unsupported/Eigen/src/IterativeSolvers/DGMRES.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.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_DGMRES_H
 #define EIGEN_DGMRES_H

 #include <Eigen/Eigenvalues>

 namespace Eigen {

 template< typename _MatrixType,
           typename _Preconditioner = DiagonalPreconditioner<typename _MatrixType::Scalar> >
 class DGMRES;

 namespace internal {

 template< typename _MatrixType, typename _Preconditioner>
 struct traits<DGMRES<_MatrixType,_Preconditioner> >
 {
   typedef _MatrixType MatrixType;
   typedef _Preconditioner Preconditioner;
 };

 /** \brief Computes a permutation vector to have a sorted sequence
   * \param vec The vector to reorder.
   * \param perm gives the sorted sequence on output. Must be initialized with 0..n-1
   * \param ncut Put  the ncut smallest elements at the end of the vector
   * WARNING This is an expensive sort, so should be used only
   * for small size vectors
   * TODO Use modified QuickSplit or std::nth_element to get the smallest values
   */
 template <typename VectorType, typename IndexType>
 void sortWithPermutation (VectorType& vec, IndexType& perm, typename IndexType::Scalar& ncut)
 {
   eigen_assert(vec.size() == perm.size());
   bool flag;
   for (Index k  = 0; k < ncut; k++)
   {
     flag = false;
     for (Index j = 0; j < vec.size()-1; j++)
     {
       if ( vec(perm(j)) < vec(perm(j+1)) )
       {
         std::swap(perm(j),perm(j+1));
         flag = true;
       }
       if (!flag) break; // The vector is in sorted order
     }
   }
 }

 }
 /**
  * \ingroup IterativeLInearSolvers_Module
  * \brief A Restarted GMRES with deflation.
  * This class implements a modification of the GMRES solver for
  * sparse linear systems. The basis is built with modified
  * Gram-Schmidt. At each restart, a few approximated eigenvectors
  * corresponding to the smallest eigenvalues are used to build a
  * preconditioner for the next cycle. This preconditioner
  * for deflation can be combined with any other preconditioner,
  * the IncompleteLUT for instance. The preconditioner is applied
  * at right of the matrix and the combination is multiplicative.
  *
  * \tparam _MatrixType the type of the sparse matrix A, can be a dense or a sparse matrix.
  * \tparam _Preconditioner the type of the preconditioner. Default is DiagonalPreconditioner
  * Typical usage :
  * \code
  * SparseMatrix<double> A;
  * VectorXd x, b;
  * //Fill A and b ...
  * DGMRES<SparseMatrix<double> > solver;
  * solver.set_restart(30); // Set restarting value
  * solver.setEigenv(1); // Set the number of eigenvalues to deflate
  * solver.compute(A);
  * x = solver.solve(b);
  * \endcode
  *
  * DGMRES can also be used in a matrix-free context, see the following \link MatrixfreeSolverExample example \endlink.
  *
  * References :
  * [1] D. NUENTSA WAKAM and F. PACULL, Memory Efficient Hybrid
  *  Algebraic Solvers for Linear Systems Arising from Compressible
  *  Flows, Computers and Fluids, In Press,
  *  http://dx.doi.org/10.1016/j.compfluid.2012.03.023
  * [2] K. Burrage and J. Erhel, On the performance of various
  * adaptive preconditioned GMRES strategies, 5(1998), 101-121.
  * [3] J. Erhel, K. Burrage and B. Pohl, Restarted GMRES
  *  preconditioned by deflation,J. Computational and Applied
  *  Mathematics, 69(1996), 303-318.

  *
  */
 template< typename _MatrixType, typename _Preconditioner>
 class DGMRES : public IterativeSolverBase<DGMRES<_MatrixType,_Preconditioner> >
 {
     typedef IterativeSolverBase<DGMRES> Base;
     using Base::matrix;
     using Base::m_error;
     using Base::m_iterations;
     using Base::m_info;
     using Base::m_isInitialized;
     using Base::m_tolerance;
   public:
     using Base::_solve_impl;
     typedef _MatrixType MatrixType;
     typedef typename MatrixType::Scalar Scalar;
     typedef typename MatrixType::StorageIndex StorageIndex;
     typedef typename MatrixType::RealScalar RealScalar;
     typedef _Preconditioner Preconditioner;
     typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
     typedef Matrix<RealScalar,Dynamic,Dynamic> DenseRealMatrix;
     typedef Matrix<Scalar,Dynamic,1> DenseVector;
     typedef Matrix<RealScalar,Dynamic,1> DenseRealVector;
     typedef Matrix<std::complex<RealScalar>, Dynamic, 1> ComplexVector;


   /** Default constructor. */
   DGMRES() : Base(),m_restart(30),m_neig(0),m_r(0),m_maxNeig(5),m_isDeflAllocated(false),m_isDeflInitialized(false) {}

   /** Initialize the solver with matrix \a A for further \c Ax=b solving.
     *
     * This constructor is a shortcut for the default constructor followed
     * by a call to compute().
     *
     * \warning this class stores a reference to the matrix A as well as some
     * precomputed values that depend on it. Therefore, if \a A is changed
     * this class becomes invalid. Call compute() to update it with the new
     * matrix A, or modify a copy of A.
     */
   template<typename MatrixDerived>
   explicit DGMRES(const EigenBase<MatrixDerived>& A) : Base(A.derived()), m_restart(30),m_neig(0),m_r(0),m_maxNeig(5),m_isDeflAllocated(false),m_isDeflInitialized(false) {}

   ~DGMRES() {}

   /** \internal */
   template<typename Rhs,typename Dest>
   void _solve_with_guess_impl(const Rhs& b, Dest& x) const
   {
     bool failed = false;
     for(Index j=0; j<b.cols(); ++j)
     {
       m_iterations = Base::maxIterations();
       m_error = Base::m_tolerance;

       typename Dest::ColXpr xj(x,j);
       dgmres(matrix(), b.col(j), xj, Base::m_preconditioner);
     }
     m_info = failed ? NumericalIssue
            : m_error <= Base::m_tolerance ? Success
            : NoConvergence;
     m_isInitialized = true;
   }

   /** \internal */
   template<typename Rhs,typename Dest>
   void _solve_impl(const Rhs& b, MatrixBase<Dest>& x) const
   {
     x = b;
     _solve_with_guess_impl(b,x.derived());
   }
   /**
    * Get the restart value
     */
   Index restart() { return m_restart; }

   /**
    * Set the restart value (default is 30)
    */
   void set_restart(const Index restart) { m_restart=restart; }

   /**
    * Set the number of eigenvalues to deflate at each restart
    */
   void setEigenv(const Index neig)
   {
     m_neig = neig;
     if (neig+1 > m_maxNeig) m_maxNeig = neig+1; // To allow for complex conjugates
   }

   /**
    * Get the size of the deflation subspace size
    */
   Index deflSize() {return m_r; }

   /**
    * Set the maximum size of the deflation subspace
    */
   void setMaxEigenv(const Index maxNeig) { m_maxNeig = maxNeig; }

   protected:
     // DGMRES algorithm
     template<typename Rhs, typename Dest>
     void dgmres(const MatrixType& mat,const Rhs& rhs, Dest& x, const Preconditioner& precond) const;
     // Perform one cycle of GMRES
     template<typename Dest>
     Index dgmresCycle(const MatrixType& mat, const Preconditioner& precond, Dest& x, DenseVector& r0, RealScalar& beta, const RealScalar& normRhs, Index& nbIts) const;
     // Compute data to use for deflation
     Index dgmresComputeDeflationData(const MatrixType& mat, const Preconditioner& precond, const Index& it, StorageIndex& neig) const;
     // Apply deflation to a vector
     template<typename RhsType, typename DestType>
     Index dgmresApplyDeflation(const RhsType& In, DestType& Out) const;
     ComplexVector schurValues(const ComplexSchur<DenseMatrix>& schurofH) const;
     ComplexVector schurValues(const RealSchur<DenseMatrix>& schurofH) const;
     // Init data for deflation
     void dgmresInitDeflation(Index& rows) const;
     mutable DenseMatrix m_V; // Krylov basis vectors
     mutable DenseMatrix m_H; // Hessenberg matrix
     mutable DenseMatrix m_Hes; // Initial hessenberg matrix wihout Givens rotations applied
     mutable Index m_restart; // Maximum size of the Krylov subspace
     mutable DenseMatrix m_U; // Vectors that form the basis of the invariant subspace
     mutable DenseMatrix m_MU; // matrix operator applied to m_U (for next cycles)
     mutable DenseMatrix m_T; /* T=U^T*M^{-1}*A*U */
     mutable PartialPivLU<DenseMatrix> m_luT; // LU factorization of m_T
     mutable StorageIndex m_neig; //Number of eigenvalues to extract at each restart
     mutable Index m_r; // Current number of deflated eigenvalues, size of m_U
     mutable Index m_maxNeig; // Maximum number of eigenvalues to deflate
     mutable RealScalar m_lambdaN; //Modulus of the largest eigenvalue of A
     mutable bool m_isDeflAllocated;
     mutable bool m_isDeflInitialized;

     //Adaptive strategy
     mutable RealScalar m_smv; // Smaller multiple of the remaining number of steps allowed
     mutable bool m_force; // Force the use of deflation at each restart

 };
 /**
  * \brief Perform several cycles of restarted GMRES with modified Gram Schmidt,
  *
  * A right preconditioner is used combined with deflation.
  *
  */
 template< typename _MatrixType, typename _Preconditioner>
 template<typename Rhs, typename Dest>
 void DGMRES<_MatrixType, _Preconditioner>::dgmres(const MatrixType& mat,const Rhs& rhs, Dest& x,
               const Preconditioner& precond) const
 {
   //Initialization
   Index n = mat.rows();
   DenseVector r0(n);
   Index nbIts = 0;
   m_H.resize(m_restart+1, m_restart);
   m_Hes.resize(m_restart, m_restart);
   m_V.resize(n,m_restart+1);
   //Initial residual vector and intial norm
   x = precond.solve(x);
   r0 = rhs - mat * x;
   RealScalar beta = r0.norm();
   RealScalar normRhs = rhs.norm();
   m_error = beta/normRhs;
   if(m_error < m_tolerance)
     m_info = Success;
   else
     m_info = NoConvergence;

   // Iterative process
   while (nbIts < m_iterations && m_info == NoConvergence)
   {
     dgmresCycle(mat, precond, x, r0, beta, normRhs, nbIts);

     // Compute the new residual vector for the restart
     if (nbIts < m_iterations && m_info == NoConvergence)
       r0 = rhs - mat * x;
   }
 }

 /**
  * \brief Perform one restart cycle of DGMRES
  * \param mat The coefficient matrix
  * \param precond The preconditioner
  * \param x the new approximated solution
  * \param r0 The initial residual vector
  * \param beta The norm of the residual computed so far
  * \param normRhs The norm of the right hand side vector
  * \param nbIts The number of iterations
  */
 template< typename _MatrixType, typename _Preconditioner>
 template<typename Dest>
 Index DGMRES<_MatrixType, _Preconditioner>::dgmresCycle(const MatrixType& mat, const Preconditioner& precond, Dest& x, DenseVector& r0, RealScalar& beta, const RealScalar& normRhs, Index& nbIts) const
 {
   //Initialization
   DenseVector g(m_restart+1); // Right hand side of the least square problem
   g.setZero();
   g(0) = Scalar(beta);
   m_V.col(0) = r0/beta;
   m_info = NoConvergence;
   std::vector<JacobiRotation<Scalar> >gr(m_restart); // Givens rotations
   Index it = 0; // Number of inner iterations
   Index n = mat.rows();
   DenseVector tv1(n), tv2(n);  //Temporary vectors
   while (m_info == NoConvergence && it < m_restart && nbIts < m_iterations)
   {
     // Apply preconditioner(s) at right
     if (m_isDeflInitialized )
     {
       dgmresApplyDeflation(m_V.col(it), tv1); // Deflation
       tv2 = precond.solve(tv1);
     }
     else
     {
       tv2 = precond.solve(m_V.col(it)); // User's selected preconditioner
     }
     tv1 = mat * tv2;

     // Orthogonalize it with the previous basis in the basis using modified Gram-Schmidt
     Scalar coef;
     for (Index i = 0; i <= it; ++i)
     {
       coef = tv1.dot(m_V.col(i));
       tv1 = tv1 - coef * m_V.col(i);
       m_H(i,it) = coef;
       m_Hes(i,it) = coef;
     }
     // Normalize the vector
     coef = tv1.norm();
     m_V.col(it+1) = tv1/coef;
     m_H(it+1, it) = coef;
 //     m_Hes(it+1,it) = coef;

     // FIXME Check for happy breakdown

     // Update Hessenberg matrix with Givens rotations
     for (Index i = 1; i <= it; ++i)
     {
       m_H.col(it).applyOnTheLeft(i-1,i,gr[i-1].adjoint());
     }
     // Compute the new plane rotation
     gr[it].makeGivens(m_H(it, it), m_H(it+1,it));
     // Apply the new rotation
     m_H.col(it).applyOnTheLeft(it,it+1,gr[it].adjoint());
     g.applyOnTheLeft(it,it+1, gr[it].adjoint());

     beta = std::abs(g(it+1));
     m_error = beta/normRhs;
     // std::cerr << nbIts << " Relative Residual Norm " << m_error << std::endl;
     it++; nbIts++;

     if (m_error < m_tolerance)
     {
       // The method has converged
       m_info = Success;
       break;
     }
   }

   // Compute the new coefficients by solving the least square problem
 //   it++;
   //FIXME  Check first if the matrix is singular ... zero diagonal
   DenseVector nrs(m_restart);
   nrs = m_H.topLeftCorner(it,it).template triangularView<Upper>().solve(g.head(it));

   // Form the new solution
   if (m_isDeflInitialized)
   {
     tv1 = m_V.leftCols(it) * nrs;
     dgmresApplyDeflation(tv1, tv2);
     x = x + precond.solve(tv2);
   }
   else
     x = x + precond.solve(m_V.leftCols(it) * nrs);

   // Go for a new cycle and compute data for deflation
   if(nbIts < m_iterations && m_info == NoConvergence && m_neig > 0 && (m_r+m_neig) < m_maxNeig)
     dgmresComputeDeflationData(mat, precond, it, m_neig);
   return 0;

 }


 template< typename _MatrixType, typename _Preconditioner>
 void DGMRES<_MatrixType, _Preconditioner>::dgmresInitDeflation(Index& rows) const
 {
   m_U.resize(rows, m_maxNeig);
   m_MU.resize(rows, m_maxNeig);
   m_T.resize(m_maxNeig, m_maxNeig);
   m_lambdaN = 0.0;
   m_isDeflAllocated = true;
 }

 template< typename _MatrixType, typename _Preconditioner>
 inline typename DGMRES<_MatrixType, _Preconditioner>::ComplexVector DGMRES<_MatrixType, _Preconditioner>::schurValues(const ComplexSchur<DenseMatrix>& schurofH) const
 {
   return schurofH.matrixT().diagonal();
 }

 template< typename _MatrixType, typename _Preconditioner>
 inline typename DGMRES<_MatrixType, _Preconditioner>::ComplexVector DGMRES<_MatrixType, _Preconditioner>::schurValues(const RealSchur<DenseMatrix>& schurofH) const
 {
   const DenseMatrix& T = schurofH.matrixT();
   Index it = T.rows();
   ComplexVector eig(it);
   Index j = 0;
   while (j < it-1)
   {
     if (T(j+1,j) ==Scalar(0))
     {
       eig(j) = std::complex<RealScalar>(T(j,j),RealScalar(0));
       j++;
     }
     else
     {
       eig(j) = std::complex<RealScalar>(T(j,j),T(j+1,j));
       eig(j+1) = std::complex<RealScalar>(T(j,j+1),T(j+1,j+1));
       j++;
     }
   }
   if (j < it-1) eig(j) = std::complex<RealScalar>(T(j,j),RealScalar(0));
   return eig;
 }

 template< typename _MatrixType, typename _Preconditioner>
 Index DGMRES<_MatrixType, _Preconditioner>::dgmresComputeDeflationData(const MatrixType& mat, const Preconditioner& precond, const Index& it, StorageIndex& neig) const
 {
   // First, find the Schur form of the Hessenberg matrix H
   typename internal::conditional<NumTraits<Scalar>::IsComplex, ComplexSchur<DenseMatrix>, RealSchur<DenseMatrix> >::type schurofH;
   bool computeU = true;
   DenseMatrix matrixQ(it,it);
   matrixQ.setIdentity();
   schurofH.computeFromHessenberg(m_Hes.topLeftCorner(it,it), matrixQ, computeU);

   ComplexVector eig(it);
   Matrix<StorageIndex,Dynamic,1>perm(it);
   eig = this->schurValues(schurofH);

   // Reorder the absolute values of Schur values
   DenseRealVector modulEig(it);
   for (Index j=0; j<it; ++j) modulEig(j) = std::abs(eig(j));
   perm.setLinSpaced(it,0,internal::convert_index<StorageIndex>(it-1));
   internal::sortWithPermutation(modulEig, perm, neig);

   if (!m_lambdaN)
   {
     m_lambdaN = (std::max)(modulEig.maxCoeff(), m_lambdaN);
   }
   //Count the real number of extracted eigenvalues (with complex conjugates)
   Index nbrEig = 0;
   while (nbrEig < neig)
   {
     if(eig(perm(it-nbrEig-1)).imag() == RealScalar(0)) nbrEig++;
     else nbrEig += 2;
   }
   // Extract the  Schur vectors corresponding to the smallest Ritz values
   DenseMatrix Sr(it, nbrEig);
   Sr.setZero();
   for (Index j = 0; j < nbrEig; j++)
   {
     Sr.col(j) = schurofH.matrixU().col(perm(it-j-1));
   }

   // Form the Schur vectors of the initial matrix using the Krylov basis
   DenseMatrix X;
   X = m_V.leftCols(it) * Sr;
   if (m_r)
   {
    // Orthogonalize X against m_U using modified Gram-Schmidt
    for (Index j = 0; j < nbrEig; j++)
      for (Index k =0; k < m_r; k++)
       X.col(j) = X.col(j) - (m_U.col(k).dot(X.col(j)))*m_U.col(k);
   }

   // Compute m_MX = A * M^-1 * X
   Index m = m_V.rows();
   if (!m_isDeflAllocated)
     dgmresInitDeflation(m);
   DenseMatrix MX(m, nbrEig);
   DenseVector tv1(m);
   for (Index j = 0; j < nbrEig; j++)
   {
     tv1 = mat * X.col(j);
     MX.col(j) = precond.solve(tv1);
   }

   //Update m_T = [U'MU U'MX; X'MU X'MX]
   m_T.block(m_r, m_r, nbrEig, nbrEig) = X.transpose() * MX;
   if(m_r)
   {
     m_T.block(0, m_r, m_r, nbrEig) = m_U.leftCols(m_r).transpose() * MX;
     m_T.block(m_r, 0, nbrEig, m_r) = X.transpose() * m_MU.leftCols(m_r);
   }

   // Save X into m_U and m_MX in m_MU
   for (Index j = 0; j < nbrEig; j++) m_U.col(m_r+j) = X.col(j);
   for (Index j = 0; j < nbrEig; j++) m_MU.col(m_r+j) = MX.col(j);
   // Increase the size of the invariant subspace
   m_r += nbrEig;

   // Factorize m_T into m_luT
   m_luT.compute(m_T.topLeftCorner(m_r, m_r));

   //FIXME CHeck if the factorization was correctly done (nonsingular matrix)
   m_isDeflInitialized = true;
   return 0;
 }
 template<typename _MatrixType, typename _Preconditioner>
 template<typename RhsType, typename DestType>
 Index DGMRES<_MatrixType, _Preconditioner>::dgmresApplyDeflation(const RhsType &x, DestType &y) const
 {
   DenseVector x1 = m_U.leftCols(m_r).transpose() * x;
   y = x + m_U.leftCols(m_r) * ( m_lambdaN * m_luT.solve(x1) - x1);
   return 0;
 }

 } // end namespace Eigen
 #endif
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.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_DGMRES_H
	#define EIGEN_DGMRES_H

	#include <Eigen/Eigenvalues>

	namespace Eigen {

	template< typename _MatrixType,
	typename _Preconditioner = DiagonalPreconditioner<typename _MatrixType::Scalar> >
	class DGMRES;

	namespace internal {

	template< typename _MatrixType, typename _Preconditioner>
	struct traits<DGMRES<_MatrixType,_Preconditioner> >
	{
	typedef _MatrixType MatrixType;
	typedef _Preconditioner Preconditioner;
	};

	/** \brief Computes a permutation vector to have a sorted sequence
	* \param vec The vector to reorder.
	* \param perm gives the sorted sequence on output. Must be initialized with 0..n-1
	* \param ncut Put the ncut smallest elements at the end of the vector
	* WARNING This is an expensive sort, so should be used only
	* for small size vectors
	* TODO Use modified QuickSplit or std::nth_element to get the smallest values
	*/
	template <typename VectorType, typename IndexType>
	void sortWithPermutation (VectorType& vec, IndexType& perm, typename IndexType::Scalar& ncut)
	{
	eigen_assert(vec.size() == perm.size());
	bool flag;
	for (Index k = 0; k < ncut; k++)
	{
	flag = false;
	for (Index j = 0; j < vec.size()-1; j++)
	{
	if ( vec(perm(j)) < vec(perm(j+1)) )
	{
	std::swap(perm(j),perm(j+1));
	flag = true;
	}
	if (!flag) break; // The vector is in sorted order
	}
	}
	}

	}
	/**
	* \ingroup IterativeLInearSolvers_Module
	* \brief A Restarted GMRES with deflation.
	* This class implements a modification of the GMRES solver for
	* sparse linear systems. The basis is built with modified
	* Gram-Schmidt. At each restart, a few approximated eigenvectors
	* corresponding to the smallest eigenvalues are used to build a
	* preconditioner for the next cycle. This preconditioner
	* for deflation can be combined with any other preconditioner,
	* the IncompleteLUT for instance. The preconditioner is applied
	* at right of the matrix and the combination is multiplicative.
	*
	* \tparam _MatrixType the type of the sparse matrix A, can be a dense or a sparse matrix.
	* \tparam _Preconditioner the type of the preconditioner. Default is DiagonalPreconditioner
	* Typical usage :
	* \code
	* SparseMatrix<double> A;
	* VectorXd x, b;
	* //Fill A and b ...
	* DGMRES<SparseMatrix<double> > solver;
	* solver.set_restart(30); // Set restarting value
	* solver.setEigenv(1); // Set the number of eigenvalues to deflate
	* solver.compute(A);
	* x = solver.solve(b);
	* \endcode
	*
	* DGMRES can also be used in a matrix-free context, see the following \link MatrixfreeSolverExample example \endlink.
	*
	* References :
	* [1] D. NUENTSA WAKAM and F. PACULL, Memory Efficient Hybrid
	* Algebraic Solvers for Linear Systems Arising from Compressible
	* Flows, Computers and Fluids, In Press,
	* http://dx.doi.org/10.1016/j.compfluid.2012.03.023
	* [2] K. Burrage and J. Erhel, On the performance of various
	* adaptive preconditioned GMRES strategies, 5(1998), 101-121.
	* [3] J. Erhel, K. Burrage and B. Pohl, Restarted GMRES
	* preconditioned by deflation,J. Computational and Applied
	* Mathematics, 69(1996), 303-318.

	*
	*/
	template< typename _MatrixType, typename _Preconditioner>
	class DGMRES : public IterativeSolverBase<DGMRES<_MatrixType,_Preconditioner> >
	{
	typedef IterativeSolverBase<DGMRES> Base;
	using Base::matrix;
	using Base::m_error;
	using Base::m_iterations;
	using Base::m_info;
	using Base::m_isInitialized;
	using Base::m_tolerance;
	public:
	using Base::_solve_impl;
	typedef _MatrixType MatrixType;
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::StorageIndex StorageIndex;
	typedef typename MatrixType::RealScalar RealScalar;
	typedef _Preconditioner Preconditioner;
	typedef Matrix<Scalar,Dynamic,Dynamic> DenseMatrix;
	typedef Matrix<RealScalar,Dynamic,Dynamic> DenseRealMatrix;
	typedef Matrix<Scalar,Dynamic,1> DenseVector;
	typedef Matrix<RealScalar,Dynamic,1> DenseRealVector;
	typedef Matrix<std::complex<RealScalar>, Dynamic, 1> ComplexVector;


	/** Default constructor. */
	DGMRES() : Base(),m_restart(30),m_neig(0),m_r(0),m_maxNeig(5),m_isDeflAllocated(false),m_isDeflInitialized(false) {}

	/** Initialize the solver with matrix \a A for further \c Ax=b solving.
	*
	* This constructor is a shortcut for the default constructor followed
	* by a call to compute().
	*
	* \warning this class stores a reference to the matrix A as well as some
	* precomputed values that depend on it. Therefore, if \a A is changed
	* this class becomes invalid. Call compute() to update it with the new
	* matrix A, or modify a copy of A.
	*/
	template<typename MatrixDerived>
	explicit DGMRES(const EigenBase<MatrixDerived>& A) : Base(A.derived()), m_restart(30),m_neig(0),m_r(0),m_maxNeig(5),m_isDeflAllocated(false),m_isDeflInitialized(false) {}

	~DGMRES() {}

	/** \internal */
	template<typename Rhs,typename Dest>
	void _solve_with_guess_impl(const Rhs& b, Dest& x) const
	{
	bool failed = false;
	for(Index j=0; j<b.cols(); ++j)
	{
	m_iterations = Base::maxIterations();
	m_error = Base::m_tolerance;

	typename Dest::ColXpr xj(x,j);
	dgmres(matrix(), b.col(j), xj, Base::m_preconditioner);
	}
	m_info = failed ? NumericalIssue
	: m_error <= Base::m_tolerance ? Success
	: NoConvergence;
	m_isInitialized = true;
	}

	/** \internal */
	template<typename Rhs,typename Dest>
	void _solve_impl(const Rhs& b, MatrixBase<Dest>& x) const
	{
	x = b;
	_solve_with_guess_impl(b,x.derived());
	}
	/**
	* Get the restart value
	*/
	Index restart() { return m_restart; }

	/**
	* Set the restart value (default is 30)
	*/
	void set_restart(const Index restart) { m_restart=restart; }

	/**
	* Set the number of eigenvalues to deflate at each restart
	*/
	void setEigenv(const Index neig)
	{
	m_neig = neig;
	if (neig+1 > m_maxNeig) m_maxNeig = neig+1; // To allow for complex conjugates
	}

	/**
	* Get the size of the deflation subspace size
	*/
	Index deflSize() {return m_r; }

	/**
	* Set the maximum size of the deflation subspace
	*/
	void setMaxEigenv(const Index maxNeig) { m_maxNeig = maxNeig; }

	protected:
	// DGMRES algorithm
	template<typename Rhs, typename Dest>
	void dgmres(const MatrixType& mat,const Rhs& rhs, Dest& x, const Preconditioner& precond) const;
	// Perform one cycle of GMRES
	template<typename Dest>
	Index dgmresCycle(const MatrixType& mat, const Preconditioner& precond, Dest& x, DenseVector& r0, RealScalar& beta, const RealScalar& normRhs, Index& nbIts) const;
	// Compute data to use for deflation
	Index dgmresComputeDeflationData(const MatrixType& mat, const Preconditioner& precond, const Index& it, StorageIndex& neig) const;
	// Apply deflation to a vector
	template<typename RhsType, typename DestType>
	Index dgmresApplyDeflation(const RhsType& In, DestType& Out) const;
	ComplexVector schurValues(const ComplexSchur<DenseMatrix>& schurofH) const;
	ComplexVector schurValues(const RealSchur<DenseMatrix>& schurofH) const;
	// Init data for deflation
	void dgmresInitDeflation(Index& rows) const;
	mutable DenseMatrix m_V; // Krylov basis vectors
	mutable DenseMatrix m_H; // Hessenberg matrix
	mutable DenseMatrix m_Hes; // Initial hessenberg matrix wihout Givens rotations applied
	mutable Index m_restart; // Maximum size of the Krylov subspace
	mutable DenseMatrix m_U; // Vectors that form the basis of the invariant subspace
	mutable DenseMatrix m_MU; // matrix operator applied to m_U (for next cycles)
	mutable DenseMatrix m_T; /* T=U^TM^{-1}AU /
	mutable PartialPivLU<DenseMatrix> m_luT; // LU factorization of m_T
	mutable StorageIndex m_neig; //Number of eigenvalues to extract at each restart
	mutable Index m_r; // Current number of deflated eigenvalues, size of m_U
	mutable Index m_maxNeig; // Maximum number of eigenvalues to deflate
	mutable RealScalar m_lambdaN; //Modulus of the largest eigenvalue of A
	mutable bool m_isDeflAllocated;
	mutable bool m_isDeflInitialized;

	//Adaptive strategy
	mutable RealScalar m_smv; // Smaller multiple of the remaining number of steps allowed
	mutable bool m_force; // Force the use of deflation at each restart

	};
	/**
	* \brief Perform several cycles of restarted GMRES with modified Gram Schmidt,
	*
	* A right preconditioner is used combined with deflation.
	*
	*/
	template< typename _MatrixType, typename _Preconditioner>
	template<typename Rhs, typename Dest>
	void DGMRES<_MatrixType, _Preconditioner>::dgmres(const MatrixType& mat,const Rhs& rhs, Dest& x,
	const Preconditioner& precond) const
	{
	//Initialization
	Index n = mat.rows();
	DenseVector r0(n);
	Index nbIts = 0;
	m_H.resize(m_restart+1, m_restart);
	m_Hes.resize(m_restart, m_restart);
	m_V.resize(n,m_restart+1);
	//Initial residual vector and intial norm
	x = precond.solve(x);
	r0 = rhs - mat * x;
	RealScalar beta = r0.norm();
	RealScalar normRhs = rhs.norm();
	m_error = beta/normRhs;
	if(m_error < m_tolerance)
	m_info = Success;
	else
	m_info = NoConvergence;

	// Iterative process
	while (nbIts < m_iterations && m_info == NoConvergence)
	{
	dgmresCycle(mat, precond, x, r0, beta, normRhs, nbIts);

	// Compute the new residual vector for the restart
	if (nbIts < m_iterations && m_info == NoConvergence)
	r0 = rhs - mat * x;
	}
	}

	/**
	* \brief Perform one restart cycle of DGMRES
	* \param mat The coefficient matrix
	* \param precond The preconditioner
	* \param x the new approximated solution
	* \param r0 The initial residual vector
	* \param beta The norm of the residual computed so far
	* \param normRhs The norm of the right hand side vector
	* \param nbIts The number of iterations
	*/
	template< typename _MatrixType, typename _Preconditioner>
	template<typename Dest>
	Index DGMRES<_MatrixType, _Preconditioner>::dgmresCycle(const MatrixType& mat, const Preconditioner& precond, Dest& x, DenseVector& r0, RealScalar& beta, const RealScalar& normRhs, Index& nbIts) const
	{
	//Initialization
	DenseVector g(m_restart+1); // Right hand side of the least square problem
	g.setZero();
	g(0) = Scalar(beta);
	m_V.col(0) = r0/beta;
	m_info = NoConvergence;
	std::vector<JacobiRotation<Scalar> >gr(m_restart); // Givens rotations
	Index it = 0; // Number of inner iterations
	Index n = mat.rows();
	DenseVector tv1(n), tv2(n); //Temporary vectors
	while (m_info == NoConvergence && it < m_restart && nbIts < m_iterations)
	{
	// Apply preconditioner(s) at right
	if (m_isDeflInitialized )
	{
	dgmresApplyDeflation(m_V.col(it), tv1); // Deflation
	tv2 = precond.solve(tv1);
	}
	else
	{
	tv2 = precond.solve(m_V.col(it)); // User's selected preconditioner
	}
	tv1 = mat * tv2;

	// Orthogonalize it with the previous basis in the basis using modified Gram-Schmidt
	Scalar coef;
	for (Index i = 0; i <= it; ++i)
	{
	coef = tv1.dot(m_V.col(i));
	tv1 = tv1 - coef * m_V.col(i);
	m_H(i,it) = coef;
	m_Hes(i,it) = coef;
	}
	// Normalize the vector
	coef = tv1.norm();
	m_V.col(it+1) = tv1/coef;
	m_H(it+1, it) = coef;
	// m_Hes(it+1,it) = coef;

	// FIXME Check for happy breakdown

	// Update Hessenberg matrix with Givens rotations
	for (Index i = 1; i <= it; ++i)
	{
	m_H.col(it).applyOnTheLeft(i-1,i,gr[i-1].adjoint());
	}
	// Compute the new plane rotation
	gr[it].makeGivens(m_H(it, it), m_H(it+1,it));
	// Apply the new rotation
	m_H.col(it).applyOnTheLeft(it,it+1,gr[it].adjoint());
	g.applyOnTheLeft(it,it+1, gr[it].adjoint());

	beta = std::abs(g(it+1));
	m_error = beta/normRhs;
	// std::cerr << nbIts << " Relative Residual Norm " << m_error << std::endl;
	it++; nbIts++;

	if (m_error < m_tolerance)
	{
	// The method has converged
	m_info = Success;
	break;
	}
	}

	// Compute the new coefficients by solving the least square problem
	// it++;
	//FIXME Check first if the matrix is singular ... zero diagonal
	DenseVector nrs(m_restart);
	nrs = m_H.topLeftCorner(it,it).template triangularView<Upper>().solve(g.head(it));

	// Form the new solution
	if (m_isDeflInitialized)
	{
	tv1 = m_V.leftCols(it) * nrs;
	dgmresApplyDeflation(tv1, tv2);
	x = x + precond.solve(tv2);
	}
	else
	x = x + precond.solve(m_V.leftCols(it) * nrs);

	// Go for a new cycle and compute data for deflation
	if(nbIts < m_iterations && m_info == NoConvergence && m_neig > 0 && (m_r+m_neig) < m_maxNeig)
	dgmresComputeDeflationData(mat, precond, it, m_neig);
	return 0;

	}


	template< typename _MatrixType, typename _Preconditioner>
	void DGMRES<_MatrixType, _Preconditioner>::dgmresInitDeflation(Index& rows) const
	{
	m_U.resize(rows, m_maxNeig);
	m_MU.resize(rows, m_maxNeig);
	m_T.resize(m_maxNeig, m_maxNeig);
	m_lambdaN = 0.0;
	m_isDeflAllocated = true;
	}

	template< typename _MatrixType, typename _Preconditioner>
	inline typename DGMRES<_MatrixType, _Preconditioner>::ComplexVector DGMRES<_MatrixType, _Preconditioner>::schurValues(const ComplexSchur<DenseMatrix>& schurofH) const
	{
	return schurofH.matrixT().diagonal();
	}

	template< typename _MatrixType, typename _Preconditioner>
	inline typename DGMRES<_MatrixType, _Preconditioner>::ComplexVector DGMRES<_MatrixType, _Preconditioner>::schurValues(const RealSchur<DenseMatrix>& schurofH) const
	{
	const DenseMatrix& T = schurofH.matrixT();
	Index it = T.rows();
	ComplexVector eig(it);
	Index j = 0;
	while (j < it-1)
	{
	if (T(j+1,j) ==Scalar(0))
	{
	eig(j) = std::complex<RealScalar>(T(j,j),RealScalar(0));
	j++;
	}
	else
	{
	eig(j) = std::complex<RealScalar>(T(j,j),T(j+1,j));
	eig(j+1) = std::complex<RealScalar>(T(j,j+1),T(j+1,j+1));
	j++;
	}
	}
	if (j < it-1) eig(j) = std::complex<RealScalar>(T(j,j),RealScalar(0));
	return eig;
	}

	template< typename _MatrixType, typename _Preconditioner>
	Index DGMRES<_MatrixType, _Preconditioner>::dgmresComputeDeflationData(const MatrixType& mat, const Preconditioner& precond, const Index& it, StorageIndex& neig) const
	{
	// First, find the Schur form of the Hessenberg matrix H
	typename internal::conditional<NumTraits<Scalar>::IsComplex, ComplexSchur<DenseMatrix>, RealSchur<DenseMatrix> >::type schurofH;
	bool computeU = true;
	DenseMatrix matrixQ(it,it);
	matrixQ.setIdentity();
	schurofH.computeFromHessenberg(m_Hes.topLeftCorner(it,it), matrixQ, computeU);

	ComplexVector eig(it);
	Matrix<StorageIndex,Dynamic,1>perm(it);
	eig = this->schurValues(schurofH);

	// Reorder the absolute values of Schur values
	DenseRealVector modulEig(it);
	for (Index j=0; j<it; ++j) modulEig(j) = std::abs(eig(j));
	perm.setLinSpaced(it,0,internal::convert_index<StorageIndex>(it-1));
	internal::sortWithPermutation(modulEig, perm, neig);

	if (!m_lambdaN)
	{
	m_lambdaN = (std::max)(modulEig.maxCoeff(), m_lambdaN);
	}
	//Count the real number of extracted eigenvalues (with complex conjugates)
	Index nbrEig = 0;
	while (nbrEig < neig)
	{
	if(eig(perm(it-nbrEig-1)).imag() == RealScalar(0)) nbrEig++;
	else nbrEig += 2;
	}
	// Extract the Schur vectors corresponding to the smallest Ritz values
	DenseMatrix Sr(it, nbrEig);
	Sr.setZero();
	for (Index j = 0; j < nbrEig; j++)
	{
	Sr.col(j) = schurofH.matrixU().col(perm(it-j-1));
	}

	// Form the Schur vectors of the initial matrix using the Krylov basis
	DenseMatrix X;
	X = m_V.leftCols(it) * Sr;
	if (m_r)
	{
	// Orthogonalize X against m_U using modified Gram-Schmidt
	for (Index j = 0; j < nbrEig; j++)
	for (Index k =0; k < m_r; k++)
	X.col(j) = X.col(j) - (m_U.col(k).dot(X.col(j)))*m_U.col(k);
	}

	// Compute m_MX = A * M^-1 * X
	Index m = m_V.rows();
	if (!m_isDeflAllocated)
	dgmresInitDeflation(m);
	DenseMatrix MX(m, nbrEig);
	DenseVector tv1(m);
	for (Index j = 0; j < nbrEig; j++)
	{
	tv1 = mat * X.col(j);
	MX.col(j) = precond.solve(tv1);
	}

	//Update m_T = [U'MU U'MX; X'MU X'MX]
	m_T.block(m_r, m_r, nbrEig, nbrEig) = X.transpose() * MX;
	if(m_r)
	{
	m_T.block(0, m_r, m_r, nbrEig) = m_U.leftCols(m_r).transpose() * MX;
	m_T.block(m_r, 0, nbrEig, m_r) = X.transpose() * m_MU.leftCols(m_r);
	}

	// Save X into m_U and m_MX in m_MU
	for (Index j = 0; j < nbrEig; j++) m_U.col(m_r+j) = X.col(j);
	for (Index j = 0; j < nbrEig; j++) m_MU.col(m_r+j) = MX.col(j);
	// Increase the size of the invariant subspace
	m_r += nbrEig;

	// Factorize m_T into m_luT
	m_luT.compute(m_T.topLeftCorner(m_r, m_r));

	//FIXME CHeck if the factorization was correctly done (nonsingular matrix)
	m_isDeflInitialized = true;
	return 0;
	}
	template<typename _MatrixType, typename _Preconditioner>
	template<typename RhsType, typename DestType>
	Index DGMRES<_MatrixType, _Preconditioner>::dgmresApplyDeflation(const RhsType &x, DestType &y) const
	{
	DenseVector x1 = m_U.leftCols(m_r).transpose() * x;
	y = x + m_U.leftCols(m_r) * ( m_lambdaN * m_luT.solve(x1) - x1);
	return 0;
	}

	} // end namespace Eigen
	#endif