adjoint (conjugate transpose) of the Householder sequence. */ AdjointReturnType adjoint() const { return AdjointReturnType(m_vectors, m_coeffs.conjugate()) .setReverseFlag(!m_reverse) .setLength(m_length) .setShift(m_shift); } /** \brief Inverse of the Householder sequence (equals the adjoint). */ AdjointReturnType inverse() const { return adjoint(); } /** \internal */ template inline EIGEN_DEVICE_FUNC void evalTo(DestType& dst) const { Matrix workspace( rows()); evalTo(dst, workspace); } /** \internal */ template EIGEN_DEVICE_FUNC void evalTo(Dest& dst, Workspace& workspace) const { workspace.resize(rows()); Index vecs = m_length; if (internal::is_same_dense(dst, m_vectors)) { // in-place dst.diagonal().setOnes(); dst.template triangularView().setZero(); for (Index k = vecs - 1; k >= 0; --k) { Index cornerSize = rows() - k - m_shift; if (m_reverse) dst.bottomRightCorner(cornerSize, cornerSize) .applyHouseholderOnTheRight(essentialVector(k), m_coeffs.coeff(k), workspace.data()); else dst.bottomRightCorner(cornerSize, cornerSize) .applyHouseholderOnTheLeft(essentialVector(k), m_coeffs.coeff(k), workspace.data()); // clear the off diagonal vector dst.col(k).tail(rows() - k - 1).setZero(); } // clear the remaining columns if needed for (Index k = 0; k < cols() - vecs; ++k) dst.col(k).tail(rows() - k - 1).setZero(); } else if (m_length > BlockSize) { dst.setIdentity(rows(), rows()); if (m_reverse) applyThisOnTheLeft(dst, workspace, true); else applyThisOnTheLeft(dst, workspace, true); } else { dst.setIdentity(rows(), rows()); for (Index k = vecs - 1; k >= 0; --k) { Index cornerSize = rows() - k - m_shift; if (m_reverse) dst.bottomRightCorner(cornerSize, cornerSize) .applyHouseholderOnTheRight(essentialVector(k), m_coeffs.coeff(k), workspace.data()); else dst.bottomRightCorner(cornerSize, cornerSize) .applyHouseholderOnTheLeft(essentialVector(k), m_coeffs.coeff(k), workspace.data()); } } } /** \internal */ template inline void applyThisOnTheRight(Dest& dst) const { Matrix workspace(dst.rows()); applyThisOnTheRight(dst, workspace); } /** \internal */ template inline void applyThisOnTheRight(Dest& dst, Workspace& workspace) const { workspace.resize(dst.rows()); for (Index k = 0; k < m_length; ++k) { Index actual_k = m_reverse ? m_length - k - 1 : k; dst.rightCols(rows() - m_shift - actual_k) .applyHouseholderOnTheRight(essentialVector(actual_k), m_coeffs.coeff(actual_k), workspace.data()); } } /** \internal */ template inline void applyThisOnTheLeft(Dest& dst, bool inputIsIdentity = false) const { Matrix workspace; applyThisOnTheLeft(dst, workspace, inputIsIdentity); } /** \internal */ template inline void applyThisOnTheLeft(Dest& dst, Workspace& workspace, bool inputIsIdentity = false) const { if (inputIsIdentity && m_reverse) inputIsIdentity = false; // if the entries are large enough, then apply the reflectors by block if (m_length >= BlockSize && dst.cols() > 1) { // Make sure we have at least 2 useful blocks, otherwise it is point-less: Index blockSize = m_length < Index(2 * BlockSize) ? (m_length + 1) / 2 : Index(BlockSize); for (Index i = 0; i < m_length; i += blockSize) { Index end = m_reverse ? (std::min)(m_length, i + blockSize) : m_length - i; Index k = m_reverse ? i : (std::max)(Index(0), end - blockSize); Index bs = end - k; Index start = k + m_shift; typedef Block, Dynamic, Dynamic> SubVectorsType; SubVectorsType sub_vecs1(m_vectors.const_cast_derived(), Side == OnTheRight ? k : start, Side == OnTheRight ? start : k, Side == OnTheRight ? bs : m_vectors.rows() - start, Side == OnTheRight ? m_vectors.cols() - start : bs); std::conditional_t, SubVectorsType&> sub_vecs(sub_vecs1); Index dstRows = rows() - m_shift - k; if (inputIsIdentity) { Block sub_dst = dst.bottomRightCorner(dstRows, dstRows); apply_block_householder_on_the_left(sub_dst, sub_vecs, m_coeffs.segment(k, bs), !m_reverse); } else { auto sub_dst = dst.bottomRows(dstRows); apply_block_householder_on_the_left(sub_dst, sub_vecs, m_coeffs.segment(k, bs), !m_reverse); } } } else { workspace.resize(dst.cols()); for (Index k = 0; k < m_length; ++k) { Index actual_k = m_reverse ? k : m_length - k - 1; Index dstRows = rows() - m_shift - actual_k; if (inputIsIdentity) { Block sub_dst = dst.bottomRightCorner(dstRows, dstRows); sub_dst.applyHouseholderOnTheLeft(essentialVector(actual_k), m_coeffs.coeff(actual_k), workspace.data()); } else { auto sub_dst = dst.bottomRows(dstRows); sub_dst.applyHouseholderOnTheLeft(essentialVector(actual_k), m_coeffs.coeff(actual_k), workspace.data()); } } } } /** \brief Computes the product of a Householder sequence with a matrix. * \param[in] other %Matrix being multiplied. * \returns Expression object representing the product. * * This function computes \f$ HM \f$ where \f$ H \f$ is the Householder sequence represented by \p *this * and \f$ M \f$ is the matrix \p other. */ template typename internal::matrix_type_times_scalar_type::Type operator*( const MatrixBase& other) const { typename internal::matrix_type_times_scalar_type::Type res( other.template cast::ResultScalar>()); applyThisOnTheLeft(res, internal::is_identity::value && res.rows() == res.cols()); return res; } template friend struct internal::hseq_side_dependent_impl; /** \brief Sets the length of the Householder sequence. * \param [in] length New value for the length. * * By default, the length \f$ n \f$ of the Householder sequence \f$ H = H_0 H_1 \ldots H_{n-1} \f$ is set * to the number of columns of the matrix \p v passed to the constructor, or the number of rows if that * is smaller. After this function is called, the length equals \p length. * * \sa length() */ EIGEN_DEVICE_FUNC HouseholderSequence& setLength(Index length) { m_length = length; return *this; } /** \brief Sets the shift of the Householder sequence. * \param [in] shift New value for the shift. * * By default, a %HouseholderSequence object represents \f$ H = H_0 H_1 \ldots H_{n-1} \f$ and the i-th * column of the matrix \p v passed to the constructor corresponds to the i-th Householder * reflection. After this function is called, the object represents \f$ H = H_{\mathrm{shift}} * H_{\mathrm{shift}+1} \ldots H_{n-1} \f$ and the i-th column of \p v corresponds to the (shift+i)-th * Householder reflection. * * \sa shift() */ EIGEN_DEVICE_FUNC HouseholderSequence& setShift(Index shift) { m_shift = shift; return *this; } EIGEN_DEVICE_FUNC Index length() const { return m_length; } /**< \brief Returns the length of the Householder sequence. */ EIGEN_DEVICE_FUNC Index shift() const { return m_shift; } /**< \brief Returns the shift of the Householder sequence. */ /* Necessary for .adjoint() and .conjugate() */ template friend class HouseholderSequence; protected: /** \internal * \brief Sets the reverse flag. * \param [in] reverse New value of the reverse flag. * * By default, the reverse flag is not set. If the reverse flag is set, then this object represents * \f$ H^r = H_{n-1} \ldots H_1 H_0 \f$ instead of \f$ H = H_0 H_1 \ldots H_{n-1} \f$. * \note For real valued HouseholderSequence this is equivalent to transposing \f$ H \f$. * * \sa reverseFlag(), transpose(), adjoint() */ HouseholderSequence& setReverseFlag(bool reverse) { m_reverse = reverse; return *this; } bool reverseFlag() const { return m_reverse; } /**< \internal \brief Returns the reverse flag. */ typename VectorsType::Nested m_vectors; typename CoeffsType::Nested m_coeffs; bool m_reverse; Index m_length; Index m_shift; enum { BlockSize = 48 }; }; /** \brief Computes the product of a matrix with a Householder sequence. * \param[in] other %Matrix being multiplied. * \param[in] h %HouseholderSequence being multiplied. * \returns Expression object representing the product. * * This function computes \f$ MH \f$ where \f$ M \f$ is the matrix \p other and \f$ H \f$ is the * Householder sequence represented by \p h. */ template typename internal::matrix_type_times_scalar_type::Type operator*( const MatrixBase& other, const HouseholderSequence& h) { typename internal::matrix_type_times_scalar_type::Type res( other.template cast::ResultScalar>()); h.applyThisOnTheRight(res); return res; } /** \ingroup Householder_Module * \householder_module * \brief Convenience function for constructing a Householder sequence. * \returns A HouseholderSequence constructed from the specified arguments. */ template HouseholderSequence householderSequence(const VectorsType& v, const CoeffsType& h) { return HouseholderSequence(v, h); } /** \ingroup Householder_Module * \householder_module * \brief Convenience function for constructing a Householder sequence. * \returns A HouseholderSequence constructed from the specified arguments. * \details This function differs from householderSequence() in that the template argument \p OnTheSide of * the constructed HouseholderSequence is set to OnTheRight, instead of the default OnTheLeft. */ template HouseholderSequence rightHouseholderSequence(const VectorsType& v, const CoeffsType& h) { return HouseholderSequence(v, h); } } // end namespace Eigen #endif // EIGEN_HOUSEHOLDER_SEQUENCE_H