Eigen/src/SVD/SVDBase.h - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2009-2010 Benoit Jacob <jacob.benoit.1@gmail.com>
 // Copyright (C) 2014 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // Copyright (C) 2013 Gauthier Brun <brun.gauthier@gmail.com>
 // Copyright (C) 2013 Nicolas Carre <nicolas.carre@ensimag.fr>
 // Copyright (C) 2013 Jean Ceccato <jean.ceccato@ensimag.fr>
 // Copyright (C) 2013 Pierre Zoppitelli <pierre.zoppitelli@ensimag.fr>
 //
 // 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_SVDBASE_H
 #define EIGEN_SVDBASE_H

 // IWYU pragma: private
 #include "./InternalHeaderCheck.h"

 namespace Eigen {

 namespace internal {

 enum OptionsMasks {
   QRPreconditionerBits = NoQRPreconditioner | HouseholderQRPreconditioner | ColPivHouseholderQRPreconditioner |
                          FullPivHouseholderQRPreconditioner,
   ComputationOptionsBits = ComputeThinU | ComputeFullU | ComputeThinV | ComputeFullV
 };

 constexpr int get_qr_preconditioner(int options) { return options & QRPreconditionerBits; }

 constexpr int get_computation_options(int options) { return options & ComputationOptionsBits; }

 constexpr bool should_svd_compute_thin_u(int options) { return (options & ComputeThinU) != 0; }
 constexpr bool should_svd_compute_full_u(int options) { return (options & ComputeFullU) != 0; }
 constexpr bool should_svd_compute_thin_v(int options) { return (options & ComputeThinV) != 0; }
 constexpr bool should_svd_compute_full_v(int options) { return (options & ComputeFullV) != 0; }

 template <typename MatrixType, int Options>
 void check_svd_options_assertions(unsigned int computationOptions, Index rows, Index cols) {
   EIGEN_STATIC_ASSERT((Options & ComputationOptionsBits) == 0,
                       "SVDBase: Cannot request U or V using both static and runtime options, even if they match. "
                       "Requesting unitaries at runtime is DEPRECATED: "
                       "Prefer requesting unitaries statically, using the Options template parameter.");
   eigen_assert(
       !(should_svd_compute_thin_u(computationOptions) && cols < rows && MatrixType::RowsAtCompileTime != Dynamic) &&
       !(should_svd_compute_thin_v(computationOptions) && rows < cols && MatrixType::ColsAtCompileTime != Dynamic) &&
       "SVDBase: If thin U is requested at runtime, your matrix must have more rows than columns or a dynamic number of "
       "rows."
       "Similarly, if thin V is requested at runtime, you matrix must have more columns than rows or a dynamic number "
       "of columns.");
   (void)computationOptions;
   (void)rows;
   (void)cols;
 }

 template <typename Derived>
 struct traits<SVDBase<Derived> > : traits<Derived> {
   typedef MatrixXpr XprKind;
   typedef SolverStorage StorageKind;
   typedef int StorageIndex;
   enum { Flags = 0 };
 };

 template <typename MatrixType, int Options_>
 struct svd_traits : traits<MatrixType> {
   static constexpr int Options = Options_;
   static constexpr bool ShouldComputeFullU = internal::should_svd_compute_full_u(Options);
   static constexpr bool ShouldComputeThinU = internal::should_svd_compute_thin_u(Options);
   static constexpr bool ShouldComputeFullV = internal::should_svd_compute_full_v(Options);
   static constexpr bool ShouldComputeThinV = internal::should_svd_compute_thin_v(Options);
   enum {
     DiagSizeAtCompileTime =
         internal::min_size_prefer_dynamic(MatrixType::RowsAtCompileTime, MatrixType::ColsAtCompileTime),
     MaxDiagSizeAtCompileTime =
         internal::min_size_prefer_dynamic(MatrixType::MaxRowsAtCompileTime, MatrixType::MaxColsAtCompileTime),
     MatrixUColsAtCompileTime = ShouldComputeThinU ? DiagSizeAtCompileTime : MatrixType::RowsAtCompileTime,
     MatrixVColsAtCompileTime = ShouldComputeThinV ? DiagSizeAtCompileTime : MatrixType::ColsAtCompileTime,
     MatrixUMaxColsAtCompileTime = ShouldComputeThinU ? MaxDiagSizeAtCompileTime : MatrixType::MaxRowsAtCompileTime,
     MatrixVMaxColsAtCompileTime = ShouldComputeThinV ? MaxDiagSizeAtCompileTime : MatrixType::MaxColsAtCompileTime
   };
 };
 }  // namespace internal

 /** \ingroup SVD_Module
  *
  *
  * \class SVDBase
  *
  * \brief Base class of SVD algorithms
  *
  * \tparam Derived the type of the actual SVD decomposition
  *
  * SVD decomposition consists in decomposing any n-by-p matrix \a A as a product
  *   \f[ A = U S V^* \f]
  * where \a U is a n-by-n unitary, \a V is a p-by-p unitary, and \a S is a n-by-p real positive matrix which is zero
  * outside of its main diagonal; the diagonal entries of S are known as the \em singular \em values of \a A and the
  * columns of \a U and \a V are known as the left and right \em singular \em vectors of \a A respectively.
  *
  * Singular values are always sorted in decreasing order.
  *
  *
  * You can ask for only \em thin \a U or \a V to be computed, meaning the following. In case of a rectangular n-by-p
  * matrix, letting \a m be the smaller value among \a n and \a p, there are only \a m singular vectors; the remaining
  * columns of \a U and \a V do not correspond to actual singular vectors. Asking for \em thin \a U or \a V means asking
  * for only their \a m first columns to be formed. So \a U is then a n-by-m matrix, and \a V is then a p-by-m matrix.
  * Notice that thin \a U and \a V are all you need for (least squares) solving.
  *
  * The status of the computation can be retrieved using the \a info() method. Unless \a info() returns \a Success, the
  * results should be not considered well defined.
  *
  * If the input matrix has inf or nan coefficients, the result of the computation is undefined, and \a info() will
  * return \a InvalidInput, but the computation is guaranteed to terminate in finite (and reasonable) time. \sa class
  * BDCSVD, class JacobiSVD
  */
 template <typename Derived>
 class SVDBase : public SolverBase<SVDBase<Derived> > {
  public:
   template <typename Derived_>
   friend struct internal::solve_assertion;

   typedef typename internal::traits<Derived>::MatrixType MatrixType;
   typedef typename MatrixType::Scalar Scalar;
   typedef typename NumTraits<typename MatrixType::Scalar>::Real RealScalar;
   typedef typename Eigen::internal::traits<SVDBase>::StorageIndex StorageIndex;

   static constexpr bool ShouldComputeFullU = internal::traits<Derived>::ShouldComputeFullU;
   static constexpr bool ShouldComputeThinU = internal::traits<Derived>::ShouldComputeThinU;
   static constexpr bool ShouldComputeFullV = internal::traits<Derived>::ShouldComputeFullV;
   static constexpr bool ShouldComputeThinV = internal::traits<Derived>::ShouldComputeThinV;

   enum {
     RowsAtCompileTime = MatrixType::RowsAtCompileTime,
     ColsAtCompileTime = MatrixType::ColsAtCompileTime,
     DiagSizeAtCompileTime = internal::min_size_prefer_dynamic(RowsAtCompileTime, ColsAtCompileTime),
     MaxRowsAtCompileTime = MatrixType::MaxRowsAtCompileTime,
     MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime,
     MaxDiagSizeAtCompileTime = internal::min_size_prefer_fixed(MaxRowsAtCompileTime, MaxColsAtCompileTime),
     MatrixOptions = internal::traits<MatrixType>::Options,
     MatrixUColsAtCompileTime = internal::traits<Derived>::MatrixUColsAtCompileTime,
     MatrixVColsAtCompileTime = internal::traits<Derived>::MatrixVColsAtCompileTime,
     MatrixUMaxColsAtCompileTime = internal::traits<Derived>::MatrixUMaxColsAtCompileTime,
     MatrixVMaxColsAtCompileTime = internal::traits<Derived>::MatrixVMaxColsAtCompileTime
   };

   EIGEN_STATIC_ASSERT(!(ShouldComputeFullU && ShouldComputeThinU), "SVDBase: Cannot request both full and thin U")
   EIGEN_STATIC_ASSERT(!(ShouldComputeFullV && ShouldComputeThinV), "SVDBase: Cannot request both full and thin V")

   typedef
       typename internal::make_proper_matrix_type<Scalar, RowsAtCompileTime, MatrixUColsAtCompileTime, MatrixOptions,
                                                  MaxRowsAtCompileTime, MatrixUMaxColsAtCompileTime>::type MatrixUType;
   typedef
       typename internal::make_proper_matrix_type<Scalar, ColsAtCompileTime, MatrixVColsAtCompileTime, MatrixOptions,
                                                  MaxColsAtCompileTime, MatrixVMaxColsAtCompileTime>::type MatrixVType;

   typedef typename internal::plain_diag_type<MatrixType, RealScalar>::type SingularValuesType;

   Derived& derived() { return *static_cast<Derived*>(this); }
   const Derived& derived() const { return *static_cast<const Derived*>(this); }

   /** \returns the \a U matrix.
    *
    * For the SVD decomposition of a n-by-p matrix, letting \a m be the minimum of \a n and \a p,
    * the U matrix is n-by-n if you asked for \link Eigen::ComputeFullU ComputeFullU \endlink, and is n-by-m if you asked
    * for \link Eigen::ComputeThinU ComputeThinU \endlink.
    *
    * The \a m first columns of \a U are the left singular vectors of the matrix being decomposed.
    *
    * This method asserts that you asked for \a U to be computed.
    */
   const MatrixUType& matrixU() const {
     _check_compute_assertions();
     eigen_assert(computeU() && "This SVD decomposition didn't compute U. Did you ask for it?");
     return m_matrixU;
   }

   /** \returns the \a V matrix.
    *
    * For the SVD decomposition of a n-by-p matrix, letting \a m be the minimum of \a n and \a p,
    * the V matrix is p-by-p if you asked for \link Eigen::ComputeFullV ComputeFullV \endlink, and is p-by-m if you asked
    * for \link Eigen::ComputeThinV ComputeThinV \endlink.
    *
    * The \a m first columns of \a V are the right singular vectors of the matrix being decomposed.
    *
    * This method asserts that you asked for \a V to be computed.
    */
   const MatrixVType& matrixV() const {
     _check_compute_assertions();
     eigen_assert(computeV() && "This SVD decomposition didn't compute V. Did you ask for it?");
     return m_matrixV;
   }

   /** \returns the vector of singular values.
    *
    * For the SVD decomposition of a n-by-p matrix, letting \a m be the minimum of \a n and \a p, the
    * returned vector has size \a m.  Singular values are always sorted in decreasing order.
    */
   const SingularValuesType& singularValues() const {
     _check_compute_assertions();
     return m_singularValues;
   }

   /** \returns the number of singular values that are not exactly 0 */
   Index nonzeroSingularValues() const {
     _check_compute_assertions();
     return m_nonzeroSingularValues;
   }

   /** \returns the rank of the matrix of which \c *this is the SVD.
    *
    * \note This method has to determine which singular values 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;
     _check_compute_assertions();
     if (m_singularValues.size() == 0) return 0;
     RealScalar premultiplied_threshold =
         numext::maxi<RealScalar>(m_singularValues.coeff(0) * threshold(), (std::numeric_limits<RealScalar>::min)());
     Index i = m_nonzeroSingularValues - 1;
     while (i >= 0 && m_singularValues.coeff(i) < premultiplied_threshold) --i;
     return i + 1;
   }

   /** Allows to prescribe a threshold to be used by certain methods, such as rank() and solve(),
    * which need to determine when singular values are to be considered nonzero.
    * This is not used for the SVD decomposition itself.
    *
    * When it needs to get the threshold value, Eigen calls threshold().
    * The default is \c NumTraits<Scalar>::epsilon()
    *
    * \param threshold The new value to use as the threshold.
    *
    * A singular value will be considered nonzero if its value is strictly greater than
    *  \f$ \vert singular value \vert \leqslant threshold \times \vert max singular value \vert \f$.
    *
    * If you want to come back to the default behavior, call setThreshold(Default_t)
    */
   Derived& setThreshold(const RealScalar& threshold) {
     m_usePrescribedThreshold = true;
     m_prescribedThreshold = threshold;
     return derived();
   }

   /** 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 svd.setThreshold(Eigen::Default); \endcode
    *
    * See the documentation of setThreshold(const RealScalar&).
    */
   Derived& setThreshold(Default_t) {
     m_usePrescribedThreshold = false;
     return derived();
   }

   /** 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);
     // this temporary is needed to workaround a MSVC issue
     Index diagSize = (std::max<Index>)(1, m_diagSize);
     return m_usePrescribedThreshold ? m_prescribedThreshold : RealScalar(diagSize) * NumTraits<Scalar>::epsilon();
   }

   /** \returns true if \a U (full or thin) is asked for in this SVD decomposition */
   inline bool computeU() const { return m_computeFullU || m_computeThinU; }
   /** \returns true if \a V (full or thin) is asked for in this SVD decomposition */
   inline bool computeV() const { return m_computeFullV || m_computeThinV; }

   inline Index rows() const { return m_rows.value(); }
   inline Index cols() const { return m_cols.value(); }
   inline Index diagSize() const { return m_diagSize.value(); }

 #ifdef EIGEN_PARSED_BY_DOXYGEN
   /** \returns a (least squares) solution of \f$ A x = b \f$ using the current SVD decomposition of A.
    *
    * \param b the right-hand-side of the equation to solve.
    *
    * \note Solving requires both U and V to be computed. Thin U and V are enough, there is no need for full U or V.
    *
    * \note SVD solving is implicitly least-squares. Thus, this method serves both purposes of exact solving and
    * least-squares solving. In other words, the returned solution is guaranteed to minimize the Euclidean norm \f$ \Vert
    * A x - b \Vert \f$.
    */
   template <typename Rhs>
   inline const Solve<Derived, Rhs> solve(const MatrixBase<Rhs>& b) const;
 #endif

   /** \brief Reports whether previous computation was successful.
    *
    * \returns \c Success if computation was successful.
    */
   EIGEN_DEVICE_FUNC ComputationInfo info() const {
     eigen_assert(m_isInitialized && "SVD is not initialized.");
     return m_info;
   }

 #ifndef EIGEN_PARSED_BY_DOXYGEN
   template <typename RhsType, typename DstType>
   void _solve_impl(const RhsType& rhs, DstType& dst) const;

   template <bool Conjugate, typename RhsType, typename DstType>
   void _solve_impl_transposed(const RhsType& rhs, DstType& dst) const;
 #endif

  protected:
   EIGEN_STATIC_ASSERT_NON_INTEGER(Scalar)

   void _check_compute_assertions() const { eigen_assert(m_isInitialized && "SVD is not initialized."); }

   template <bool Transpose_, typename Rhs>
   void _check_solve_assertion(const Rhs& b) const {
     EIGEN_ONLY_USED_FOR_DEBUG(b);
     _check_compute_assertions();
     eigen_assert(computeU() && computeV() &&
                  "SVDBase::solve(): Both unitaries U and V are required to be computed (thin unitaries suffice).");
     eigen_assert((Transpose_ ? cols() : rows()) == b.rows() &&
                  "SVDBase::solve(): invalid number of rows of the right hand side matrix b");
   }

   // return true if already allocated
   bool allocate(Index rows, Index cols, unsigned int computationOptions);

   MatrixUType m_matrixU;
   MatrixVType m_matrixV;
   SingularValuesType m_singularValues;
   ComputationInfo m_info;
   bool m_isInitialized, m_isAllocated, m_usePrescribedThreshold;
   bool m_computeFullU, m_computeThinU;
   bool m_computeFullV, m_computeThinV;
   unsigned int m_computationOptions;
   Index m_nonzeroSingularValues;
   internal::variable_if_dynamic<Index, RowsAtCompileTime> m_rows;
   internal::variable_if_dynamic<Index, ColsAtCompileTime> m_cols;
   internal::variable_if_dynamic<Index, DiagSizeAtCompileTime> m_diagSize;
   RealScalar m_prescribedThreshold;

   /** \brief Default Constructor.
    *
    * Default constructor of SVDBase
    */
   SVDBase()
       : m_matrixU(MatrixUType()),
         m_matrixV(MatrixVType()),
         m_singularValues(SingularValuesType()),
         m_info(Success),
         m_isInitialized(false),
         m_isAllocated(false),
         m_usePrescribedThreshold(false),
         m_computeFullU(ShouldComputeFullU),
         m_computeThinU(ShouldComputeThinU),
         m_computeFullV(ShouldComputeFullV),
         m_computeThinV(ShouldComputeThinV),
         m_computationOptions(internal::traits<Derived>::Options),
         m_nonzeroSingularValues(0),
         m_rows(RowsAtCompileTime),
         m_cols(ColsAtCompileTime),
         m_diagSize(DiagSizeAtCompileTime),
         m_prescribedThreshold(0) {}
 };

 #ifndef EIGEN_PARSED_BY_DOXYGEN
 template <typename Derived>
 template <typename RhsType, typename DstType>
 void SVDBase<Derived>::_solve_impl(const RhsType& rhs, DstType& dst) const {
   // A = U S V^*
   // So A^{-1} = V S^{-1} U^*

   Matrix<typename RhsType::Scalar, Dynamic, RhsType::ColsAtCompileTime, 0, MatrixType::MaxRowsAtCompileTime,
          RhsType::MaxColsAtCompileTime>
       tmp;
   Index l_rank = rank();
   tmp.noalias() = m_matrixU.leftCols(l_rank).adjoint() * rhs;
   tmp = m_singularValues.head(l_rank).asDiagonal().inverse() * tmp;
   dst = m_matrixV.leftCols(l_rank) * tmp;
 }

 template <typename Derived>
 template <bool Conjugate, typename RhsType, typename DstType>
 void SVDBase<Derived>::_solve_impl_transposed(const RhsType& rhs, DstType& dst) const {
   // A = U S V^*
   // So  A^{-*} = U S^{-1} V^*
   // And A^{-T} = U_conj S^{-1} V^T
   Matrix<typename RhsType::Scalar, Dynamic, RhsType::ColsAtCompileTime, 0, MatrixType::MaxRowsAtCompileTime,
          RhsType::MaxColsAtCompileTime>
       tmp;
   Index l_rank = rank();

   tmp.noalias() = m_matrixV.leftCols(l_rank).transpose().template conjugateIf<Conjugate>() * rhs;
   tmp = m_singularValues.head(l_rank).asDiagonal().inverse() * tmp;
   dst = m_matrixU.template conjugateIf<!Conjugate>().leftCols(l_rank) * tmp;
 }
 #endif

 template <typename Derived>
 bool SVDBase<Derived>::allocate(Index rows, Index cols, unsigned int computationOptions) {
   eigen_assert(rows >= 0 && cols >= 0);

   if (m_isAllocated && rows == m_rows.value() && cols == m_cols.value() && computationOptions == m_computationOptions) {
     return true;
   }

   m_rows.setValue(rows);
   m_cols.setValue(cols);
   m_info = Success;
   m_isInitialized = false;
   m_isAllocated = true;
   m_computationOptions = computationOptions;
   m_computeFullU = ShouldComputeFullU || internal::should_svd_compute_full_u(computationOptions);
   m_computeThinU = ShouldComputeThinU || internal::should_svd_compute_thin_u(computationOptions);
   m_computeFullV = ShouldComputeFullV || internal::should_svd_compute_full_v(computationOptions);
   m_computeThinV = ShouldComputeThinV || internal::should_svd_compute_thin_v(computationOptions);

   eigen_assert(!(m_computeFullU && m_computeThinU) && "SVDBase: you can't ask for both full and thin U");
   eigen_assert(!(m_computeFullV && m_computeThinV) && "SVDBase: you can't ask for both full and thin V");

   m_diagSize.setValue(numext::mini(m_rows.value(), m_cols.value()));
   m_singularValues.resize(m_diagSize.value());
   if (RowsAtCompileTime == Dynamic)
     m_matrixU.resize(m_rows.value(), m_computeFullU ? m_rows.value() : m_computeThinU ? m_diagSize.value() : 0);
   if (ColsAtCompileTime == Dynamic)
     m_matrixV.resize(m_cols.value(), m_computeFullV ? m_cols.value() : m_computeThinV ? m_diagSize.value() : 0);

   return false;
 }

 }  // namespace Eigen

 #endif  // EIGEN_SVDBASE_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2009-2010 Benoit Jacob <jacob.benoit.1@gmail.com>
	// Copyright (C) 2014 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// Copyright (C) 2013 Gauthier Brun <brun.gauthier@gmail.com>
	// Copyright (C) 2013 Nicolas Carre <nicolas.carre@ensimag.fr>
	// Copyright (C) 2013 Jean Ceccato <jean.ceccato@ensimag.fr>
	// Copyright (C) 2013 Pierre Zoppitelli <pierre.zoppitelli@ensimag.fr>
	//
	// 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_SVDBASE_H
	#define EIGEN_SVDBASE_H

	// IWYU pragma: private
	#include "./InternalHeaderCheck.h"

	namespace Eigen {

	namespace internal {

	enum OptionsMasks {
	QRPreconditionerBits = NoQRPreconditioner \| HouseholderQRPreconditioner \| ColPivHouseholderQRPreconditioner \|
	FullPivHouseholderQRPreconditioner,
	ComputationOptionsBits = ComputeThinU \| ComputeFullU \| ComputeThinV \| ComputeFullV
	};

	constexpr int get_qr_preconditioner(int options) { return options & QRPreconditionerBits; }

	constexpr int get_computation_options(int options) { return options & ComputationOptionsBits; }

	constexpr bool should_svd_compute_thin_u(int options) { return (options & ComputeThinU) != 0; }
	constexpr bool should_svd_compute_full_u(int options) { return (options & ComputeFullU) != 0; }
	constexpr bool should_svd_compute_thin_v(int options) { return (options & ComputeThinV) != 0; }
	constexpr bool should_svd_compute_full_v(int options) { return (options & ComputeFullV) != 0; }

	template <typename MatrixType, int Options>
	void check_svd_options_assertions(unsigned int computationOptions, Index rows, Index cols) {
	EIGEN_STATIC_ASSERT((Options & ComputationOptionsBits) == 0,
	"SVDBase: Cannot request U or V using both static and runtime options, even if they match. "
	"Requesting unitaries at runtime is DEPRECATED: "
	"Prefer requesting unitaries statically, using the Options template parameter.");
	eigen_assert(
	!(should_svd_compute_thin_u(computationOptions) && cols < rows && MatrixType::RowsAtCompileTime != Dynamic) &&
	!(should_svd_compute_thin_v(computationOptions) && rows < cols && MatrixType::ColsAtCompileTime != Dynamic) &&
	"SVDBase: If thin U is requested at runtime, your matrix must have more rows than columns or a dynamic number of "
	"rows."
	"Similarly, if thin V is requested at runtime, you matrix must have more columns than rows or a dynamic number "
	"of columns.");
	(void)computationOptions;
	(void)rows;
	(void)cols;
	}

	template <typename Derived>
	struct traits<SVDBase<Derived> > : traits<Derived> {
	typedef MatrixXpr XprKind;
	typedef SolverStorage StorageKind;
	typedef int StorageIndex;
	enum { Flags = 0 };
	};

	template <typename MatrixType, int Options_>
	struct svd_traits : traits<MatrixType> {
	static constexpr int Options = Options_;
	static constexpr bool ShouldComputeFullU = internal::should_svd_compute_full_u(Options);
	static constexpr bool ShouldComputeThinU = internal::should_svd_compute_thin_u(Options);
	static constexpr bool ShouldComputeFullV = internal::should_svd_compute_full_v(Options);
	static constexpr bool ShouldComputeThinV = internal::should_svd_compute_thin_v(Options);
	enum {
	DiagSizeAtCompileTime =
	internal::min_size_prefer_dynamic(MatrixType::RowsAtCompileTime, MatrixType::ColsAtCompileTime),
	MaxDiagSizeAtCompileTime =
	internal::min_size_prefer_dynamic(MatrixType::MaxRowsAtCompileTime, MatrixType::MaxColsAtCompileTime),
	MatrixUColsAtCompileTime = ShouldComputeThinU ? DiagSizeAtCompileTime : MatrixType::RowsAtCompileTime,
	MatrixVColsAtCompileTime = ShouldComputeThinV ? DiagSizeAtCompileTime : MatrixType::ColsAtCompileTime,
	MatrixUMaxColsAtCompileTime = ShouldComputeThinU ? MaxDiagSizeAtCompileTime : MatrixType::MaxRowsAtCompileTime,
	MatrixVMaxColsAtCompileTime = ShouldComputeThinV ? MaxDiagSizeAtCompileTime : MatrixType::MaxColsAtCompileTime
	};
	};
	} // namespace internal

	/** \ingroup SVD_Module
	*
	*
	* \class SVDBase
	*
	* \brief Base class of SVD algorithms
	*
	* \tparam Derived the type of the actual SVD decomposition
	*
	* SVD decomposition consists in decomposing any n-by-p matrix \a A as a product
	* \f[ A = U S V^* \f]
	* where \a U is a n-by-n unitary, \a V is a p-by-p unitary, and \a S is a n-by-p real positive matrix which is zero
	* outside of its main diagonal; the diagonal entries of S are known as the \em singular \em values of \a A and the
	* columns of \a U and \a V are known as the left and right \em singular \em vectors of \a A respectively.
	*
	* Singular values are always sorted in decreasing order.
	*
	*
	* You can ask for only \em thin \a U or \a V to be computed, meaning the following. In case of a rectangular n-by-p
	* matrix, letting \a m be the smaller value among \a n and \a p, there are only \a m singular vectors; the remaining
	* columns of \a U and \a V do not correspond to actual singular vectors. Asking for \em thin \a U or \a V means asking
	* for only their \a m first columns to be formed. So \a U is then a n-by-m matrix, and \a V is then a p-by-m matrix.
	* Notice that thin \a U and \a V are all you need for (least squares) solving.
	*
	* The status of the computation can be retrieved using the \a info() method. Unless \a info() returns \a Success, the
	* results should be not considered well defined.
	*
	* If the input matrix has inf or nan coefficients, the result of the computation is undefined, and \a info() will
	* return \a InvalidInput, but the computation is guaranteed to terminate in finite (and reasonable) time. \sa class
	* BDCSVD, class JacobiSVD
	*/
	template <typename Derived>
	class SVDBase : public SolverBase<SVDBase<Derived> > {
	public:
	template <typename Derived_>
	friend struct internal::solve_assertion;

	typedef typename internal::traits<Derived>::MatrixType MatrixType;
	typedef typename MatrixType::Scalar Scalar;
	typedef typename NumTraits<typename MatrixType::Scalar>::Real RealScalar;
	typedef typename Eigen::internal::traits<SVDBase>::StorageIndex StorageIndex;

	static constexpr bool ShouldComputeFullU = internal::traits<Derived>::ShouldComputeFullU;
	static constexpr bool ShouldComputeThinU = internal::traits<Derived>::ShouldComputeThinU;
	static constexpr bool ShouldComputeFullV = internal::traits<Derived>::ShouldComputeFullV;
	static constexpr bool ShouldComputeThinV = internal::traits<Derived>::ShouldComputeThinV;

	enum {
	RowsAtCompileTime = MatrixType::RowsAtCompileTime,
	ColsAtCompileTime = MatrixType::ColsAtCompileTime,
	DiagSizeAtCompileTime = internal::min_size_prefer_dynamic(RowsAtCompileTime, ColsAtCompileTime),
	MaxRowsAtCompileTime = MatrixType::MaxRowsAtCompileTime,
	MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime,
	MaxDiagSizeAtCompileTime = internal::min_size_prefer_fixed(MaxRowsAtCompileTime, MaxColsAtCompileTime),
	MatrixOptions = internal::traits<MatrixType>::Options,
	MatrixUColsAtCompileTime = internal::traits<Derived>::MatrixUColsAtCompileTime,
	MatrixVColsAtCompileTime = internal::traits<Derived>::MatrixVColsAtCompileTime,
	MatrixUMaxColsAtCompileTime = internal::traits<Derived>::MatrixUMaxColsAtCompileTime,
	MatrixVMaxColsAtCompileTime = internal::traits<Derived>::MatrixVMaxColsAtCompileTime
	};

	EIGEN_STATIC_ASSERT(!(ShouldComputeFullU && ShouldComputeThinU), "SVDBase: Cannot request both full and thin U")
	EIGEN_STATIC_ASSERT(!(ShouldComputeFullV && ShouldComputeThinV), "SVDBase: Cannot request both full and thin V")

	typedef
	typename internal::make_proper_matrix_type<Scalar, RowsAtCompileTime, MatrixUColsAtCompileTime, MatrixOptions,
	MaxRowsAtCompileTime, MatrixUMaxColsAtCompileTime>::type MatrixUType;
	typedef
	typename internal::make_proper_matrix_type<Scalar, ColsAtCompileTime, MatrixVColsAtCompileTime, MatrixOptions,
	MaxColsAtCompileTime, MatrixVMaxColsAtCompileTime>::type MatrixVType;

	typedef typename internal::plain_diag_type<MatrixType, RealScalar>::type SingularValuesType;

	Derived& derived() { return static_cast<Derived>(this); }
	const Derived& derived() const { return static_cast<const Derived>(this); }

	/** \returns the \a U matrix.
	*
	* For the SVD decomposition of a n-by-p matrix, letting \a m be the minimum of \a n and \a p,
	* the U matrix is n-by-n if you asked for \link Eigen::ComputeFullU ComputeFullU \endlink, and is n-by-m if you asked
	* for \link Eigen::ComputeThinU ComputeThinU \endlink.
	*
	* The \a m first columns of \a U are the left singular vectors of the matrix being decomposed.
	*
	* This method asserts that you asked for \a U to be computed.
	*/
	const MatrixUType& matrixU() const {
	_check_compute_assertions();
	eigen_assert(computeU() && "This SVD decomposition didn't compute U. Did you ask for it?");
	return m_matrixU;
	}

	/** \returns the \a V matrix.
	*
	* For the SVD decomposition of a n-by-p matrix, letting \a m be the minimum of \a n and \a p,
	* the V matrix is p-by-p if you asked for \link Eigen::ComputeFullV ComputeFullV \endlink, and is p-by-m if you asked
	* for \link Eigen::ComputeThinV ComputeThinV \endlink.
	*
	* The \a m first columns of \a V are the right singular vectors of the matrix being decomposed.
	*
	* This method asserts that you asked for \a V to be computed.
	*/
	const MatrixVType& matrixV() const {
	_check_compute_assertions();
	eigen_assert(computeV() && "This SVD decomposition didn't compute V. Did you ask for it?");
	return m_matrixV;
	}

	/** \returns the vector of singular values.
	*
	* For the SVD decomposition of a n-by-p matrix, letting \a m be the minimum of \a n and \a p, the
	* returned vector has size \a m. Singular values are always sorted in decreasing order.
	*/
	const SingularValuesType& singularValues() const {
	_check_compute_assertions();
	return m_singularValues;
	}

	/** \returns the number of singular values that are not exactly 0 */
	Index nonzeroSingularValues() const {
	_check_compute_assertions();
	return m_nonzeroSingularValues;
	}

	/** \returns the rank of the matrix of which \c *this is the SVD.
	*
	* \note This method has to determine which singular values 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;
	_check_compute_assertions();
	if (m_singularValues.size() == 0) return 0;
	RealScalar premultiplied_threshold =
	numext::maxi<RealScalar>(m_singularValues.coeff(0) * threshold(), (std::numeric_limits<RealScalar>::min)());
	Index i = m_nonzeroSingularValues - 1;
	while (i >= 0 && m_singularValues.coeff(i) < premultiplied_threshold) --i;
	return i + 1;
	}

	/** Allows to prescribe a threshold to be used by certain methods, such as rank() and solve(),
	* which need to determine when singular values are to be considered nonzero.
	* This is not used for the SVD decomposition itself.
	*
	* When it needs to get the threshold value, Eigen calls threshold().
	* The default is \c NumTraits<Scalar>::epsilon()
	*
	* \param threshold The new value to use as the threshold.
	*
	* A singular value will be considered nonzero if its value is strictly greater than
	* \f$ \vert singular value \vert \leqslant threshold \times \vert max singular value \vert \f$.
	*
	* If you want to come back to the default behavior, call setThreshold(Default_t)
	*/
	Derived& setThreshold(const RealScalar& threshold) {
	m_usePrescribedThreshold = true;
	m_prescribedThreshold = threshold;
	return derived();
	}

	/** 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 svd.setThreshold(Eigen::Default); \endcode
	*
	* See the documentation of setThreshold(const RealScalar&).
	*/
	Derived& setThreshold(Default_t) {
	m_usePrescribedThreshold = false;
	return derived();
	}

	/** 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);
	// this temporary is needed to workaround a MSVC issue
	Index diagSize = (std::max<Index>)(1, m_diagSize);
	return m_usePrescribedThreshold ? m_prescribedThreshold : RealScalar(diagSize) * NumTraits<Scalar>::epsilon();
	}

	/** \returns true if \a U (full or thin) is asked for in this SVD decomposition */
	inline bool computeU() const { return m_computeFullU \|\| m_computeThinU; }
	/** \returns true if \a V (full or thin) is asked for in this SVD decomposition */
	inline bool computeV() const { return m_computeFullV \|\| m_computeThinV; }

	inline Index rows() const { return m_rows.value(); }
	inline Index cols() const { return m_cols.value(); }
	inline Index diagSize() const { return m_diagSize.value(); }

	#ifdef EIGEN_PARSED_BY_DOXYGEN
	/** \returns a (least squares) solution of \f$ A x = b \f$ using the current SVD decomposition of A.
	*
	* \param b the right-hand-side of the equation to solve.
	*
	* \note Solving requires both U and V to be computed. Thin U and V are enough, there is no need for full U or V.
	*
	* \note SVD solving is implicitly least-squares. Thus, this method serves both purposes of exact solving and
	* least-squares solving. In other words, the returned solution is guaranteed to minimize the Euclidean norm \f$ \Vert
	* A x - b \Vert \f$.
	*/
	template <typename Rhs>
	inline const Solve<Derived, Rhs> solve(const MatrixBase<Rhs>& b) const;
	#endif

	/** \brief Reports whether previous computation was successful.
	*
	* \returns \c Success if computation was successful.
	*/
	EIGEN_DEVICE_FUNC ComputationInfo info() const {
	eigen_assert(m_isInitialized && "SVD is not initialized.");
	return m_info;
	}

	#ifndef EIGEN_PARSED_BY_DOXYGEN
	template <typename RhsType, typename DstType>
	void _solve_impl(const RhsType& rhs, DstType& dst) const;

	template <bool Conjugate, typename RhsType, typename DstType>
	void _solve_impl_transposed(const RhsType& rhs, DstType& dst) const;
	#endif

	protected:
	EIGEN_STATIC_ASSERT_NON_INTEGER(Scalar)

	void _check_compute_assertions() const { eigen_assert(m_isInitialized && "SVD is not initialized."); }

	template <bool Transpose_, typename Rhs>
	void _check_solve_assertion(const Rhs& b) const {
	EIGEN_ONLY_USED_FOR_DEBUG(b);
	_check_compute_assertions();
	eigen_assert(computeU() && computeV() &&
	"SVDBase::solve(): Both unitaries U and V are required to be computed (thin unitaries suffice).");
	eigen_assert((Transpose_ ? cols() : rows()) == b.rows() &&
	"SVDBase::solve(): invalid number of rows of the right hand side matrix b");
	}

	// return true if already allocated
	bool allocate(Index rows, Index cols, unsigned int computationOptions);

	MatrixUType m_matrixU;
	MatrixVType m_matrixV;
	SingularValuesType m_singularValues;
	ComputationInfo m_info;
	bool m_isInitialized, m_isAllocated, m_usePrescribedThreshold;
	bool m_computeFullU, m_computeThinU;
	bool m_computeFullV, m_computeThinV;
	unsigned int m_computationOptions;
	Index m_nonzeroSingularValues;
	internal::variable_if_dynamic<Index, RowsAtCompileTime> m_rows;
	internal::variable_if_dynamic<Index, ColsAtCompileTime> m_cols;
	internal::variable_if_dynamic<Index, DiagSizeAtCompileTime> m_diagSize;
	RealScalar m_prescribedThreshold;

	/** \brief Default Constructor.
	*
	* Default constructor of SVDBase
	*/
	SVDBase()
	: m_matrixU(MatrixUType()),
	m_matrixV(MatrixVType()),
	m_singularValues(SingularValuesType()),
	m_info(Success),
	m_isInitialized(false),
	m_isAllocated(false),
	m_usePrescribedThreshold(false),
	m_computeFullU(ShouldComputeFullU),
	m_computeThinU(ShouldComputeThinU),
	m_computeFullV(ShouldComputeFullV),
	m_computeThinV(ShouldComputeThinV),
	m_computationOptions(internal::traits<Derived>::Options),
	m_nonzeroSingularValues(0),
	m_rows(RowsAtCompileTime),
	m_cols(ColsAtCompileTime),
	m_diagSize(DiagSizeAtCompileTime),
	m_prescribedThreshold(0) {}
	};

	#ifndef EIGEN_PARSED_BY_DOXYGEN
	template <typename Derived>
	template <typename RhsType, typename DstType>
	void SVDBase<Derived>::_solve_impl(const RhsType& rhs, DstType& dst) const {
	// A = U S V^*
	// So A^{-1} = V S^{-1} U^*

	Matrix<typename RhsType::Scalar, Dynamic, RhsType::ColsAtCompileTime, 0, MatrixType::MaxRowsAtCompileTime,
	RhsType::MaxColsAtCompileTime>
	tmp;
	Index l_rank = rank();
	tmp.noalias() = m_matrixU.leftCols(l_rank).adjoint() * rhs;
	tmp = m_singularValues.head(l_rank).asDiagonal().inverse() * tmp;
	dst = m_matrixV.leftCols(l_rank) * tmp;
	}

	template <typename Derived>
	template <bool Conjugate, typename RhsType, typename DstType>
	void SVDBase<Derived>::_solve_impl_transposed(const RhsType& rhs, DstType& dst) const {
	// A = U S V^*
	// So A^{-} = U S^{-1} V^
	// And A^{-T} = U_conj S^{-1} V^T
	Matrix<typename RhsType::Scalar, Dynamic, RhsType::ColsAtCompileTime, 0, MatrixType::MaxRowsAtCompileTime,
	RhsType::MaxColsAtCompileTime>
	tmp;
	Index l_rank = rank();

	tmp.noalias() = m_matrixV.leftCols(l_rank).transpose().template conjugateIf<Conjugate>() * rhs;
	tmp = m_singularValues.head(l_rank).asDiagonal().inverse() * tmp;
	dst = m_matrixU.template conjugateIf<!Conjugate>().leftCols(l_rank) * tmp;
	}
	#endif

	template <typename Derived>
	bool SVDBase<Derived>::allocate(Index rows, Index cols, unsigned int computationOptions) {
	eigen_assert(rows >= 0 && cols >= 0);

	if (m_isAllocated && rows == m_rows.value() && cols == m_cols.value() && computationOptions == m_computationOptions) {
	return true;
	}

	m_rows.setValue(rows);
	m_cols.setValue(cols);
	m_info = Success;
	m_isInitialized = false;
	m_isAllocated = true;
	m_computationOptions = computationOptions;
	m_computeFullU = ShouldComputeFullU \|\| internal::should_svd_compute_full_u(computationOptions);
	m_computeThinU = ShouldComputeThinU \|\| internal::should_svd_compute_thin_u(computationOptions);
	m_computeFullV = ShouldComputeFullV \|\| internal::should_svd_compute_full_v(computationOptions);
	m_computeThinV = ShouldComputeThinV \|\| internal::should_svd_compute_thin_v(computationOptions);

	eigen_assert(!(m_computeFullU && m_computeThinU) && "SVDBase: you can't ask for both full and thin U");
	eigen_assert(!(m_computeFullV && m_computeThinV) && "SVDBase: you can't ask for both full and thin V");

	m_diagSize.setValue(numext::mini(m_rows.value(), m_cols.value()));
	m_singularValues.resize(m_diagSize.value());
	if (RowsAtCompileTime == Dynamic)
	m_matrixU.resize(m_rows.value(), m_computeFullU ? m_rows.value() : m_computeThinU ? m_diagSize.value() : 0);
	if (ColsAtCompileTime == Dynamic)
	m_matrixV.resize(m_cols.value(), m_computeFullV ? m_cols.value() : m_computeThinV ? m_diagSize.value() : 0);

	return false;
	}

	} // namespace Eigen

	#endif // EIGEN_SVDBASE_H