Eigen/src/IterativeLinearSolvers/IncompleteLUT.h - mirror - 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>
 // Copyright (C) 2014 Gael Guennebaud <gael.guennebaud@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_INCOMPLETE_LUT_H
 #define EIGEN_INCOMPLETE_LUT_H


 namespace Eigen {

 namespace internal {

 /** \internal
   * Compute a quick-sort split of a vector
   * On output, the vector row is permuted such that its elements satisfy
   * abs(row(i)) >= abs(row(ncut)) if i<ncut
   * abs(row(i)) <= abs(row(ncut)) if i>ncut
   * \param row The vector of values
   * \param ind The array of index for the elements in @p row
   * \param ncut  The number of largest elements to keep
   **/
 template <typename VectorV, typename VectorI>
 Index QuickSplit(VectorV &row, VectorI &ind, Index ncut)
 {
   typedef typename VectorV::RealScalar RealScalar;
   using std::swap;
   using std::abs;
   Index mid;
   Index n = row.size(); /* length of the vector */
   Index first, last ;

   ncut--; /* to fit the zero-based indices */
   first = 0;
   last = n-1;
   if (ncut < first || ncut > last ) return 0;

   do {
     mid = first;
     RealScalar abskey = abs(row(mid));
     for (Index j = first + 1; j <= last; j++) {
       if ( abs(row(j)) > abskey) {
         ++mid;
         swap(row(mid), row(j));
         swap(ind(mid), ind(j));
       }
     }
     /* Interchange for the pivot element */
     swap(row(mid), row(first));
     swap(ind(mid), ind(first));

     if (mid > ncut) last = mid - 1;
     else if (mid < ncut ) first = mid + 1;
   } while (mid != ncut );

   return 0; /* mid is equal to ncut */
 }

 }// end namespace internal

 /** \ingroup IterativeLinearSolvers_Module
   * \class IncompleteLUT
   * \brief Incomplete LU factorization with dual-threshold strategy
   *
   * \implsparsesolverconcept
   *
   * During the numerical factorization, two dropping rules are used :
   *  1) any element whose magnitude is less than some tolerance is dropped.
   *    This tolerance is obtained by multiplying the input tolerance @p droptol
   *    by the average magnitude of all the original elements in the current row.
   *  2) After the elimination of the row, only the @p fill largest elements in
   *    the L part and the @p fill largest elements in the U part are kept
   *    (in addition to the diagonal element ). Note that @p fill is computed from
   *    the input parameter @p fillfactor which is used the ratio to control the fill_in
   *    relatively to the initial number of nonzero elements.
   *
   * The two extreme cases are when @p droptol=0 (to keep all the @p fill*2 largest elements)
   * and when @p fill=n/2 with @p droptol being different to zero.
   *
   * References : Yousef Saad, ILUT: A dual threshold incomplete LU factorization,
   *              Numerical Linear Algebra with Applications, 1(4), pp 387-402, 1994.
   *
   * NOTE : The following implementation is derived from the ILUT implementation
   * in the SPARSKIT package, Copyright (C) 2005, the Regents of the University of Minnesota
   *  released under the terms of the GNU LGPL:
   *    http://www-users.cs.umn.edu/~saad/software/SPARSKIT/README
   * However, Yousef Saad gave us permission to relicense his ILUT code to MPL2.
   * See the Eigen mailing list archive, thread: ILUT, date: July 8, 2012:
   *   http://listengine.tuxfamily.org/lists.tuxfamily.org/eigen/2012/07/msg00064.html
   * alternatively, on GMANE:
   *   http://comments.gmane.org/gmane.comp.lib.eigen/3302
   */
 template <typename _Scalar, typename _StorageIndex = int>
 class IncompleteLUT : public SparseSolverBase<IncompleteLUT<_Scalar, _StorageIndex> >
 {
   protected:
     typedef SparseSolverBase<IncompleteLUT> Base;
     using Base::m_isInitialized;
   public:
     typedef _Scalar Scalar;
     typedef _StorageIndex StorageIndex;
     typedef typename NumTraits<Scalar>::Real RealScalar;
     typedef Matrix<Scalar,Dynamic,1> Vector;
     typedef Matrix<StorageIndex,Dynamic,1> VectorI;
     typedef SparseMatrix<Scalar,RowMajor,StorageIndex> FactorType;

     enum {
       ColsAtCompileTime = Dynamic,
       MaxColsAtCompileTime = Dynamic
     };

   public:

     IncompleteLUT()
       : m_droptol(NumTraits<Scalar>::dummy_precision()), m_fillfactor(10),
         m_analysisIsOk(false), m_factorizationIsOk(false)
     {}

     template<typename MatrixType>
     explicit IncompleteLUT(const MatrixType& mat, const RealScalar& droptol=NumTraits<Scalar>::dummy_precision(), int fillfactor = 10)
       : m_droptol(droptol),m_fillfactor(fillfactor),
         m_analysisIsOk(false),m_factorizationIsOk(false)
     {
       eigen_assert(fillfactor != 0);
       compute(mat);
     }

     Index rows() const { return m_lu.rows(); }

     Index cols() const { return m_lu.cols(); }

     /** \brief Reports whether previous computation was successful.
       *
       * \returns \c Success if computation was successful,
       *          \c NumericalIssue if the matrix.appears to be negative.
       */
     ComputationInfo info() const
     {
       eigen_assert(m_isInitialized && "IncompleteLUT is not initialized.");
       return m_info;
     }

     template<typename MatrixType>
     void analyzePattern(const MatrixType& amat);

     template<typename MatrixType>
     void factorize(const MatrixType& amat);

     /**
       * Compute an incomplete LU factorization with dual threshold on the matrix mat
       * No pivoting is done in this version
       *
       **/
     template<typename MatrixType>
     IncompleteLUT& compute(const MatrixType& amat)
     {
       analyzePattern(amat);
       factorize(amat);
       return *this;
     }

     void setDroptol(const RealScalar& droptol);
     void setFillfactor(int fillfactor);

     template<typename Rhs, typename Dest>
     void _solve_impl(const Rhs& b, Dest& x) const
     {
       x = m_Pinv * b;
       x = m_lu.template triangularView<UnitLower>().solve(x);
       x = m_lu.template triangularView<Upper>().solve(x);
       x = m_P * x;
     }

 protected:

     /** keeps off-diagonal entries; drops diagonal entries */
     struct keep_diag {
       inline bool operator() (const Index& row, const Index& col, const Scalar&) const
       {
         return row!=col;
       }
     };

 protected:

     FactorType m_lu;
     RealScalar m_droptol;
     int m_fillfactor;
     bool m_analysisIsOk;
     bool m_factorizationIsOk;
     ComputationInfo m_info;
     PermutationMatrix<Dynamic,Dynamic,StorageIndex> m_P;     // Fill-reducing permutation
     PermutationMatrix<Dynamic,Dynamic,StorageIndex> m_Pinv;  // Inverse permutation
 };

 /**
  * Set control parameter droptol
  *  \param droptol   Drop any element whose magnitude is less than this tolerance
  **/
 template<typename Scalar, typename StorageIndex>
 void IncompleteLUT<Scalar,StorageIndex>::setDroptol(const RealScalar& droptol)
 {
   this->m_droptol = droptol;
 }

 /**
  * Set control parameter fillfactor
  * \param fillfactor  This is used to compute the  number @p fill_in of largest elements to keep on each row.
  **/
 template<typename Scalar, typename StorageIndex>
 void IncompleteLUT<Scalar,StorageIndex>::setFillfactor(int fillfactor)
 {
   this->m_fillfactor = fillfactor;
 }

 template <typename Scalar, typename StorageIndex>
 template<typename _MatrixType>
 void IncompleteLUT<Scalar,StorageIndex>::analyzePattern(const _MatrixType& amat)
 {
   // Compute the Fill-reducing permutation
   // Since ILUT does not perform any numerical pivoting,
   // it is highly preferable to keep the diagonal through symmetric permutations.
   // To this end, let's symmetrize the pattern and perform AMD on it.
   SparseMatrix<Scalar,ColMajor, StorageIndex> mat1 = amat;
   SparseMatrix<Scalar,ColMajor, StorageIndex> mat2 = amat.transpose();
   // FIXME for a matrix with nearly symmetric pattern, mat2+mat1 is the appropriate choice.
   //       on the other hand for a really non-symmetric pattern, mat2*mat1 should be preferred...
   SparseMatrix<Scalar,ColMajor, StorageIndex> AtA = mat2 + mat1;
   AMDOrdering<StorageIndex> ordering;
   ordering(AtA,m_P);
   m_Pinv  = m_P.inverse(); // cache the inverse permutation
   m_analysisIsOk = true;
   m_factorizationIsOk = false;
   m_isInitialized = true;
 }

 template <typename Scalar, typename StorageIndex>
 template<typename _MatrixType>
 void IncompleteLUT<Scalar,StorageIndex>::factorize(const _MatrixType& amat)
 {
   using std::sqrt;
   using std::swap;
   using std::abs;
   using internal::convert_index;

   eigen_assert((amat.rows() == amat.cols()) && "The factorization should be done on a square matrix");
   Index n = amat.cols();  // Size of the matrix
   m_lu.resize(n,n);
   // Declare Working vectors and variables
   Vector u(n) ;     // real values of the row -- maximum size is n --
   VectorI ju(n);   // column position of the values in u -- maximum size  is n
   VectorI jr(n);   // Indicate the position of the nonzero elements in the vector u -- A zero location is indicated by -1

   // Apply the fill-reducing permutation
   eigen_assert(m_analysisIsOk && "You must first call analyzePattern()");
   SparseMatrix<Scalar,RowMajor, StorageIndex> mat;
   mat = amat.twistedBy(m_Pinv);

   // Initialization
   jr.fill(-1);
   ju.fill(0);
   u.fill(0);

   // number of largest elements to keep in each row:
   Index fill_in = (amat.nonZeros()*m_fillfactor)/n + 1;
   if (fill_in > n) fill_in = n;

   // number of largest nonzero elements to keep in the L and the U part of the current row:
   Index nnzL = fill_in/2;
   Index nnzU = nnzL;
   m_lu.reserve(n * (nnzL + nnzU + 1));

   // global loop over the rows of the sparse matrix
   for (Index ii = 0; ii < n; ii++)
   {
     // 1 - copy the lower and the upper part of the row i of mat in the working vector u

     Index sizeu = 1; // number of nonzero elements in the upper part of the current row
     Index sizel = 0; // number of nonzero elements in the lower part of the current row
     ju(ii)    = convert_index<StorageIndex>(ii);
     u(ii)     = 0;
     jr(ii)    = convert_index<StorageIndex>(ii);
     RealScalar rownorm = 0;

     typename FactorType::InnerIterator j_it(mat, ii); // Iterate through the current row ii
     for (; j_it; ++j_it)
     {
       Index k = j_it.index();
       if (k < ii)
       {
         // copy the lower part
         ju(sizel) = convert_index<StorageIndex>(k);
         u(sizel) = j_it.value();
         jr(k) = convert_index<StorageIndex>(sizel);
         ++sizel;
       }
       else if (k == ii)
       {
         u(ii) = j_it.value();
       }
       else
       {
         // copy the upper part
         Index jpos = ii + sizeu;
         ju(jpos) = convert_index<StorageIndex>(k);
         u(jpos) = j_it.value();
         jr(k) = convert_index<StorageIndex>(jpos);
         ++sizeu;
       }
       rownorm += numext::abs2(j_it.value());
     }

     // 2 - detect possible zero row
     if(rownorm==0)
     {
       m_info = NumericalIssue;
       return;
     }
     // Take the 2-norm of the current row as a relative tolerance
     rownorm = sqrt(rownorm);

     // 3 - eliminate the previous nonzero rows
     Index jj = 0;
     Index len = 0;
     while (jj < sizel)
     {
       // In order to eliminate in the correct order,
       // we must select first the smallest column index among  ju(jj:sizel)
       Index k;
       Index minrow = ju.segment(jj,sizel-jj).minCoeff(&k); // k is relative to the segment
       k += jj;
       if (minrow != ju(jj))
       {
         // swap the two locations
         Index j = ju(jj);
         swap(ju(jj), ju(k));
         jr(minrow) = convert_index<StorageIndex>(jj);
         jr(j) = convert_index<StorageIndex>(k);
         swap(u(jj), u(k));
       }
       // Reset this location
       jr(minrow) = -1;

       // Start elimination
       typename FactorType::InnerIterator ki_it(m_lu, minrow);
       while (ki_it && ki_it.index() < minrow) ++ki_it;
       eigen_internal_assert(ki_it && ki_it.col()==minrow);
       Scalar fact = u(jj) / ki_it.value();

       // drop too small elements
       if(abs(fact) <= m_droptol)
       {
         jj++;
         continue;
       }

       // linear combination of the current row ii and the row minrow
       ++ki_it;
       for (; ki_it; ++ki_it)
       {
         Scalar prod = fact * ki_it.value();
         Index j     = ki_it.index();
         Index jpos  = jr(j);
         if (jpos == -1) // fill-in element
         {
           Index newpos;
           if (j >= ii) // dealing with the upper part
           {
             newpos = ii + sizeu;
             sizeu++;
             eigen_internal_assert(sizeu<=n);
           }
           else // dealing with the lower part
           {
             newpos = sizel;
             sizel++;
             eigen_internal_assert(sizel<=ii);
           }
           ju(newpos) = convert_index<StorageIndex>(j);
           u(newpos) = -prod;
           jr(j) = convert_index<StorageIndex>(newpos);
         }
         else
           u(jpos) -= prod;
       }
       // store the pivot element
       u(len)  = fact;
       ju(len) = convert_index<StorageIndex>(minrow);
       ++len;

       jj++;
     } // end of the elimination on the row ii

     // reset the upper part of the pointer jr to zero
     for(Index k = 0; k <sizeu; k++) jr(ju(ii+k)) = -1;

     // 4 - partially sort and insert the elements in the m_lu matrix

     // sort the L-part of the row
     sizel = len;
     len = (std::min)(sizel, nnzL);
     typename Vector::SegmentReturnType ul(u.segment(0, sizel));
     typename VectorI::SegmentReturnType jul(ju.segment(0, sizel));
     internal::QuickSplit(ul, jul, len);

     // store the largest m_fill elements of the L part
     m_lu.startVec(ii);
     for(Index k = 0; k < len; k++)
       m_lu.insertBackByOuterInnerUnordered(ii,ju(k)) = u(k);

     // store the diagonal element
     // apply a shifting rule to avoid zero pivots (we are doing an incomplete factorization)
     if (u(ii) == Scalar(0))
       u(ii) = sqrt(m_droptol) * rownorm;
     m_lu.insertBackByOuterInnerUnordered(ii, ii) = u(ii);

     // sort the U-part of the row
     // apply the dropping rule first
     len = 0;
     for(Index k = 1; k < sizeu; k++)
     {
       if(abs(u(ii+k)) > m_droptol * rownorm )
       {
         ++len;
         u(ii + len)  = u(ii + k);
         ju(ii + len) = ju(ii + k);
       }
     }
     sizeu = len + 1; // +1 to take into account the diagonal element
     len = (std::min)(sizeu, nnzU);
     typename Vector::SegmentReturnType uu(u.segment(ii+1, sizeu-1));
     typename VectorI::SegmentReturnType juu(ju.segment(ii+1, sizeu-1));
     internal::QuickSplit(uu, juu, len);

     // store the largest elements of the U part
     for(Index k = ii + 1; k < ii + len; k++)
       m_lu.insertBackByOuterInnerUnordered(ii,ju(k)) = u(k);
   }
   m_lu.finalize();
   m_lu.makeCompressed();

   m_factorizationIsOk = true;
   m_info = Success;
 }

 } // end namespace Eigen

 #endif // EIGEN_INCOMPLETE_LUT_H
	// 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>
	// Copyright (C) 2014 Gael Guennebaud <gael.guennebaud@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_INCOMPLETE_LUT_H
	#define EIGEN_INCOMPLETE_LUT_H


	namespace Eigen {

	namespace internal {

	/** \internal
	* Compute a quick-sort split of a vector
	* On output, the vector row is permuted such that its elements satisfy
	* abs(row(i)) >= abs(row(ncut)) if i<ncut
	* abs(row(i)) <= abs(row(ncut)) if i>ncut
	* \param row The vector of values
	* \param ind The array of index for the elements in @p row
	* \param ncut The number of largest elements to keep
	**/
	template <typename VectorV, typename VectorI>
	Index QuickSplit(VectorV &row, VectorI &ind, Index ncut)
	{
	typedef typename VectorV::RealScalar RealScalar;
	using std::swap;
	using std::abs;
	Index mid;
	Index n = row.size(); /* length of the vector */
	Index first, last ;

	ncut--; /* to fit the zero-based indices */
	first = 0;
	last = n-1;
	if (ncut < first \|\| ncut > last ) return 0;

	do {
	mid = first;
	RealScalar abskey = abs(row(mid));
	for (Index j = first + 1; j <= last; j++) {
	if ( abs(row(j)) > abskey) {
	++mid;
	swap(row(mid), row(j));
	swap(ind(mid), ind(j));
	}
	}
	/* Interchange for the pivot element */
	swap(row(mid), row(first));
	swap(ind(mid), ind(first));

	if (mid > ncut) last = mid - 1;
	else if (mid < ncut ) first = mid + 1;
	} while (mid != ncut );

	return 0; /* mid is equal to ncut */
	}

	}// end namespace internal

	/** \ingroup IterativeLinearSolvers_Module
	* \class IncompleteLUT
	* \brief Incomplete LU factorization with dual-threshold strategy
	*
	* \implsparsesolverconcept
	*
	* During the numerical factorization, two dropping rules are used :
	* 1) any element whose magnitude is less than some tolerance is dropped.
	* This tolerance is obtained by multiplying the input tolerance @p droptol
	* by the average magnitude of all the original elements in the current row.
	* 2) After the elimination of the row, only the @p fill largest elements in
	* the L part and the @p fill largest elements in the U part are kept
	* (in addition to the diagonal element ). Note that @p fill is computed from
	* the input parameter @p fillfactor which is used the ratio to control the fill_in
	* relatively to the initial number of nonzero elements.
	*
	* The two extreme cases are when @p droptol=0 (to keep all the @p fill*2 largest elements)
	* and when @p fill=n/2 with @p droptol being different to zero.
	*
	* References : Yousef Saad, ILUT: A dual threshold incomplete LU factorization,
	* Numerical Linear Algebra with Applications, 1(4), pp 387-402, 1994.
	*
	* NOTE : The following implementation is derived from the ILUT implementation
	* in the SPARSKIT package, Copyright (C) 2005, the Regents of the University of Minnesota
	* released under the terms of the GNU LGPL:
	* http://www-users.cs.umn.edu/~saad/software/SPARSKIT/README
	* However, Yousef Saad gave us permission to relicense his ILUT code to MPL2.
	* See the Eigen mailing list archive, thread: ILUT, date: July 8, 2012:
	* http://listengine.tuxfamily.org/lists.tuxfamily.org/eigen/2012/07/msg00064.html
	* alternatively, on GMANE:
	* http://comments.gmane.org/gmane.comp.lib.eigen/3302
	*/
	template <typename _Scalar, typename _StorageIndex = int>
	class IncompleteLUT : public SparseSolverBase<IncompleteLUT<_Scalar, _StorageIndex> >
	{
	protected:
	typedef SparseSolverBase<IncompleteLUT> Base;
	using Base::m_isInitialized;
	public:
	typedef _Scalar Scalar;
	typedef _StorageIndex StorageIndex;
	typedef typename NumTraits<Scalar>::Real RealScalar;
	typedef Matrix<Scalar,Dynamic,1> Vector;
	typedef Matrix<StorageIndex,Dynamic,1> VectorI;
	typedef SparseMatrix<Scalar,RowMajor,StorageIndex> FactorType;

	enum {
	ColsAtCompileTime = Dynamic,
	MaxColsAtCompileTime = Dynamic
	};

	public:

	IncompleteLUT()
	: m_droptol(NumTraits<Scalar>::dummy_precision()), m_fillfactor(10),
	m_analysisIsOk(false), m_factorizationIsOk(false)
	{}

	template<typename MatrixType>
	explicit IncompleteLUT(const MatrixType& mat, const RealScalar& droptol=NumTraits<Scalar>::dummy_precision(), int fillfactor = 10)
	: m_droptol(droptol),m_fillfactor(fillfactor),
	m_analysisIsOk(false),m_factorizationIsOk(false)
	{
	eigen_assert(fillfactor != 0);
	compute(mat);
	}

	Index rows() const { return m_lu.rows(); }

	Index cols() const { return m_lu.cols(); }

	/** \brief Reports whether previous computation was successful.
	*
	* \returns \c Success if computation was successful,
	* \c NumericalIssue if the matrix.appears to be negative.
	*/
	ComputationInfo info() const
	{
	eigen_assert(m_isInitialized && "IncompleteLUT is not initialized.");
	return m_info;
	}

	template<typename MatrixType>
	void analyzePattern(const MatrixType& amat);

	template<typename MatrixType>
	void factorize(const MatrixType& amat);

	/**
	* Compute an incomplete LU factorization with dual threshold on the matrix mat
	* No pivoting is done in this version
	*
	**/
	template<typename MatrixType>
	IncompleteLUT& compute(const MatrixType& amat)
	{
	analyzePattern(amat);
	factorize(amat);
	return *this;
	}

	void setDroptol(const RealScalar& droptol);
	void setFillfactor(int fillfactor);

	template<typename Rhs, typename Dest>
	void _solve_impl(const Rhs& b, Dest& x) const
	{
	x = m_Pinv * b;
	x = m_lu.template triangularView<UnitLower>().solve(x);
	x = m_lu.template triangularView<Upper>().solve(x);
	x = m_P * x;
	}

	protected:

	/** keeps off-diagonal entries; drops diagonal entries */
	struct keep_diag {
	inline bool operator() (const Index& row, const Index& col, const Scalar&) const
	{
	return row!=col;
	}
	};

	protected:

	FactorType m_lu;
	RealScalar m_droptol;
	int m_fillfactor;
	bool m_analysisIsOk;
	bool m_factorizationIsOk;
	ComputationInfo m_info;
	PermutationMatrix<Dynamic,Dynamic,StorageIndex> m_P; // Fill-reducing permutation
	PermutationMatrix<Dynamic,Dynamic,StorageIndex> m_Pinv; // Inverse permutation
	};

	/**
	* Set control parameter droptol
	* \param droptol Drop any element whose magnitude is less than this tolerance
	**/
	template<typename Scalar, typename StorageIndex>
	void IncompleteLUT<Scalar,StorageIndex>::setDroptol(const RealScalar& droptol)
	{
	this->m_droptol = droptol;
	}

	/**
	* Set control parameter fillfactor
	* \param fillfactor This is used to compute the number @p fill_in of largest elements to keep on each row.
	**/
	template<typename Scalar, typename StorageIndex>
	void IncompleteLUT<Scalar,StorageIndex>::setFillfactor(int fillfactor)
	{
	this->m_fillfactor = fillfactor;
	}

	template <typename Scalar, typename StorageIndex>
	template<typename _MatrixType>
	void IncompleteLUT<Scalar,StorageIndex>::analyzePattern(const _MatrixType& amat)
	{
	// Compute the Fill-reducing permutation
	// Since ILUT does not perform any numerical pivoting,
	// it is highly preferable to keep the diagonal through symmetric permutations.
	// To this end, let's symmetrize the pattern and perform AMD on it.
	SparseMatrix<Scalar,ColMajor, StorageIndex> mat1 = amat;
	SparseMatrix<Scalar,ColMajor, StorageIndex> mat2 = amat.transpose();
	// FIXME for a matrix with nearly symmetric pattern, mat2+mat1 is the appropriate choice.
	// on the other hand for a really non-symmetric pattern, mat2*mat1 should be preferred...
	SparseMatrix<Scalar,ColMajor, StorageIndex> AtA = mat2 + mat1;
	AMDOrdering<StorageIndex> ordering;
	ordering(AtA,m_P);
	m_Pinv = m_P.inverse(); // cache the inverse permutation
	m_analysisIsOk = true;
	m_factorizationIsOk = false;
	m_isInitialized = true;
	}

	template <typename Scalar, typename StorageIndex>
	template<typename _MatrixType>
	void IncompleteLUT<Scalar,StorageIndex>::factorize(const _MatrixType& amat)
	{
	using std::sqrt;
	using std::swap;
	using std::abs;
	using internal::convert_index;

	eigen_assert((amat.rows() == amat.cols()) && "The factorization should be done on a square matrix");
	Index n = amat.cols(); // Size of the matrix
	m_lu.resize(n,n);
	// Declare Working vectors and variables
	Vector u(n) ; // real values of the row -- maximum size is n --
	VectorI ju(n); // column position of the values in u -- maximum size is n
	VectorI jr(n); // Indicate the position of the nonzero elements in the vector u -- A zero location is indicated by -1

	// Apply the fill-reducing permutation
	eigen_assert(m_analysisIsOk && "You must first call analyzePattern()");
	SparseMatrix<Scalar,RowMajor, StorageIndex> mat;
	mat = amat.twistedBy(m_Pinv);

	// Initialization
	jr.fill(-1);
	ju.fill(0);
	u.fill(0);

	// number of largest elements to keep in each row:
	Index fill_in = (amat.nonZeros()*m_fillfactor)/n + 1;
	if (fill_in > n) fill_in = n;

	// number of largest nonzero elements to keep in the L and the U part of the current row:
	Index nnzL = fill_in/2;
	Index nnzU = nnzL;
	m_lu.reserve(n * (nnzL + nnzU + 1));

	// global loop over the rows of the sparse matrix
	for (Index ii = 0; ii < n; ii++)
	{
	// 1 - copy the lower and the upper part of the row i of mat in the working vector u

	Index sizeu = 1; // number of nonzero elements in the upper part of the current row
	Index sizel = 0; // number of nonzero elements in the lower part of the current row
	ju(ii) = convert_index<StorageIndex>(ii);
	u(ii) = 0;
	jr(ii) = convert_index<StorageIndex>(ii);
	RealScalar rownorm = 0;

	typename FactorType::InnerIterator j_it(mat, ii); // Iterate through the current row ii
	for (; j_it; ++j_it)
	{
	Index k = j_it.index();
	if (k < ii)
	{
	// copy the lower part
	ju(sizel) = convert_index<StorageIndex>(k);
	u(sizel) = j_it.value();
	jr(k) = convert_index<StorageIndex>(sizel);
	++sizel;
	}
	else if (k == ii)
	{
	u(ii) = j_it.value();
	}
	else
	{
	// copy the upper part
	Index jpos = ii + sizeu;
	ju(jpos) = convert_index<StorageIndex>(k);
	u(jpos) = j_it.value();
	jr(k) = convert_index<StorageIndex>(jpos);
	++sizeu;
	}
	rownorm += numext::abs2(j_it.value());
	}

	// 2 - detect possible zero row
	if(rownorm==0)
	{
	m_info = NumericalIssue;
	return;
	}
	// Take the 2-norm of the current row as a relative tolerance
	rownorm = sqrt(rownorm);

	// 3 - eliminate the previous nonzero rows
	Index jj = 0;
	Index len = 0;
	while (jj < sizel)
	{
	// In order to eliminate in the correct order,
	// we must select first the smallest column index among ju(jj:sizel)
	Index k;
	Index minrow = ju.segment(jj,sizel-jj).minCoeff(&k); // k is relative to the segment
	k += jj;
	if (minrow != ju(jj))
	{
	// swap the two locations
	Index j = ju(jj);
	swap(ju(jj), ju(k));
	jr(minrow) = convert_index<StorageIndex>(jj);
	jr(j) = convert_index<StorageIndex>(k);
	swap(u(jj), u(k));
	}
	// Reset this location
	jr(minrow) = -1;

	// Start elimination
	typename FactorType::InnerIterator ki_it(m_lu, minrow);
	while (ki_it && ki_it.index() < minrow) ++ki_it;
	eigen_internal_assert(ki_it && ki_it.col()==minrow);
	Scalar fact = u(jj) / ki_it.value();

	// drop too small elements
	if(abs(fact) <= m_droptol)
	{
	jj++;
	continue;
	}

	// linear combination of the current row ii and the row minrow
	++ki_it;
	for (; ki_it; ++ki_it)
	{
	Scalar prod = fact * ki_it.value();
	Index j = ki_it.index();
	Index jpos = jr(j);
	if (jpos == -1) // fill-in element
	{
	Index newpos;
	if (j >= ii) // dealing with the upper part
	{
	newpos = ii + sizeu;
	sizeu++;
	eigen_internal_assert(sizeu<=n);
	}
	else // dealing with the lower part
	{
	newpos = sizel;
	sizel++;
	eigen_internal_assert(sizel<=ii);
	}
	ju(newpos) = convert_index<StorageIndex>(j);
	u(newpos) = -prod;
	jr(j) = convert_index<StorageIndex>(newpos);
	}
	else
	u(jpos) -= prod;
	}
	// store the pivot element
	u(len) = fact;
	ju(len) = convert_index<StorageIndex>(minrow);
	++len;

	jj++;
	} // end of the elimination on the row ii

	// reset the upper part of the pointer jr to zero
	for(Index k = 0; k <sizeu; k++) jr(ju(ii+k)) = -1;

	// 4 - partially sort and insert the elements in the m_lu matrix

	// sort the L-part of the row
	sizel = len;
	len = (std::min)(sizel, nnzL);
	typename Vector::SegmentReturnType ul(u.segment(0, sizel));
	typename VectorI::SegmentReturnType jul(ju.segment(0, sizel));
	internal::QuickSplit(ul, jul, len);

	// store the largest m_fill elements of the L part
	m_lu.startVec(ii);
	for(Index k = 0; k < len; k++)
	m_lu.insertBackByOuterInnerUnordered(ii,ju(k)) = u(k);

	// store the diagonal element
	// apply a shifting rule to avoid zero pivots (we are doing an incomplete factorization)
	if (u(ii) == Scalar(0))
	u(ii) = sqrt(m_droptol) * rownorm;
	m_lu.insertBackByOuterInnerUnordered(ii, ii) = u(ii);

	// sort the U-part of the row
	// apply the dropping rule first
	len = 0;
	for(Index k = 1; k < sizeu; k++)
	{
	if(abs(u(ii+k)) > m_droptol * rownorm )
	{
	++len;
	u(ii + len) = u(ii + k);
	ju(ii + len) = ju(ii + k);
	}
	}
	sizeu = len + 1; // +1 to take into account the diagonal element
	len = (std::min)(sizeu, nnzU);
	typename Vector::SegmentReturnType uu(u.segment(ii+1, sizeu-1));
	typename VectorI::SegmentReturnType juu(ju.segment(ii+1, sizeu-1));
	internal::QuickSplit(uu, juu, len);

	// store the largest elements of the U part
	for(Index k = ii + 1; k < ii + len; k++)
	m_lu.insertBackByOuterInnerUnordered(ii,ju(k)) = u(k);
	}
	m_lu.finalize();
	m_lu.makeCompressed();

	m_factorizationIsOk = true;
	m_info = Success;
	}

	} // end namespace Eigen

	#endif // EIGEN_INCOMPLETE_LUT_H