// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2008-2009 Gael Guennebaud // Copyright (C) 2009 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_FULLPIVOTINGHOUSEHOLDERQR_H #define EIGEN_FULLPIVOTINGHOUSEHOLDERQR_H // IWYU pragma: private #include "./InternalHeaderCheck.h" namespace Eigen { namespace internal { template struct traits > : traits { typedef MatrixXpr XprKind; typedef SolverStorage StorageKind; typedef PermutationIndex_ PermutationIndex; enum { Flags = 0 }; }; template struct FullPivHouseholderQRMatrixQReturnType; template struct traits > { typedef typename MatrixType::PlainObject ReturnType; }; } // end namespace internal /** \ingroup QR_Module * * \class FullPivHouseholderQR * * \brief Householder rank-revealing QR decomposition of a matrix with full pivoting * * \tparam MatrixType_ the type of the matrix of which we are computing the QR decomposition * * This class performs a rank-revealing QR decomposition of a matrix \b A into matrices \b P, \b P', \b Q and \b R * such that * \f[ * \mathbf{P} \, \mathbf{A} \, \mathbf{P}' = \mathbf{Q} \, \mathbf{R} * \f] * by using Householder transformations. Here, \b P and \b P' are permutation matrices, \b Q a unitary matrix * and \b R an upper triangular matrix. * * This decomposition performs a very prudent full pivoting in order to be rank-revealing and achieve optimal * numerical stability. The trade-off is that it is slower than HouseholderQR and ColPivHouseholderQR. * * This class supports the \link InplaceDecomposition inplace decomposition \endlink mechanism. * * \sa MatrixBase::fullPivHouseholderQr() */ template class FullPivHouseholderQR : public SolverBase > { public: typedef MatrixType_ MatrixType; typedef SolverBase Base; friend class SolverBase; typedef PermutationIndex_ PermutationIndex; EIGEN_GENERIC_PUBLIC_INTERFACE(FullPivHouseholderQR) enum { MaxRowsAtCompileTime = MatrixType::MaxRowsAtCompileTime, MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime }; typedef internal::FullPivHouseholderQRMatrixQReturnType MatrixQReturnType; typedef typename internal::plain_diag_type::type HCoeffsType; typedef Matrix IntDiagSizeVectorType; typedef PermutationMatrix PermutationType; typedef typename internal::plain_row_type::type RowVectorType; typedef typename internal::plain_col_type::type ColVectorType; typedef typename MatrixType::PlainObject PlainObject; /** \brief Default Constructor. * * The default constructor is useful in cases in which the user intends to * perform decompositions via FullPivHouseholderQR::compute(const MatrixType&). */ FullPivHouseholderQR() : m_qr(), m_hCoeffs(), m_rows_transpositions(), m_cols_transpositions(), m_cols_permutation(), m_temp(), m_isInitialized(false), m_usePrescribedThreshold(false) {} /** \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 FullPivHouseholderQR() */ FullPivHouseholderQR(Index rows, Index cols) : m_qr(rows, cols), m_hCoeffs((std::min)(rows, cols)), m_rows_transpositions((std::min)(rows, cols)), m_cols_transpositions((std::min)(rows, cols)), m_cols_permutation(cols), m_temp(cols), m_isInitialized(false), m_usePrescribedThreshold(false) {} /** \brief Constructs a QR factorization from a given matrix * * This constructor computes the QR factorization of the matrix \a matrix by calling * the method compute(). It is a short cut for: * * \code * FullPivHouseholderQR qr(matrix.rows(), matrix.cols()); * qr.compute(matrix); * \endcode * * \sa compute() */ template explicit FullPivHouseholderQR(const EigenBase& matrix) : m_qr(matrix.rows(), matrix.cols()), m_hCoeffs((std::min)(matrix.rows(), matrix.cols())), m_rows_transpositions((std::min)(matrix.rows(), matrix.cols())), m_cols_transpositions((std::min)(matrix.rows(), matrix.cols())), m_cols_permutation(matrix.cols()), m_temp(matrix.cols()), m_isInitialized(false), m_usePrescribedThreshold(false) { compute(matrix.derived()); } /** \brief Constructs a QR factorization from a given matrix * * This overloaded constructor is provided for \link InplaceDecomposition inplace decomposition \endlink when \c * MatrixType is a Eigen::Ref. * * \sa FullPivHouseholderQR(const EigenBase&) */ template explicit FullPivHouseholderQR(EigenBase& matrix) : m_qr(matrix.derived()), m_hCoeffs((std::min)(matrix.rows(), matrix.cols())), m_rows_transpositions((std::min)(matrix.rows(), matrix.cols())), m_cols_transpositions((std::min)(matrix.rows(), matrix.cols())), m_cols_permutation(matrix.cols()), m_temp(matrix.cols()), m_isInitialized(false), m_usePrescribedThreshold(false) { computeInPlace(); } #ifdef EIGEN_PARSED_BY_DOXYGEN /** This method finds a solution x to the equation Ax=b, where A is the matrix of which * \c *this is the QR decomposition. * * \param b the right-hand-side of the equation to solve. * * \returns the exact or least-square solution if the rank is greater or equal to the number of columns of A, * and an arbitrary solution otherwise. * * \note_about_checking_solutions * * \note_about_arbitrary_choice_of_solution * * Example: \include FullPivHouseholderQR_solve.cpp * Output: \verbinclude FullPivHouseholderQR_solve.out */ template inline const Solve solve(const MatrixBase& b) const; #endif /** \returns Expression object representing the matrix Q */ MatrixQReturnType matrixQ(void) const; /** \returns a reference to the matrix where the Householder QR decomposition is stored */ const MatrixType& matrixQR() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return m_qr; } template FullPivHouseholderQR& compute(const EigenBase& matrix); /** \returns a const reference to the column permutation matrix */ const PermutationType& colsPermutation() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return m_cols_permutation; } /** \returns a const reference to the vector of indices representing the rows transpositions */ const IntDiagSizeVectorType& rowsTranspositions() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return m_rows_transpositions; } /** \returns the determinant of the matrix of which * *this is the QR decomposition. It has only linear complexity * (that is, O(n) where n is the dimension of the square matrix) * as the QR decomposition has already been computed. * * \note This is only for square matrices. * * \warning a determinant can be very big or small, so for matrices * of large enough dimension, there is a risk of overflow/underflow. * One way to work around that is to use logAbsDeterminant() instead. * * \sa absDeterminant(), logAbsDeterminant(), MatrixBase::determinant() */ typename MatrixType::Scalar determinant() const; /** \returns the absolute value of the determinant of the matrix of which * *this is the QR decomposition. It has only linear complexity * (that is, O(n) where n is the dimension of the square matrix) * as the QR decomposition has already been computed. * * \note This is only for square matrices. * * \warning a determinant can be very big or small, so for matrices * of large enough dimension, there is a risk of overflow/underflow. * One way to work around that is to use logAbsDeterminant() instead. * * \sa determinant(), logAbsDeterminant(), MatrixBase::determinant() */ typename MatrixType::RealScalar absDeterminant() const; /** \returns the natural log of the absolute value of the determinant of the matrix of which * *this is the QR decomposition. It has only linear complexity * (that is, O(n) where n is the dimension of the square matrix) * as the QR decomposition has already been computed. * * \note This is only for square matrices. * * \note This method is useful to work around the risk of overflow/underflow that's inherent * to determinant computation. * * \sa determinant(), absDeterminant(), MatrixBase::determinant() */ typename MatrixType::RealScalar logAbsDeterminant() const; /** \returns the sign of the determinant of the matrix of which * *this is the QR decomposition. It has only linear complexity * (that is, O(n) where n is the dimension of the square matrix) * as the QR decomposition has already been computed. * * \note This is only for square matrices. * * \note This method is useful to work around the risk of overflow/underflow that's inherent * to determinant computation. * * \sa determinant(), absDeterminant(), logAbsDeterminant(), MatrixBase::determinant() */ typename MatrixType::Scalar signDeterminant() const; /** \returns the rank of the matrix of which *this is the QR decomposition. * * \note This method has to determine which pivots should be considered nonzero. * For that, it uses the threshold value that you can control by calling * setThreshold(const RealScalar&). */ inline Index rank() const { using std::abs; eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); RealScalar premultiplied_threshold = abs(m_maxpivot) * threshold(); Index result = 0; for (Index i = 0; i < m_nonzero_pivots; ++i) result += (abs(m_qr.coeff(i, i)) > premultiplied_threshold); return result; } /** \returns the dimension of the kernel of the matrix of which *this is the QR decomposition. * * \note This method has to determine which pivots should be considered nonzero. * For that, it uses the threshold value that you can control by calling * setThreshold(const RealScalar&). */ inline Index dimensionOfKernel() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return cols() - rank(); } /** \returns true if the matrix of which *this is the QR decomposition represents an injective * linear map, i.e. has trivial kernel; false otherwise. * * \note This method has to determine which pivots should be considered nonzero. * For that, it uses the threshold value that you can control by calling * setThreshold(const RealScalar&). */ inline bool isInjective() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return rank() == cols(); } /** \returns true if the matrix of which *this is the QR decomposition represents a surjective * linear map; false otherwise. * * \note This method has to determine which pivots should be considered nonzero. * For that, it uses the threshold value that you can control by calling * setThreshold(const RealScalar&). */ inline bool isSurjective() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return rank() == rows(); } /** \returns true if the matrix of which *this is the QR decomposition is invertible. * * \note This method has to determine which pivots should be considered nonzero. * For that, it uses the threshold value that you can control by calling * setThreshold(const RealScalar&). */ inline bool isInvertible() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return isInjective() && isSurjective(); } /** \returns the inverse of the matrix of which *this is the QR decomposition. * * \note If this matrix is not invertible, the returned matrix has undefined coefficients. * Use isInvertible() to first determine whether this matrix is invertible. */ inline const Inverse inverse() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return Inverse(*this); } inline Index rows() const { return m_qr.rows(); } inline Index cols() const { return m_qr.cols(); } /** \returns a const reference to the vector of Householder coefficients used to represent the factor \c Q. * * For advanced uses only. */ const HCoeffsType& hCoeffs() const { return m_hCoeffs; } /** Allows to prescribe a threshold to be used by certain methods, such as rank(), * who need to determine when pivots are to be considered nonzero. This is not used for the * QR decomposition itself. * * When it needs to get the threshold value, Eigen calls threshold(). By default, this * uses a formula to automatically determine a reasonable threshold. * Once you have called the present method setThreshold(const RealScalar&), * your value is used instead. * * \param threshold The new value to use as the threshold. * * A pivot will be considered nonzero if its absolute value is strictly greater than * \f$ \vert pivot \vert \leqslant threshold \times \vert maxpivot \vert \f$ * where maxpivot is the biggest pivot. * * If you want to come back to the default behavior, call setThreshold(Default_t) */ FullPivHouseholderQR& setThreshold(const RealScalar& threshold) { m_usePrescribedThreshold = true; m_prescribedThreshold = threshold; return *this; } /** Allows to come back to the default behavior, letting Eigen use its default formula for * determining the threshold. * * You should pass the special object Eigen::Default as parameter here. * \code qr.setThreshold(Eigen::Default); \endcode * * See the documentation of setThreshold(const RealScalar&). */ FullPivHouseholderQR& setThreshold(Default_t) { m_usePrescribedThreshold = false; return *this; } /** Returns the threshold that will be used by certain methods such as rank(). * * See the documentation of setThreshold(const RealScalar&). */ RealScalar threshold() const { eigen_assert(m_isInitialized || m_usePrescribedThreshold); return m_usePrescribedThreshold ? m_prescribedThreshold // this formula comes from experimenting (see "LU precision tuning" thread on the // list) and turns out to be identical to Higham's formula used already in LDLt. : NumTraits::epsilon() * RealScalar(m_qr.diagonalSize()); } /** \returns the number of nonzero pivots in the QR decomposition. * Here nonzero is meant in the exact sense, not in a fuzzy sense. * So that notion isn't really intrinsically interesting, but it is * still useful when implementing algorithms. * * \sa rank() */ inline Index nonzeroPivots() const { eigen_assert(m_isInitialized && "LU is not initialized."); return m_nonzero_pivots; } /** \returns the absolute value of the biggest pivot, i.e. the biggest * diagonal coefficient of U. */ RealScalar maxPivot() const { return m_maxpivot; } #ifndef EIGEN_PARSED_BY_DOXYGEN template void _solve_impl(const RhsType& rhs, DstType& dst) const; template void _solve_impl_transposed(const RhsType& rhs, DstType& dst) const; #endif protected: EIGEN_STATIC_ASSERT_NON_INTEGER(Scalar) void computeInPlace(); MatrixType m_qr; HCoeffsType m_hCoeffs; IntDiagSizeVectorType m_rows_transpositions; IntDiagSizeVectorType m_cols_transpositions; PermutationType m_cols_permutation; RowVectorType m_temp; bool m_isInitialized, m_usePrescribedThreshold; RealScalar m_prescribedThreshold, m_maxpivot; Index m_nonzero_pivots; RealScalar m_precision; Index m_det_p; }; template typename MatrixType::Scalar FullPivHouseholderQR::determinant() const { eigen_assert(m_isInitialized && "HouseholderQR is not initialized."); eigen_assert(m_qr.rows() == m_qr.cols() && "You can't take the determinant of a non-square matrix!"); Scalar detQ; internal::householder_determinant::IsComplex>::run(m_hCoeffs, detQ); return isInjective() ? (detQ * Scalar(m_det_p)) * m_qr.diagonal().prod() : Scalar(0); } template typename MatrixType::RealScalar FullPivHouseholderQR::absDeterminant() const { using std::abs; eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); eigen_assert(m_qr.rows() == m_qr.cols() && "You can't take the determinant of a non-square matrix!"); return isInjective() ? abs(m_qr.diagonal().prod()) : RealScalar(0); } template typename MatrixType::RealScalar FullPivHouseholderQR::logAbsDeterminant() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); eigen_assert(m_qr.rows() == m_qr.cols() && "You can't take the determinant of a non-square matrix!"); return isInjective() ? m_qr.diagonal().cwiseAbs().array().log().sum() : -NumTraits::infinity(); } template typename MatrixType::Scalar FullPivHouseholderQR::signDeterminant() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); eigen_assert(m_qr.rows() == m_qr.cols() && "You can't take the determinant of a non-square matrix!"); Scalar detQ; internal::householder_determinant::IsComplex>::run(m_hCoeffs, detQ); return isInjective() ? (detQ * Scalar(m_det_p)) * m_qr.diagonal().array().sign().prod() : Scalar(0); } /** Performs the QR factorization of the given matrix \a matrix. The result of * the factorization is stored into \c *this, and a reference to \c *this * is returned. * * \sa class FullPivHouseholderQR, FullPivHouseholderQR(const MatrixType&) */ template template FullPivHouseholderQR& FullPivHouseholderQR::compute( const EigenBase& matrix) { m_qr = matrix.derived(); computeInPlace(); return *this; } template void FullPivHouseholderQR::computeInPlace() { eigen_assert(m_qr.cols() <= NumTraits::highest()); using std::abs; Index rows = m_qr.rows(); Index cols = m_qr.cols(); Index size = (std::min)(rows, cols); m_hCoeffs.resize(size); m_temp.resize(cols); m_precision = NumTraits::epsilon() * RealScalar(size); m_rows_transpositions.resize(size); m_cols_transpositions.resize(size); Index number_of_transpositions = 0; RealScalar biggest(0); m_nonzero_pivots = size; // the generic case is that in which all pivots are nonzero (invertible case) m_maxpivot = RealScalar(0); for (Index k = 0; k < size; ++k) { Index row_of_biggest_in_corner, col_of_biggest_in_corner; typedef internal::scalar_score_coeff_op Scoring; typedef typename Scoring::result_type Score; Score score = m_qr.bottomRightCorner(rows - k, cols - k) .unaryExpr(Scoring()) .maxCoeff(&row_of_biggest_in_corner, &col_of_biggest_in_corner); row_of_biggest_in_corner += k; col_of_biggest_in_corner += k; RealScalar biggest_in_corner = internal::abs_knowing_score()(m_qr(row_of_biggest_in_corner, col_of_biggest_in_corner), score); if (k == 0) biggest = biggest_in_corner; // if the corner is negligible, then we have less than full rank, and we can finish early if (internal::isMuchSmallerThan(biggest_in_corner, biggest, m_precision)) { m_nonzero_pivots = k; for (Index i = k; i < size; i++) { m_rows_transpositions.coeffRef(i) = internal::convert_index(i); m_cols_transpositions.coeffRef(i) = internal::convert_index(i); m_hCoeffs.coeffRef(i) = Scalar(0); } break; } m_rows_transpositions.coeffRef(k) = internal::convert_index(row_of_biggest_in_corner); m_cols_transpositions.coeffRef(k) = internal::convert_index(col_of_biggest_in_corner); if (k != row_of_biggest_in_corner) { m_qr.row(k).tail(cols - k).swap(m_qr.row(row_of_biggest_in_corner).tail(cols - k)); ++number_of_transpositions; } if (k != col_of_biggest_in_corner) { m_qr.col(k).swap(m_qr.col(col_of_biggest_in_corner)); ++number_of_transpositions; } RealScalar beta; m_qr.col(k).tail(rows - k).makeHouseholderInPlace(m_hCoeffs.coeffRef(k), beta); m_qr.coeffRef(k, k) = beta; // remember the maximum absolute value of diagonal coefficients if (abs(beta) > m_maxpivot) m_maxpivot = abs(beta); m_qr.bottomRightCorner(rows - k, cols - k - 1) .applyHouseholderOnTheLeft(m_qr.col(k).tail(rows - k - 1), m_hCoeffs.coeffRef(k), &m_temp.coeffRef(k + 1)); } m_cols_permutation.setIdentity(cols); for (Index k = 0; k < size; ++k) m_cols_permutation.applyTranspositionOnTheRight(k, m_cols_transpositions.coeff(k)); m_det_p = (number_of_transpositions % 2) ? -1 : 1; m_isInitialized = true; } #ifndef EIGEN_PARSED_BY_DOXYGEN template template void FullPivHouseholderQR::_solve_impl(const RhsType& rhs, DstType& dst) const { const Index l_rank = rank(); // FIXME introduce nonzeroPivots() and use it here. and more generally, // make the same improvements in this dec as in FullPivLU. if (l_rank == 0) { dst.setZero(); return; } typename RhsType::PlainObject c(rhs); Matrix temp(rhs.cols()); for (Index k = 0; k < l_rank; ++k) { Index remainingSize = rows() - k; c.row(k).swap(c.row(m_rows_transpositions.coeff(k))); c.bottomRightCorner(remainingSize, rhs.cols()) .applyHouseholderOnTheLeft(m_qr.col(k).tail(remainingSize - 1), m_hCoeffs.coeff(k), &temp.coeffRef(0)); } m_qr.topLeftCorner(l_rank, l_rank).template triangularView().solveInPlace(c.topRows(l_rank)); for (Index i = 0; i < l_rank; ++i) dst.row(m_cols_permutation.indices().coeff(i)) = c.row(i); for (Index i = l_rank; i < cols(); ++i) dst.row(m_cols_permutation.indices().coeff(i)).setZero(); } template template void FullPivHouseholderQR::_solve_impl_transposed(const RhsType& rhs, DstType& dst) const { const Index l_rank = rank(); if (l_rank == 0) { dst.setZero(); return; } typename RhsType::PlainObject c(m_cols_permutation.transpose() * rhs); m_qr.topLeftCorner(l_rank, l_rank) .template triangularView() .transpose() .template conjugateIf() .solveInPlace(c.topRows(l_rank)); dst.topRows(l_rank) = c.topRows(l_rank); dst.bottomRows(rows() - l_rank).setZero(); Matrix temp(dst.cols()); const Index size = (std::min)(rows(), cols()); for (Index k = size - 1; k >= 0; --k) { Index remainingSize = rows() - k; dst.bottomRightCorner(remainingSize, dst.cols()) .applyHouseholderOnTheLeft(m_qr.col(k).tail(remainingSize - 1).template conjugateIf(), m_hCoeffs.template conjugateIf().coeff(k), &temp.coeffRef(0)); dst.row(k).swap(dst.row(m_rows_transpositions.coeff(k))); } } #endif namespace internal { template struct Assignment >, internal::assign_op::Scalar>, Dense2Dense> { typedef FullPivHouseholderQR QrType; 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())); } }; /** \ingroup QR_Module * * \brief Expression type for return value of FullPivHouseholderQR::matrixQ() * * \tparam MatrixType type of underlying dense matrix */ template struct FullPivHouseholderQRMatrixQReturnType : public ReturnByValue > { public: typedef typename FullPivHouseholderQR::IntDiagSizeVectorType IntDiagSizeVectorType; typedef typename internal::plain_diag_type::type HCoeffsType; typedef Matrix WorkVectorType; FullPivHouseholderQRMatrixQReturnType(const MatrixType& qr, const HCoeffsType& hCoeffs, const IntDiagSizeVectorType& rowsTranspositions) : m_qr(qr), m_hCoeffs(hCoeffs), m_rowsTranspositions(rowsTranspositions) {} template void evalTo(ResultType& result) const { const Index rows = m_qr.rows(); WorkVectorType workspace(rows); evalTo(result, workspace); } template void evalTo(ResultType& result, WorkVectorType& workspace) const { using numext::conj; // compute the product H'_0 H'_1 ... H'_n-1, // where H_k is the k-th Householder transformation I - h_k v_k v_k' // and v_k is the k-th Householder vector [1,m_qr(k+1,k), m_qr(k+2,k), ...] const Index rows = m_qr.rows(); const Index cols = m_qr.cols(); const Index size = (std::min)(rows, cols); workspace.resize(rows); result.setIdentity(rows, rows); for (Index k = size - 1; k >= 0; k--) { result.block(k, k, rows - k, rows - k) .applyHouseholderOnTheLeft(m_qr.col(k).tail(rows - k - 1), conj(m_hCoeffs.coeff(k)), &workspace.coeffRef(k)); result.row(k).swap(result.row(m_rowsTranspositions.coeff(k))); } } Index rows() const { return m_qr.rows(); } Index cols() const { return m_qr.rows(); } protected: typename MatrixType::Nested m_qr; typename HCoeffsType::Nested m_hCoeffs; typename IntDiagSizeVectorType::Nested m_rowsTranspositions; }; // template // struct evaluator > // : public evaluator > > // {}; } // end namespace internal template inline typename FullPivHouseholderQR::MatrixQReturnType FullPivHouseholderQR::matrixQ() const { eigen_assert(m_isInitialized && "FullPivHouseholderQR is not initialized."); return MatrixQReturnType(m_qr, m_hCoeffs, m_rows_transpositions); } /** \return the full-pivoting Householder QR decomposition of \c *this. * * \sa class FullPivHouseholderQR */ template template const FullPivHouseholderQR::PlainObject, PermutationIndex> MatrixBase::fullPivHouseholderQr() const { return FullPivHouseholderQR(eval()); } } // end namespace Eigen #endif // EIGEN_FULLPIVOTINGHOUSEHOLDERQR_H