Eigen/src/Eigen2Support/SVD.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008 Gael Guennebaud <g.gael@free.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 EIGEN2_SVD_H
 #define EIGEN2_SVD_H

 namespace Eigen {

 /** \ingroup SVD_Module
   * \nonstableyet
   *
   * \class SVD
   *
   * \brief Standard SVD decomposition of a matrix and associated features
   *
   * \param MatrixType the type of the matrix of which we are computing the SVD decomposition
   *
   * This class performs a standard SVD decomposition of a real matrix A of size \c M x \c N
   * with \c M \>= \c N.
   *
   *
   * \sa MatrixBase::SVD()
   */
 template<typename MatrixType> class SVD
 {
   private:
     typedef typename MatrixType::Scalar Scalar;
     typedef typename NumTraits<typename MatrixType::Scalar>::Real RealScalar;

     enum {
       PacketSize = internal::packet_traits<Scalar>::size,
       AlignmentMask = int(PacketSize)-1,
       MinSize = EIGEN_SIZE_MIN_PREFER_DYNAMIC(MatrixType::RowsAtCompileTime, MatrixType::ColsAtCompileTime)
     };

     typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> ColVector;
     typedef Matrix<Scalar, MatrixType::ColsAtCompileTime, 1> RowVector;

     typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, MinSize> MatrixUType;
     typedef Matrix<Scalar, MatrixType::ColsAtCompileTime, MatrixType::ColsAtCompileTime> MatrixVType;
     typedef Matrix<Scalar, MinSize, 1> SingularValuesType;

   public:

     SVD() {} // a user who relied on compiler-generated default compiler reported problems with MSVC in 2.0.7

     SVD(const MatrixType& matrix)
       : m_matU(matrix.rows(), (std::min)(matrix.rows(), matrix.cols())),
         m_matV(matrix.cols(),matrix.cols()),
         m_sigma((std::min)(matrix.rows(),matrix.cols()))
     {
       compute(matrix);
     }

     template<typename OtherDerived, typename ResultType>
     bool solve(const MatrixBase<OtherDerived> &b, ResultType* result) const;

     const MatrixUType& matrixU() const { return m_matU; }
     const SingularValuesType& singularValues() const { return m_sigma; }
     const MatrixVType& matrixV() const { return m_matV; }

     void compute(const MatrixType& matrix);
     SVD& sort();

     template<typename UnitaryType, typename PositiveType>
     void computeUnitaryPositive(UnitaryType *unitary, PositiveType *positive) const;
     template<typename PositiveType, typename UnitaryType>
     void computePositiveUnitary(PositiveType *positive, UnitaryType *unitary) const;
     template<typename RotationType, typename ScalingType>
     void computeRotationScaling(RotationType *unitary, ScalingType *positive) const;
     template<typename ScalingType, typename RotationType>
     void computeScalingRotation(ScalingType *positive, RotationType *unitary) const;

   protected:
     /** \internal */
     MatrixUType m_matU;
     /** \internal */
     MatrixVType m_matV;
     /** \internal */
     SingularValuesType m_sigma;
 };

 /** Computes / recomputes the SVD decomposition A = U S V^* of \a matrix
   *
   * \note this code has been adapted from JAMA (public domain)
   */
 template<typename MatrixType>
 void SVD<MatrixType>::compute(const MatrixType& matrix)
 {
   const int m = matrix.rows();
   const int n = matrix.cols();
   const int nu = (std::min)(m,n);
   ei_assert(m>=n && "In Eigen 2.0, SVD only works for MxN matrices with M>=N. Sorry!");
   ei_assert(m>1 && "In Eigen 2.0, SVD doesn't work on 1x1 matrices");

   m_matU.resize(m, nu);
   m_matU.setZero();
   m_sigma.resize((std::min)(m,n));
   m_matV.resize(n,n);

   RowVector e(n);
   ColVector work(m);
   MatrixType matA(matrix);
   const bool wantu = true;
   const bool wantv = true;
   int i=0, j=0, k=0;

   // Reduce A to bidiagonal form, storing the diagonal elements
   // in s and the super-diagonal elements in e.
   int nct = (std::min)(m-1,n);
   int nrt = (std::max)(0,(std::min)(n-2,m));
   for (k = 0; k < (std::max)(nct,nrt); ++k)
   {
     if (k < nct)
     {
       // Compute the transformation for the k-th column and
       // place the k-th diagonal in m_sigma[k].
       m_sigma[k] = matA.col(k).end(m-k).norm();
       if (m_sigma[k] != 0.0) // FIXME
       {
         if (matA(k,k) < 0.0)
           m_sigma[k] = -m_sigma[k];
         matA.col(k).end(m-k) /= m_sigma[k];
         matA(k,k) += 1.0;
       }
       m_sigma[k] = -m_sigma[k];
     }

     for (j = k+1; j < n; ++j)
     {
       if ((k < nct) && (m_sigma[k] != 0.0))
       {
         // Apply the transformation.
         Scalar t = matA.col(k).end(m-k).eigen2_dot(matA.col(j).end(m-k)); // FIXME dot product or cwise prod + .sum() ??
         t = -t/matA(k,k);
         matA.col(j).end(m-k) += t * matA.col(k).end(m-k);
       }

       // Place the k-th row of A into e for the
       // subsequent calculation of the row transformation.
       e[j] = matA(k,j);
     }

     // Place the transformation in U for subsequent back multiplication.
     if (wantu & (k < nct))
       m_matU.col(k).end(m-k) = matA.col(k).end(m-k);

     if (k < nrt)
     {
       // Compute the k-th row transformation and place the
       // k-th super-diagonal in e[k].
       e[k] = e.end(n-k-1).norm();
       if (e[k] != 0.0)
       {
           if (e[k+1] < 0.0)
             e[k] = -e[k];
           e.end(n-k-1) /= e[k];
           e[k+1] += 1.0;
       }
       e[k] = -e[k];
       if ((k+1 < m) & (e[k] != 0.0))
       {
         // Apply the transformation.
         work.end(m-k-1) = matA.corner(BottomRight,m-k-1,n-k-1) * e.end(n-k-1);
         for (j = k+1; j < n; ++j)
           matA.col(j).end(m-k-1) += (-e[j]/e[k+1]) * work.end(m-k-1);
       }

       // Place the transformation in V for subsequent back multiplication.
       if (wantv)
         m_matV.col(k).end(n-k-1) = e.end(n-k-1);
     }
   }


   // Set up the final bidiagonal matrix or order p.
   int p = (std::min)(n,m+1);
   if (nct < n)
     m_sigma[nct] = matA(nct,nct);
   if (m < p)
     m_sigma[p-1] = 0.0;
   if (nrt+1 < p)
     e[nrt] = matA(nrt,p-1);
   e[p-1] = 0.0;

   // If required, generate U.
   if (wantu)
   {
     for (j = nct; j < nu; ++j)
     {
       m_matU.col(j).setZero();
       m_matU(j,j) = 1.0;
     }
     for (k = nct-1; k >= 0; k--)
     {
       if (m_sigma[k] != 0.0)
       {
         for (j = k+1; j < nu; ++j)
         {
           Scalar t = m_matU.col(k).end(m-k).eigen2_dot(m_matU.col(j).end(m-k)); // FIXME is it really a dot product we want ?
           t = -t/m_matU(k,k);
           m_matU.col(j).end(m-k) += t * m_matU.col(k).end(m-k);
         }
         m_matU.col(k).end(m-k) = - m_matU.col(k).end(m-k);
         m_matU(k,k) = Scalar(1) + m_matU(k,k);
         if (k-1>0)
           m_matU.col(k).start(k-1).setZero();
       }
       else
       {
         m_matU.col(k).setZero();
         m_matU(k,k) = 1.0;
       }
     }
   }

   // If required, generate V.
   if (wantv)
   {
     for (k = n-1; k >= 0; k--)
     {
       if ((k < nrt) & (e[k] != 0.0))
       {
         for (j = k+1; j < nu; ++j)
         {
           Scalar t = m_matV.col(k).end(n-k-1).eigen2_dot(m_matV.col(j).end(n-k-1)); // FIXME is it really a dot product we want ?
           t = -t/m_matV(k+1,k);
           m_matV.col(j).end(n-k-1) += t * m_matV.col(k).end(n-k-1);
         }
       }
       m_matV.col(k).setZero();
       m_matV(k,k) = 1.0;
     }
   }

   // Main iteration loop for the singular values.
   int pp = p-1;
   int iter = 0;
   Scalar eps = ei_pow(Scalar(2),ei_is_same_type<Scalar,float>::ret ? Scalar(-23) : Scalar(-52));
   while (p > 0)
   {
     int k=0;
     int kase=0;

     // Here is where a test for too many iterations would go.

     // This section of the program inspects for
     // negligible elements in the s and e arrays.  On
     // completion the variables kase and k are set as follows.

     // kase = 1     if s(p) and e[k-1] are negligible and k<p
     // kase = 2     if s(k) is negligible and k<p
     // kase = 3     if e[k-1] is negligible, k<p, and
     //              s(k), ..., s(p) are not negligible (qr step).
     // kase = 4     if e(p-1) is negligible (convergence).

     for (k = p-2; k >= -1; --k)
     {
       if (k == -1)
           break;
       if (ei_abs(e[k]) <= eps*(ei_abs(m_sigma[k]) + ei_abs(m_sigma[k+1])))
       {
           e[k] = 0.0;
           break;
       }
     }
     if (k == p-2)
     {
       kase = 4;
     }
     else
     {
       int ks;
       for (ks = p-1; ks >= k; --ks)
       {
         if (ks == k)
           break;
         Scalar t = (ks != p ? ei_abs(e[ks]) : Scalar(0)) + (ks != k+1 ? ei_abs(e[ks-1]) : Scalar(0));
         if (ei_abs(m_sigma[ks]) <= eps*t)
         {
           m_sigma[ks] = 0.0;
           break;
         }
       }
       if (ks == k)
       {
         kase = 3;
       }
       else if (ks == p-1)
       {
         kase = 1;
       }
       else
       {
         kase = 2;
         k = ks;
       }
     }
     ++k;

     // Perform the task indicated by kase.
     switch (kase)
     {

       // Deflate negligible s(p).
       case 1:
       {
         Scalar f(e[p-2]);
         e[p-2] = 0.0;
         for (j = p-2; j >= k; --j)
         {
           Scalar t(numext::hypot(m_sigma[j],f));
           Scalar cs(m_sigma[j]/t);
           Scalar sn(f/t);
           m_sigma[j] = t;
           if (j != k)
           {
             f = -sn*e[j-1];
             e[j-1] = cs*e[j-1];
           }
           if (wantv)
           {
             for (i = 0; i < n; ++i)
             {
               t = cs*m_matV(i,j) + sn*m_matV(i,p-1);
               m_matV(i,p-1) = -sn*m_matV(i,j) + cs*m_matV(i,p-1);
               m_matV(i,j) = t;
             }
           }
         }
       }
       break;

       // Split at negligible s(k).
       case 2:
       {
         Scalar f(e[k-1]);
         e[k-1] = 0.0;
         for (j = k; j < p; ++j)
         {
           Scalar t(numext::hypot(m_sigma[j],f));
           Scalar cs( m_sigma[j]/t);
           Scalar sn(f/t);
           m_sigma[j] = t;
           f = -sn*e[j];
           e[j] = cs*e[j];
           if (wantu)
           {
             for (i = 0; i < m; ++i)
             {
               t = cs*m_matU(i,j) + sn*m_matU(i,k-1);
               m_matU(i,k-1) = -sn*m_matU(i,j) + cs*m_matU(i,k-1);
               m_matU(i,j) = t;
             }
           }
         }
       }
       break;

       // Perform one qr step.
       case 3:
       {
         // Calculate the shift.
         Scalar scale = (std::max)((std::max)((std::max)((std::max)(
                         ei_abs(m_sigma[p-1]),ei_abs(m_sigma[p-2])),ei_abs(e[p-2])),
                         ei_abs(m_sigma[k])),ei_abs(e[k]));
         Scalar sp = m_sigma[p-1]/scale;
         Scalar spm1 = m_sigma[p-2]/scale;
         Scalar epm1 = e[p-2]/scale;
         Scalar sk = m_sigma[k]/scale;
         Scalar ek = e[k]/scale;
         Scalar b = ((spm1 + sp)*(spm1 - sp) + epm1*epm1)/Scalar(2);
         Scalar c = (sp*epm1)*(sp*epm1);
         Scalar shift(0);
         if ((b != 0.0) || (c != 0.0))
         {
           shift = ei_sqrt(b*b + c);
           if (b < 0.0)
             shift = -shift;
           shift = c/(b + shift);
         }
         Scalar f = (sk + sp)*(sk - sp) + shift;
         Scalar g = sk*ek;

         // Chase zeros.

         for (j = k; j < p-1; ++j)
         {
           Scalar t = numext::hypot(f,g);
           Scalar cs = f/t;
           Scalar sn = g/t;
           if (j != k)
             e[j-1] = t;
           f = cs*m_sigma[j] + sn*e[j];
           e[j] = cs*e[j] - sn*m_sigma[j];
           g = sn*m_sigma[j+1];
           m_sigma[j+1] = cs*m_sigma[j+1];
           if (wantv)
           {
             for (i = 0; i < n; ++i)
             {
               t = cs*m_matV(i,j) + sn*m_matV(i,j+1);
               m_matV(i,j+1) = -sn*m_matV(i,j) + cs*m_matV(i,j+1);
               m_matV(i,j) = t;
             }
           }
           t = numext::hypot(f,g);
           cs = f/t;
           sn = g/t;
           m_sigma[j] = t;
           f = cs*e[j] + sn*m_sigma[j+1];
           m_sigma[j+1] = -sn*e[j] + cs*m_sigma[j+1];
           g = sn*e[j+1];
           e[j+1] = cs*e[j+1];
           if (wantu && (j < m-1))
           {
             for (i = 0; i < m; ++i)
             {
               t = cs*m_matU(i,j) + sn*m_matU(i,j+1);
               m_matU(i,j+1) = -sn*m_matU(i,j) + cs*m_matU(i,j+1);
               m_matU(i,j) = t;
             }
           }
         }
         e[p-2] = f;
         iter = iter + 1;
       }
       break;

       // Convergence.
       case 4:
       {
         // Make the singular values positive.
         if (m_sigma[k] <= 0.0)
         {
           m_sigma[k] = m_sigma[k] < Scalar(0) ? -m_sigma[k] : Scalar(0);
           if (wantv)
             m_matV.col(k).start(pp+1) = -m_matV.col(k).start(pp+1);
         }

         // Order the singular values.
         while (k < pp)
         {
           if (m_sigma[k] >= m_sigma[k+1])
             break;
           Scalar t = m_sigma[k];
           m_sigma[k] = m_sigma[k+1];
           m_sigma[k+1] = t;
           if (wantv && (k < n-1))
             m_matV.col(k).swap(m_matV.col(k+1));
           if (wantu && (k < m-1))
             m_matU.col(k).swap(m_matU.col(k+1));
           ++k;
         }
         iter = 0;
         p--;
       }
       break;
     } // end big switch
   } // end iterations
 }

 template<typename MatrixType>
 SVD<MatrixType>& SVD<MatrixType>::sort()
 {
   int mu = m_matU.rows();
   int mv = m_matV.rows();
   int n  = m_matU.cols();

   for (int i=0; i<n; ++i)
   {
     int  k = i;
     Scalar p = m_sigma.coeff(i);

     for (int j=i+1; j<n; ++j)
     {
       if (m_sigma.coeff(j) > p)
       {
         k = j;
         p = m_sigma.coeff(j);
       }
     }
     if (k != i)
     {
       m_sigma.coeffRef(k) = m_sigma.coeff(i);  // i.e.
       m_sigma.coeffRef(i) = p;                 // swaps the i-th and the k-th elements

       int j = mu;
       for(int s=0; j!=0; ++s, --j)
         std::swap(m_matU.coeffRef(s,i), m_matU.coeffRef(s,k));

       j = mv;
       for (int s=0; j!=0; ++s, --j)
         std::swap(m_matV.coeffRef(s,i), m_matV.coeffRef(s,k));
     }
   }
   return *this;
 }

 /** \returns the solution of \f$ A x = b \f$ using the current SVD decomposition of A.
   * The parts of the solution corresponding to zero singular values are ignored.
   *
   * \sa MatrixBase::svd(), LU::solve(), LLT::solve()
   */
 template<typename MatrixType>
 template<typename OtherDerived, typename ResultType>
 bool SVD<MatrixType>::solve(const MatrixBase<OtherDerived> &b, ResultType* result) const
 {
   ei_assert(b.rows() == m_matU.rows());

   Scalar maxVal = m_sigma.cwise().abs().maxCoeff();
   for (int j=0; j<b.cols(); ++j)
   {
     Matrix<Scalar,MatrixUType::RowsAtCompileTime,1> aux = m_matU.transpose() * b.col(j);

     for (int i = 0; i <m_matU.cols(); ++i)
     {
       Scalar si = m_sigma.coeff(i);
       if (ei_isMuchSmallerThan(ei_abs(si),maxVal))
         aux.coeffRef(i) = 0;
       else
         aux.coeffRef(i) /= si;
     }

     result->col(j) = m_matV * aux;
   }
   return true;
 }

 /** Computes the polar decomposition of the matrix, as a product unitary x positive.
   *
   * If either pointer is zero, the corresponding computation is skipped.
   *
   * Only for square matrices.
   *
   * \sa computePositiveUnitary(), computeRotationScaling()
   */
 template<typename MatrixType>
 template<typename UnitaryType, typename PositiveType>
 void SVD<MatrixType>::computeUnitaryPositive(UnitaryType *unitary,
                                              PositiveType *positive) const
 {
   ei_assert(m_matU.cols() == m_matV.cols() && "Polar decomposition is only for square matrices");
   if(unitary) *unitary = m_matU * m_matV.adjoint();
   if(positive) *positive = m_matV * m_sigma.asDiagonal() * m_matV.adjoint();
 }

 /** Computes the polar decomposition of the matrix, as a product positive x unitary.
   *
   * If either pointer is zero, the corresponding computation is skipped.
   *
   * Only for square matrices.
   *
   * \sa computeUnitaryPositive(), computeRotationScaling()
   */
 template<typename MatrixType>
 template<typename UnitaryType, typename PositiveType>
 void SVD<MatrixType>::computePositiveUnitary(UnitaryType *positive,
                                              PositiveType *unitary) const
 {
   ei_assert(m_matU.rows() == m_matV.rows() && "Polar decomposition is only for square matrices");
   if(unitary) *unitary = m_matU * m_matV.adjoint();
   if(positive) *positive = m_matU * m_sigma.asDiagonal() * m_matU.adjoint();
 }

 /** decomposes the matrix as a product rotation x scaling, the scaling being
   * not necessarily positive.
   *
   * If either pointer is zero, the corresponding computation is skipped.
   *
   * This method requires the Geometry module.
   *
   * \sa computeScalingRotation(), computeUnitaryPositive()
   */
 template<typename MatrixType>
 template<typename RotationType, typename ScalingType>
 void SVD<MatrixType>::computeRotationScaling(RotationType *rotation, ScalingType *scaling) const
 {
   ei_assert(m_matU.rows() == m_matV.rows() && "Polar decomposition is only for square matrices");
   Scalar x = (m_matU * m_matV.adjoint()).determinant(); // so x has absolute value 1
   Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> sv(m_sigma);
   sv.coeffRef(0) *= x;
   if(scaling) scaling->lazyAssign(m_matV * sv.asDiagonal() * m_matV.adjoint());
   if(rotation)
   {
     MatrixType m(m_matU);
     m.col(0) /= x;
     rotation->lazyAssign(m * m_matV.adjoint());
   }
 }

 /** decomposes the matrix as a product scaling x rotation, the scaling being
   * not necessarily positive.
   *
   * If either pointer is zero, the corresponding computation is skipped.
   *
   * This method requires the Geometry module.
   *
   * \sa computeRotationScaling(), computeUnitaryPositive()
   */
 template<typename MatrixType>
 template<typename ScalingType, typename RotationType>
 void SVD<MatrixType>::computeScalingRotation(ScalingType *scaling, RotationType *rotation) const
 {
   ei_assert(m_matU.rows() == m_matV.rows() && "Polar decomposition is only for square matrices");
   Scalar x = (m_matU * m_matV.adjoint()).determinant(); // so x has absolute value 1
   Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> sv(m_sigma);
   sv.coeffRef(0) *= x;
   if(scaling) scaling->lazyAssign(m_matU * sv.asDiagonal() * m_matU.adjoint());
   if(rotation)
   {
     MatrixType m(m_matU);
     m.col(0) /= x;
     rotation->lazyAssign(m * m_matV.adjoint());
   }
 }


 /** \svd_module
   * \returns the SVD decomposition of \c *this
   */
 template<typename Derived>
 inline SVD<typename MatrixBase<Derived>::PlainObject>
 MatrixBase<Derived>::svd() const
 {
   return SVD<PlainObject>(derived());
 }

 } // end namespace Eigen

 #endif // EIGEN2_SVD_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008 Gael Guennebaud <g.gael@free.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 EIGEN2_SVD_H
	#define EIGEN2_SVD_H

	namespace Eigen {

	/** \ingroup SVD_Module
	* \nonstableyet
	*
	* \class SVD
	*
	* \brief Standard SVD decomposition of a matrix and associated features
	*
	* \param MatrixType the type of the matrix of which we are computing the SVD decomposition
	*
	* This class performs a standard SVD decomposition of a real matrix A of size \c M x \c N
	* with \c M \>= \c N.
	*
	*
	* \sa MatrixBase::SVD()
	*/
	template<typename MatrixType> class SVD
	{
	private:
	typedef typename MatrixType::Scalar Scalar;
	typedef typename NumTraits<typename MatrixType::Scalar>::Real RealScalar;

	enum {
	PacketSize = internal::packet_traits<Scalar>::size,
	AlignmentMask = int(PacketSize)-1,
	MinSize = EIGEN_SIZE_MIN_PREFER_DYNAMIC(MatrixType::RowsAtCompileTime, MatrixType::ColsAtCompileTime)
	};

	typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> ColVector;
	typedef Matrix<Scalar, MatrixType::ColsAtCompileTime, 1> RowVector;

	typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, MinSize> MatrixUType;
	typedef Matrix<Scalar, MatrixType::ColsAtCompileTime, MatrixType::ColsAtCompileTime> MatrixVType;
	typedef Matrix<Scalar, MinSize, 1> SingularValuesType;

	public:

	SVD() {} // a user who relied on compiler-generated default compiler reported problems with MSVC in 2.0.7

	SVD(const MatrixType& matrix)
	: m_matU(matrix.rows(), (std::min)(matrix.rows(), matrix.cols())),
	m_matV(matrix.cols(),matrix.cols()),
	m_sigma((std::min)(matrix.rows(),matrix.cols()))
	{
	compute(matrix);
	}

	template<typename OtherDerived, typename ResultType>
	bool solve(const MatrixBase<OtherDerived> &b, ResultType* result) const;

	const MatrixUType& matrixU() const { return m_matU; }
	const SingularValuesType& singularValues() const { return m_sigma; }
	const MatrixVType& matrixV() const { return m_matV; }

	void compute(const MatrixType& matrix);
	SVD& sort();

	template<typename UnitaryType, typename PositiveType>
	void computeUnitaryPositive(UnitaryType unitary, PositiveType positive) const;
	template<typename PositiveType, typename UnitaryType>
	void computePositiveUnitary(PositiveType positive, UnitaryType unitary) const;
	template<typename RotationType, typename ScalingType>
	void computeRotationScaling(RotationType unitary, ScalingType positive) const;
	template<typename ScalingType, typename RotationType>
	void computeScalingRotation(ScalingType positive, RotationType unitary) const;

	protected:
	/** \internal */
	MatrixUType m_matU;
	/** \internal */
	MatrixVType m_matV;
	/** \internal */
	SingularValuesType m_sigma;
	};

	/** Computes / recomputes the SVD decomposition A = U S V^* of \a matrix
	*
	* \note this code has been adapted from JAMA (public domain)
	*/
	template<typename MatrixType>
	void SVD<MatrixType>::compute(const MatrixType& matrix)
	{
	const int m = matrix.rows();
	const int n = matrix.cols();
	const int nu = (std::min)(m,n);
	ei_assert(m>=n && "In Eigen 2.0, SVD only works for MxN matrices with M>=N. Sorry!");
	ei_assert(m>1 && "In Eigen 2.0, SVD doesn't work on 1x1 matrices");

	m_matU.resize(m, nu);
	m_matU.setZero();
	m_sigma.resize((std::min)(m,n));
	m_matV.resize(n,n);

	RowVector e(n);
	ColVector work(m);
	MatrixType matA(matrix);
	const bool wantu = true;
	const bool wantv = true;
	int i=0, j=0, k=0;

	// Reduce A to bidiagonal form, storing the diagonal elements
	// in s and the super-diagonal elements in e.
	int nct = (std::min)(m-1,n);
	int nrt = (std::max)(0,(std::min)(n-2,m));
	for (k = 0; k < (std::max)(nct,nrt); ++k)
	{
	if (k < nct)
	{
	// Compute the transformation for the k-th column and
	// place the k-th diagonal in m_sigma[k].
	m_sigma[k] = matA.col(k).end(m-k).norm();
	if (m_sigma[k] != 0.0) // FIXME
	{
	if (matA(k,k) < 0.0)
	m_sigma[k] = -m_sigma[k];
	matA.col(k).end(m-k) /= m_sigma[k];
	matA(k,k) += 1.0;
	}
	m_sigma[k] = -m_sigma[k];
	}

	for (j = k+1; j < n; ++j)
	{
	if ((k < nct) && (m_sigma[k] != 0.0))
	{
	// Apply the transformation.
	Scalar t = matA.col(k).end(m-k).eigen2_dot(matA.col(j).end(m-k)); // FIXME dot product or cwise prod + .sum() ??
	t = -t/matA(k,k);
	matA.col(j).end(m-k) += t * matA.col(k).end(m-k);
	}

	// Place the k-th row of A into e for the
	// subsequent calculation of the row transformation.
	e[j] = matA(k,j);
	}

	// Place the transformation in U for subsequent back multiplication.
	if (wantu & (k < nct))
	m_matU.col(k).end(m-k) = matA.col(k).end(m-k);

	if (k < nrt)
	{
	// Compute the k-th row transformation and place the
	// k-th super-diagonal in e[k].
	e[k] = e.end(n-k-1).norm();
	if (e[k] != 0.0)
	{
	if (e[k+1] < 0.0)
	e[k] = -e[k];
	e.end(n-k-1) /= e[k];
	e[k+1] += 1.0;
	}
	e[k] = -e[k];
	if ((k+1 < m) & (e[k] != 0.0))
	{
	// Apply the transformation.
	work.end(m-k-1) = matA.corner(BottomRight,m-k-1,n-k-1) * e.end(n-k-1);
	for (j = k+1; j < n; ++j)
	matA.col(j).end(m-k-1) += (-e[j]/e[k+1]) * work.end(m-k-1);
	}

	// Place the transformation in V for subsequent back multiplication.
	if (wantv)
	m_matV.col(k).end(n-k-1) = e.end(n-k-1);
	}
	}


	// Set up the final bidiagonal matrix or order p.
	int p = (std::min)(n,m+1);
	if (nct < n)
	m_sigma[nct] = matA(nct,nct);
	if (m < p)
	m_sigma[p-1] = 0.0;
	if (nrt+1 < p)
	e[nrt] = matA(nrt,p-1);
	e[p-1] = 0.0;

	// If required, generate U.
	if (wantu)
	{
	for (j = nct; j < nu; ++j)
	{
	m_matU.col(j).setZero();
	m_matU(j,j) = 1.0;
	}
	for (k = nct-1; k >= 0; k--)
	{
	if (m_sigma[k] != 0.0)
	{
	for (j = k+1; j < nu; ++j)
	{
	Scalar t = m_matU.col(k).end(m-k).eigen2_dot(m_matU.col(j).end(m-k)); // FIXME is it really a dot product we want ?
	t = -t/m_matU(k,k);
	m_matU.col(j).end(m-k) += t * m_matU.col(k).end(m-k);
	}
	m_matU.col(k).end(m-k) = - m_matU.col(k).end(m-k);
	m_matU(k,k) = Scalar(1) + m_matU(k,k);
	if (k-1>0)
	m_matU.col(k).start(k-1).setZero();
	}
	else
	{
	m_matU.col(k).setZero();
	m_matU(k,k) = 1.0;
	}
	}
	}

	// If required, generate V.
	if (wantv)
	{
	for (k = n-1; k >= 0; k--)
	{
	if ((k < nrt) & (e[k] != 0.0))
	{
	for (j = k+1; j < nu; ++j)
	{
	Scalar t = m_matV.col(k).end(n-k-1).eigen2_dot(m_matV.col(j).end(n-k-1)); // FIXME is it really a dot product we want ?
	t = -t/m_matV(k+1,k);
	m_matV.col(j).end(n-k-1) += t * m_matV.col(k).end(n-k-1);
	}
	}
	m_matV.col(k).setZero();
	m_matV(k,k) = 1.0;
	}
	}

	// Main iteration loop for the singular values.
	int pp = p-1;
	int iter = 0;
	Scalar eps = ei_pow(Scalar(2),ei_is_same_type<Scalar,float>::ret ? Scalar(-23) : Scalar(-52));
	while (p > 0)
	{
	int k=0;
	int kase=0;

	// Here is where a test for too many iterations would go.

	// This section of the program inspects for
	// negligible elements in the s and e arrays. On
	// completion the variables kase and k are set as follows.

	// kase = 1 if s(p) and e[k-1] are negligible and k<p
	// kase = 2 if s(k) is negligible and k<p
	// kase = 3 if e[k-1] is negligible, k<p, and
	// s(k), ..., s(p) are not negligible (qr step).
	// kase = 4 if e(p-1) is negligible (convergence).

	for (k = p-2; k >= -1; --k)
	{
	if (k == -1)
	break;
	if (ei_abs(e[k]) <= eps*(ei_abs(m_sigma[k]) + ei_abs(m_sigma[k+1])))
	{
	e[k] = 0.0;
	break;
	}
	}
	if (k == p-2)
	{
	kase = 4;
	}
	else
	{
	int ks;
	for (ks = p-1; ks >= k; --ks)
	{
	if (ks == k)
	break;
	Scalar t = (ks != p ? ei_abs(e[ks]) : Scalar(0)) + (ks != k+1 ? ei_abs(e[ks-1]) : Scalar(0));
	if (ei_abs(m_sigma[ks]) <= eps*t)
	{
	m_sigma[ks] = 0.0;
	break;
	}
	}
	if (ks == k)
	{
	kase = 3;
	}
	else if (ks == p-1)
	{
	kase = 1;
	}
	else
	{
	kase = 2;
	k = ks;
	}
	}
	++k;

	// Perform the task indicated by kase.
	switch (kase)
	{

	// Deflate negligible s(p).
	case 1:
	{
	Scalar f(e[p-2]);
	e[p-2] = 0.0;
	for (j = p-2; j >= k; --j)
	{
	Scalar t(numext::hypot(m_sigma[j],f));
	Scalar cs(m_sigma[j]/t);
	Scalar sn(f/t);
	m_sigma[j] = t;
	if (j != k)
	{
	f = -sn*e[j-1];
	e[j-1] = cs*e[j-1];
	}
	if (wantv)
	{
	for (i = 0; i < n; ++i)
	{
	t = csm_matV(i,j) + snm_matV(i,p-1);
	m_matV(i,p-1) = -snm_matV(i,j) + csm_matV(i,p-1);
	m_matV(i,j) = t;
	}
	}
	}
	}
	break;

	// Split at negligible s(k).
	case 2:
	{
	Scalar f(e[k-1]);
	e[k-1] = 0.0;
	for (j = k; j < p; ++j)
	{
	Scalar t(numext::hypot(m_sigma[j],f));
	Scalar cs( m_sigma[j]/t);
	Scalar sn(f/t);
	m_sigma[j] = t;
	f = -sn*e[j];
	e[j] = cs*e[j];
	if (wantu)
	{
	for (i = 0; i < m; ++i)
	{
	t = csm_matU(i,j) + snm_matU(i,k-1);
	m_matU(i,k-1) = -snm_matU(i,j) + csm_matU(i,k-1);
	m_matU(i,j) = t;
	}
	}
	}
	}
	break;

	// Perform one qr step.
	case 3:
	{
	// Calculate the shift.
	Scalar scale = (std::max)((std::max)((std::max)((std::max)(
	ei_abs(m_sigma[p-1]),ei_abs(m_sigma[p-2])),ei_abs(e[p-2])),
	ei_abs(m_sigma[k])),ei_abs(e[k]));
	Scalar sp = m_sigma[p-1]/scale;
	Scalar spm1 = m_sigma[p-2]/scale;
	Scalar epm1 = e[p-2]/scale;
	Scalar sk = m_sigma[k]/scale;
	Scalar ek = e[k]/scale;
	Scalar b = ((spm1 + sp)(spm1 - sp) + epm1epm1)/Scalar(2);
	Scalar c = (spepm1)(sp*epm1);
	Scalar shift(0);
	if ((b != 0.0) \|\| (c != 0.0))
	{
	shift = ei_sqrt(b*b + c);
	if (b < 0.0)
	shift = -shift;
	shift = c/(b + shift);
	}
	Scalar f = (sk + sp)*(sk - sp) + shift;
	Scalar g = sk*ek;

	// Chase zeros.

	for (j = k; j < p-1; ++j)
	{
	Scalar t = numext::hypot(f,g);
	Scalar cs = f/t;
	Scalar sn = g/t;
	if (j != k)
	e[j-1] = t;
	f = csm_sigma[j] + sne[j];
	e[j] = cse[j] - snm_sigma[j];
	g = sn*m_sigma[j+1];
	m_sigma[j+1] = cs*m_sigma[j+1];
	if (wantv)
	{
	for (i = 0; i < n; ++i)
	{
	t = csm_matV(i,j) + snm_matV(i,j+1);
	m_matV(i,j+1) = -snm_matV(i,j) + csm_matV(i,j+1);
	m_matV(i,j) = t;
	}
	}
	t = numext::hypot(f,g);
	cs = f/t;
	sn = g/t;
	m_sigma[j] = t;
	f = cse[j] + snm_sigma[j+1];
	m_sigma[j+1] = -sne[j] + csm_sigma[j+1];
	g = sn*e[j+1];
	e[j+1] = cs*e[j+1];
	if (wantu && (j < m-1))
	{
	for (i = 0; i < m; ++i)
	{
	t = csm_matU(i,j) + snm_matU(i,j+1);
	m_matU(i,j+1) = -snm_matU(i,j) + csm_matU(i,j+1);
	m_matU(i,j) = t;
	}
	}
	}
	e[p-2] = f;
	iter = iter + 1;
	}
	break;

	// Convergence.
	case 4:
	{
	// Make the singular values positive.
	if (m_sigma[k] <= 0.0)
	{
	m_sigma[k] = m_sigma[k] < Scalar(0) ? -m_sigma[k] : Scalar(0);
	if (wantv)
	m_matV.col(k).start(pp+1) = -m_matV.col(k).start(pp+1);
	}

	// Order the singular values.
	while (k < pp)
	{
	if (m_sigma[k] >= m_sigma[k+1])
	break;
	Scalar t = m_sigma[k];
	m_sigma[k] = m_sigma[k+1];
	m_sigma[k+1] = t;
	if (wantv && (k < n-1))
	m_matV.col(k).swap(m_matV.col(k+1));
	if (wantu && (k < m-1))
	m_matU.col(k).swap(m_matU.col(k+1));
	++k;
	}
	iter = 0;
	p--;
	}
	break;
	} // end big switch
	} // end iterations
	}

	template<typename MatrixType>
	SVD<MatrixType>& SVD<MatrixType>::sort()
	{
	int mu = m_matU.rows();
	int mv = m_matV.rows();
	int n = m_matU.cols();

	for (int i=0; i<n; ++i)
	{
	int k = i;
	Scalar p = m_sigma.coeff(i);

	for (int j=i+1; j<n; ++j)
	{
	if (m_sigma.coeff(j) > p)
	{
	k = j;
	p = m_sigma.coeff(j);
	}
	}
	if (k != i)
	{
	m_sigma.coeffRef(k) = m_sigma.coeff(i); // i.e.
	m_sigma.coeffRef(i) = p; // swaps the i-th and the k-th elements

	int j = mu;
	for(int s=0; j!=0; ++s, --j)
	std::swap(m_matU.coeffRef(s,i), m_matU.coeffRef(s,k));

	j = mv;
	for (int s=0; j!=0; ++s, --j)
	std::swap(m_matV.coeffRef(s,i), m_matV.coeffRef(s,k));
	}
	}
	return *this;
	}

	/** \returns the solution of \f$ A x = b \f$ using the current SVD decomposition of A.
	* The parts of the solution corresponding to zero singular values are ignored.
	*
	* \sa MatrixBase::svd(), LU::solve(), LLT::solve()
	*/
	template<typename MatrixType>
	template<typename OtherDerived, typename ResultType>
	bool SVD<MatrixType>::solve(const MatrixBase<OtherDerived> &b, ResultType* result) const
	{
	ei_assert(b.rows() == m_matU.rows());

	Scalar maxVal = m_sigma.cwise().abs().maxCoeff();
	for (int j=0; j<b.cols(); ++j)
	{
	Matrix<Scalar,MatrixUType::RowsAtCompileTime,1> aux = m_matU.transpose() * b.col(j);

	for (int i = 0; i <m_matU.cols(); ++i)
	{
	Scalar si = m_sigma.coeff(i);
	if (ei_isMuchSmallerThan(ei_abs(si),maxVal))
	aux.coeffRef(i) = 0;
	else
	aux.coeffRef(i) /= si;
	}

	result->col(j) = m_matV * aux;
	}
	return true;
	}

	/** Computes the polar decomposition of the matrix, as a product unitary x positive.
	*
	* If either pointer is zero, the corresponding computation is skipped.
	*
	* Only for square matrices.
	*
	* \sa computePositiveUnitary(), computeRotationScaling()
	*/
	template<typename MatrixType>
	template<typename UnitaryType, typename PositiveType>
	void SVD<MatrixType>::computeUnitaryPositive(UnitaryType *unitary,
	PositiveType *positive) const
	{
	ei_assert(m_matU.cols() == m_matV.cols() && "Polar decomposition is only for square matrices");
	if(unitary) unitary = m_matU m_matV.adjoint();
	if(positive) positive = m_matV m_sigma.asDiagonal() * m_matV.adjoint();
	}

	/** Computes the polar decomposition of the matrix, as a product positive x unitary.
	*
	* If either pointer is zero, the corresponding computation is skipped.
	*
	* Only for square matrices.
	*
	* \sa computeUnitaryPositive(), computeRotationScaling()
	*/
	template<typename MatrixType>
	template<typename UnitaryType, typename PositiveType>
	void SVD<MatrixType>::computePositiveUnitary(UnitaryType *positive,
	PositiveType *unitary) const
	{
	ei_assert(m_matU.rows() == m_matV.rows() && "Polar decomposition is only for square matrices");
	if(unitary) unitary = m_matU m_matV.adjoint();
	if(positive) positive = m_matU m_sigma.asDiagonal() * m_matU.adjoint();
	}

	/** decomposes the matrix as a product rotation x scaling, the scaling being
	* not necessarily positive.
	*
	* If either pointer is zero, the corresponding computation is skipped.
	*
	* This method requires the Geometry module.
	*
	* \sa computeScalingRotation(), computeUnitaryPositive()
	*/
	template<typename MatrixType>
	template<typename RotationType, typename ScalingType>
	void SVD<MatrixType>::computeRotationScaling(RotationType rotation, ScalingType scaling) const
	{
	ei_assert(m_matU.rows() == m_matV.rows() && "Polar decomposition is only for square matrices");
	Scalar x = (m_matU * m_matV.adjoint()).determinant(); // so x has absolute value 1
	Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> sv(m_sigma);
	sv.coeffRef(0) *= x;
	if(scaling) scaling->lazyAssign(m_matV * sv.asDiagonal() * m_matV.adjoint());
	if(rotation)
	{
	MatrixType m(m_matU);
	m.col(0) /= x;
	rotation->lazyAssign(m * m_matV.adjoint());
	}
	}

	/** decomposes the matrix as a product scaling x rotation, the scaling being
	* not necessarily positive.
	*
	* If either pointer is zero, the corresponding computation is skipped.
	*
	* This method requires the Geometry module.
	*
	* \sa computeRotationScaling(), computeUnitaryPositive()
	*/
	template<typename MatrixType>
	template<typename ScalingType, typename RotationType>
	void SVD<MatrixType>::computeScalingRotation(ScalingType scaling, RotationType rotation) const
	{
	ei_assert(m_matU.rows() == m_matV.rows() && "Polar decomposition is only for square matrices");
	Scalar x = (m_matU * m_matV.adjoint()).determinant(); // so x has absolute value 1
	Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> sv(m_sigma);
	sv.coeffRef(0) *= x;
	if(scaling) scaling->lazyAssign(m_matU * sv.asDiagonal() * m_matU.adjoint());
	if(rotation)
	{
	MatrixType m(m_matU);
	m.col(0) /= x;
	rotation->lazyAssign(m * m_matV.adjoint());
	}
	}


	/** \svd_module
	* \returns the SVD decomposition of \c *this
	*/
	template<typename Derived>
	inline SVD<typename MatrixBase<Derived>::PlainObject>
	MatrixBase<Derived>::svd() const
	{
	return SVD<PlainObject>(derived());
	}

	} // end namespace Eigen

	#endif // EIGEN2_SVD_H