Eigen/src/SparseCore/SparseSelfAdjointView.h - fp2-dev/platform/external/eigen - Gitiles

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2009 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_SPARSE_SELFADJOINTVIEW_H
 #define EIGEN_SPARSE_SELFADJOINTVIEW_H

 namespace Eigen {

 /** \ingroup SparseCore_Module
   * \class SparseSelfAdjointView
   *
   * \brief Pseudo expression to manipulate a triangular sparse matrix as a selfadjoint matrix.
   *
   * \param MatrixType the type of the dense matrix storing the coefficients
   * \param UpLo can be either \c #Lower or \c #Upper
   *
   * This class is an expression of a sefladjoint matrix from a triangular part of a matrix
   * with given dense storage of the coefficients. It is the return type of MatrixBase::selfadjointView()
   * and most of the time this is the only way that it is used.
   *
   * \sa SparseMatrixBase::selfadjointView()
   */
 template<typename Lhs, typename Rhs, int UpLo>
 class SparseSelfAdjointTimeDenseProduct;

 template<typename Lhs, typename Rhs, int UpLo>
 class DenseTimeSparseSelfAdjointProduct;

 namespace internal {

 template<typename MatrixType, unsigned int UpLo>
 struct traits<SparseSelfAdjointView<MatrixType,UpLo> > : traits<MatrixType> {
 };

 template<int SrcUpLo,int DstUpLo,typename MatrixType,int DestOrder>
 void permute_symm_to_symm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DestOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm = 0);

 template<int UpLo,typename MatrixType,int DestOrder>
 void permute_symm_to_fullsymm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DestOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm = 0);

 }

 template<typename MatrixType, unsigned int UpLo> class SparseSelfAdjointView
   : public EigenBase<SparseSelfAdjointView<MatrixType,UpLo> >
 {
   public:

     typedef typename MatrixType::Scalar Scalar;
     typedef typename MatrixType::Index Index;
     typedef Matrix<Index,Dynamic,1> VectorI;
     typedef typename MatrixType::Nested MatrixTypeNested;
     typedef typename internal::remove_all<MatrixTypeNested>::type _MatrixTypeNested;

     inline SparseSelfAdjointView(const MatrixType& matrix) : m_matrix(matrix)
     {
       eigen_assert(rows()==cols() && "SelfAdjointView is only for squared matrices");
     }

     inline Index rows() const { return m_matrix.rows(); }
     inline Index cols() const { return m_matrix.cols(); }

     /** \internal \returns a reference to the nested matrix */
     const _MatrixTypeNested& matrix() const { return m_matrix; }
     _MatrixTypeNested& matrix() { return m_matrix.const_cast_derived(); }

     /** \returns an expression of the matrix product between a sparse self-adjoint matrix \c *this and a sparse matrix \a rhs.
       *
       * Note that there is no algorithmic advantage of performing such a product compared to a general sparse-sparse matrix product.
       * Indeed, the SparseSelfadjointView operand is first copied into a temporary SparseMatrix before computing the product.
       */
     template<typename OtherDerived>
     SparseSparseProduct<typename OtherDerived::PlainObject, OtherDerived>
     operator*(const SparseMatrixBase<OtherDerived>& rhs) const
     {
       return SparseSparseProduct<typename OtherDerived::PlainObject, OtherDerived>(*this, rhs.derived());
     }

     /** \returns an expression of the matrix product between a sparse matrix \a lhs and a sparse self-adjoint matrix \a rhs.
       *
       * Note that there is no algorithmic advantage of performing such a product compared to a general sparse-sparse matrix product.
       * Indeed, the SparseSelfadjointView operand is first copied into a temporary SparseMatrix before computing the product.
       */
     template<typename OtherDerived> friend
     SparseSparseProduct<OtherDerived, typename OtherDerived::PlainObject >
     operator*(const SparseMatrixBase<OtherDerived>& lhs, const SparseSelfAdjointView& rhs)
     {
       return SparseSparseProduct<OtherDerived, typename OtherDerived::PlainObject>(lhs.derived(), rhs);
     }

     /** Efficient sparse self-adjoint matrix times dense vector/matrix product */
     template<typename OtherDerived>
     SparseSelfAdjointTimeDenseProduct<MatrixType,OtherDerived,UpLo>
     operator*(const MatrixBase<OtherDerived>& rhs) const
     {
       return SparseSelfAdjointTimeDenseProduct<MatrixType,OtherDerived,UpLo>(m_matrix, rhs.derived());
     }

     /** Efficient dense vector/matrix times sparse self-adjoint matrix product */
     template<typename OtherDerived> friend
     DenseTimeSparseSelfAdjointProduct<OtherDerived,MatrixType,UpLo>
     operator*(const MatrixBase<OtherDerived>& lhs, const SparseSelfAdjointView& rhs)
     {
       return DenseTimeSparseSelfAdjointProduct<OtherDerived,_MatrixTypeNested,UpLo>(lhs.derived(), rhs.m_matrix);
     }

     /** Perform a symmetric rank K update of the selfadjoint matrix \c *this:
       * \f$ this = this + \alpha ( u u^* ) \f$ where \a u is a vector or matrix.
       *
       * \returns a reference to \c *this
       *
       * To perform \f$ this = this + \alpha ( u^* u ) \f$ you can simply
       * call this function with u.adjoint().
       */
     template<typename DerivedU>
     SparseSelfAdjointView& rankUpdate(const SparseMatrixBase<DerivedU>& u, const Scalar& alpha = Scalar(1));

     /** \internal triggered by sparse_matrix = SparseSelfadjointView; */
     template<typename DestScalar,int StorageOrder> void evalTo(SparseMatrix<DestScalar,StorageOrder,Index>& _dest) const
     {
       internal::permute_symm_to_fullsymm<UpLo>(m_matrix, _dest);
     }

     template<typename DestScalar> void evalTo(DynamicSparseMatrix<DestScalar,ColMajor,Index>& _dest) const
     {
       // TODO directly evaluate into _dest;
       SparseMatrix<DestScalar,ColMajor,Index> tmp(_dest.rows(),_dest.cols());
       internal::permute_symm_to_fullsymm<UpLo>(m_matrix, tmp);
       _dest = tmp;
     }

     /** \returns an expression of P H P^-1 */
     SparseSymmetricPermutationProduct<_MatrixTypeNested,UpLo> twistedBy(const PermutationMatrix<Dynamic,Dynamic,Index>& perm) const
     {
       return SparseSymmetricPermutationProduct<_MatrixTypeNested,UpLo>(m_matrix, perm);
     }

     template<typename SrcMatrixType,int SrcUpLo>
     SparseSelfAdjointView& operator=(const SparseSymmetricPermutationProduct<SrcMatrixType,SrcUpLo>& permutedMatrix)
     {
       permutedMatrix.evalTo(*this);
       return *this;
     }


     SparseSelfAdjointView& operator=(const SparseSelfAdjointView& src)
     {
       PermutationMatrix<Dynamic> pnull;
       return *this = src.twistedBy(pnull);
     }

     template<typename SrcMatrixType,unsigned int SrcUpLo>
     SparseSelfAdjointView& operator=(const SparseSelfAdjointView<SrcMatrixType,SrcUpLo>& src)
     {
       PermutationMatrix<Dynamic> pnull;
       return *this = src.twistedBy(pnull);
     }


     // const SparseLLT<PlainObject, UpLo> llt() const;
     // const SparseLDLT<PlainObject, UpLo> ldlt() const;

   protected:

     typename MatrixType::Nested m_matrix;
     mutable VectorI m_countPerRow;
     mutable VectorI m_countPerCol;
 };

 /***************************************************************************
 * Implementation of SparseMatrixBase methods
 ***************************************************************************/

 template<typename Derived>
 template<unsigned int UpLo>
 const SparseSelfAdjointView<Derived, UpLo> SparseMatrixBase<Derived>::selfadjointView() const
 {
   return derived();
 }

 template<typename Derived>
 template<unsigned int UpLo>
 SparseSelfAdjointView<Derived, UpLo> SparseMatrixBase<Derived>::selfadjointView()
 {
   return derived();
 }

 /***************************************************************************
 * Implementation of SparseSelfAdjointView methods
 ***************************************************************************/

 template<typename MatrixType, unsigned int UpLo>
 template<typename DerivedU>
 SparseSelfAdjointView<MatrixType,UpLo>&
 SparseSelfAdjointView<MatrixType,UpLo>::rankUpdate(const SparseMatrixBase<DerivedU>& u, const Scalar& alpha)
 {
   SparseMatrix<Scalar,MatrixType::Flags&RowMajorBit?RowMajor:ColMajor> tmp = u * u.adjoint();
   if(alpha==Scalar(0))
     m_matrix.const_cast_derived() = tmp.template triangularView<UpLo>();
   else
     m_matrix.const_cast_derived() += alpha * tmp.template triangularView<UpLo>();

   return *this;
 }

 /***************************************************************************
 * Implementation of sparse self-adjoint time dense matrix
 ***************************************************************************/

 namespace internal {
 template<typename Lhs, typename Rhs, int UpLo>
 struct traits<SparseSelfAdjointTimeDenseProduct<Lhs,Rhs,UpLo> >
  : traits<ProductBase<SparseSelfAdjointTimeDenseProduct<Lhs,Rhs,UpLo>, Lhs, Rhs> >
 {
   typedef Dense StorageKind;
 };
 }

 template<typename Lhs, typename Rhs, int UpLo>
 class SparseSelfAdjointTimeDenseProduct
   : public ProductBase<SparseSelfAdjointTimeDenseProduct<Lhs,Rhs,UpLo>, Lhs, Rhs>
 {
   public:
     EIGEN_PRODUCT_PUBLIC_INTERFACE(SparseSelfAdjointTimeDenseProduct)

     SparseSelfAdjointTimeDenseProduct(const Lhs& lhs, const Rhs& rhs) : Base(lhs,rhs)
     {}

     template<typename Dest> void scaleAndAddTo(Dest& dest, const Scalar& alpha) const
     {
       EIGEN_ONLY_USED_FOR_DEBUG(alpha);
       // TODO use alpha
       eigen_assert(alpha==Scalar(1) && "alpha != 1 is not implemented yet, sorry");
       typedef typename internal::remove_all<Lhs>::type _Lhs;
       typedef typename _Lhs::InnerIterator LhsInnerIterator;
       enum {
         LhsIsRowMajor = (_Lhs::Flags&RowMajorBit)==RowMajorBit,
         ProcessFirstHalf =
                  ((UpLo&(Upper|Lower))==(Upper|Lower))
               || ( (UpLo&Upper) && !LhsIsRowMajor)
               || ( (UpLo&Lower) && LhsIsRowMajor),
         ProcessSecondHalf = !ProcessFirstHalf
       };
       for (Index j=0; j<m_lhs.outerSize(); ++j)
       {
         LhsInnerIterator i(m_lhs,j);
         if (ProcessSecondHalf)
         {
           while (i && i.index()<j) ++i;
           if(i && i.index()==j)
           {
             dest.row(j) += i.value() * m_rhs.row(j);
             ++i;
           }
         }
         for(; (ProcessFirstHalf ? i && i.index() < j : i) ; ++i)
         {
           Index a = LhsIsRowMajor ? j : i.index();
           Index b = LhsIsRowMajor ? i.index() : j;
           typename Lhs::Scalar v = i.value();
           dest.row(a) += (v) * m_rhs.row(b);
           dest.row(b) += numext::conj(v) * m_rhs.row(a);
         }
         if (ProcessFirstHalf && i && (i.index()==j))
           dest.row(j) += i.value() * m_rhs.row(j);
       }
     }

   private:
     SparseSelfAdjointTimeDenseProduct& operator=(const SparseSelfAdjointTimeDenseProduct&);
 };

 namespace internal {
 template<typename Lhs, typename Rhs, int UpLo>
 struct traits<DenseTimeSparseSelfAdjointProduct<Lhs,Rhs,UpLo> >
  : traits<ProductBase<DenseTimeSparseSelfAdjointProduct<Lhs,Rhs,UpLo>, Lhs, Rhs> >
 {};
 }

 template<typename Lhs, typename Rhs, int UpLo>
 class DenseTimeSparseSelfAdjointProduct
   : public ProductBase<DenseTimeSparseSelfAdjointProduct<Lhs,Rhs,UpLo>, Lhs, Rhs>
 {
   public:
     EIGEN_PRODUCT_PUBLIC_INTERFACE(DenseTimeSparseSelfAdjointProduct)

     DenseTimeSparseSelfAdjointProduct(const Lhs& lhs, const Rhs& rhs) : Base(lhs,rhs)
     {}

     template<typename Dest> void scaleAndAddTo(Dest& /*dest*/, const Scalar& /*alpha*/) const
     {
       // TODO
     }

   private:
     DenseTimeSparseSelfAdjointProduct& operator=(const DenseTimeSparseSelfAdjointProduct&);
 };

 /***************************************************************************
 * Implementation of symmetric copies and permutations
 ***************************************************************************/
 namespace internal {

 template<typename MatrixType, int UpLo>
 struct traits<SparseSymmetricPermutationProduct<MatrixType,UpLo> > : traits<MatrixType> {
 };

 template<int UpLo,typename MatrixType,int DestOrder>
 void permute_symm_to_fullsymm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DestOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm)
 {
   typedef typename MatrixType::Index Index;
   typedef typename MatrixType::Scalar Scalar;
   typedef SparseMatrix<Scalar,DestOrder,Index> Dest;
   typedef Matrix<Index,Dynamic,1> VectorI;

   Dest& dest(_dest.derived());
   enum {
     StorageOrderMatch = int(Dest::IsRowMajor) == int(MatrixType::IsRowMajor)
   };

   Index size = mat.rows();
   VectorI count;
   count.resize(size);
   count.setZero();
   dest.resize(size,size);
   for(Index j = 0; j<size; ++j)
   {
     Index jp = perm ? perm[j] : j;
     for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
     {
       Index i = it.index();
       Index r = it.row();
       Index c = it.col();
       Index ip = perm ? perm[i] : i;
       if(UpLo==(Upper|Lower))
         count[StorageOrderMatch ? jp : ip]++;
       else if(r==c)
         count[ip]++;
       else if(( UpLo==Lower && r>c) || ( UpLo==Upper && r<c))
       {
         count[ip]++;
         count[jp]++;
       }
     }
   }
   Index nnz = count.sum();

   // reserve space
   dest.resizeNonZeros(nnz);
   dest.outerIndexPtr()[0] = 0;
   for(Index j=0; j<size; ++j)
     dest.outerIndexPtr()[j+1] = dest.outerIndexPtr()[j] + count[j];
   for(Index j=0; j<size; ++j)
     count[j] = dest.outerIndexPtr()[j];

   // copy data
   for(Index j = 0; j<size; ++j)
   {
     for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
     {
       Index i = it.index();
       Index r = it.row();
       Index c = it.col();

       Index jp = perm ? perm[j] : j;
       Index ip = perm ? perm[i] : i;

       if(UpLo==(Upper|Lower))
       {
         Index k = count[StorageOrderMatch ? jp : ip]++;
         dest.innerIndexPtr()[k] = StorageOrderMatch ? ip : jp;
         dest.valuePtr()[k] = it.value();
       }
       else if(r==c)
       {
         Index k = count[ip]++;
         dest.innerIndexPtr()[k] = ip;
         dest.valuePtr()[k] = it.value();
       }
       else if(( (UpLo&Lower)==Lower && r>c) || ( (UpLo&Upper)==Upper && r<c))
       {
         if(!StorageOrderMatch)
           std::swap(ip,jp);
         Index k = count[jp]++;
         dest.innerIndexPtr()[k] = ip;
         dest.valuePtr()[k] = it.value();
         k = count[ip]++;
         dest.innerIndexPtr()[k] = jp;
         dest.valuePtr()[k] = numext::conj(it.value());
       }
     }
   }
 }

 template<int _SrcUpLo,int _DstUpLo,typename MatrixType,int DstOrder>
 void permute_symm_to_symm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DstOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm)
 {
   typedef typename MatrixType::Index Index;
   typedef typename MatrixType::Scalar Scalar;
   SparseMatrix<Scalar,DstOrder,Index>& dest(_dest.derived());
   typedef Matrix<Index,Dynamic,1> VectorI;
   enum {
     SrcOrder = MatrixType::IsRowMajor ? RowMajor : ColMajor,
     StorageOrderMatch = int(SrcOrder) == int(DstOrder),
     DstUpLo = DstOrder==RowMajor ? (_DstUpLo==Upper ? Lower : Upper) : _DstUpLo,
     SrcUpLo = SrcOrder==RowMajor ? (_SrcUpLo==Upper ? Lower : Upper) : _SrcUpLo
   };

   Index size = mat.rows();
   VectorI count(size);
   count.setZero();
   dest.resize(size,size);
   for(Index j = 0; j<size; ++j)
   {
     Index jp = perm ? perm[j] : j;
     for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
     {
       Index i = it.index();
       if((int(SrcUpLo)==int(Lower) && i<j) || (int(SrcUpLo)==int(Upper) && i>j))
         continue;

       Index ip = perm ? perm[i] : i;
       count[int(DstUpLo)==int(Lower) ? (std::min)(ip,jp) : (std::max)(ip,jp)]++;
     }
   }
   dest.outerIndexPtr()[0] = 0;
   for(Index j=0; j<size; ++j)
     dest.outerIndexPtr()[j+1] = dest.outerIndexPtr()[j] + count[j];
   dest.resizeNonZeros(dest.outerIndexPtr()[size]);
   for(Index j=0; j<size; ++j)
     count[j] = dest.outerIndexPtr()[j];

   for(Index j = 0; j<size; ++j)
   {

     for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
     {
       Index i = it.index();
       if((int(SrcUpLo)==int(Lower) && i<j) || (int(SrcUpLo)==int(Upper) && i>j))
         continue;

       Index jp = perm ? perm[j] : j;
       Index ip = perm? perm[i] : i;

       Index k = count[int(DstUpLo)==int(Lower) ? (std::min)(ip,jp) : (std::max)(ip,jp)]++;
       dest.innerIndexPtr()[k] = int(DstUpLo)==int(Lower) ? (std::max)(ip,jp) : (std::min)(ip,jp);

       if(!StorageOrderMatch) std::swap(ip,jp);
       if( ((int(DstUpLo)==int(Lower) && ip<jp) || (int(DstUpLo)==int(Upper) && ip>jp)))
         dest.valuePtr()[k] = numext::conj(it.value());
       else
         dest.valuePtr()[k] = it.value();
     }
   }
 }

 }

 template<typename MatrixType,int UpLo>
 class SparseSymmetricPermutationProduct
   : public EigenBase<SparseSymmetricPermutationProduct<MatrixType,UpLo> >
 {
   public:
     typedef typename MatrixType::Scalar Scalar;
     typedef typename MatrixType::Index Index;
   protected:
     typedef PermutationMatrix<Dynamic,Dynamic,Index> Perm;
   public:
     typedef Matrix<Index,Dynamic,1> VectorI;
     typedef typename MatrixType::Nested MatrixTypeNested;
     typedef typename internal::remove_all<MatrixTypeNested>::type _MatrixTypeNested;

     SparseSymmetricPermutationProduct(const MatrixType& mat, const Perm& perm)
       : m_matrix(mat), m_perm(perm)
     {}

     inline Index rows() const { return m_matrix.rows(); }
     inline Index cols() const { return m_matrix.cols(); }

     template<typename DestScalar, int Options, typename DstIndex>
     void evalTo(SparseMatrix<DestScalar,Options,DstIndex>& _dest) const
     {
 //       internal::permute_symm_to_fullsymm<UpLo>(m_matrix,_dest,m_perm.indices().data());
       SparseMatrix<DestScalar,(Options&RowMajor)==RowMajor ? ColMajor : RowMajor, DstIndex> tmp;
       internal::permute_symm_to_fullsymm<UpLo>(m_matrix,tmp,m_perm.indices().data());
       _dest = tmp;
     }

     template<typename DestType,unsigned int DestUpLo> void evalTo(SparseSelfAdjointView<DestType,DestUpLo>& dest) const
     {
       internal::permute_symm_to_symm<UpLo,DestUpLo>(m_matrix,dest.matrix(),m_perm.indices().data());
     }

   protected:
     MatrixTypeNested m_matrix;
     const Perm& m_perm;

 };

 } // end namespace Eigen

 #endif // EIGEN_SPARSE_SELFADJOINTVIEW_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2009 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_SPARSE_SELFADJOINTVIEW_H
	#define EIGEN_SPARSE_SELFADJOINTVIEW_H

	namespace Eigen {

	/** \ingroup SparseCore_Module
	* \class SparseSelfAdjointView
	*
	* \brief Pseudo expression to manipulate a triangular sparse matrix as a selfadjoint matrix.
	*
	* \param MatrixType the type of the dense matrix storing the coefficients
	* \param UpLo can be either \c #Lower or \c #Upper
	*
	* This class is an expression of a sefladjoint matrix from a triangular part of a matrix
	* with given dense storage of the coefficients. It is the return type of MatrixBase::selfadjointView()
	* and most of the time this is the only way that it is used.
	*
	* \sa SparseMatrixBase::selfadjointView()
	*/
	template<typename Lhs, typename Rhs, int UpLo>
	class SparseSelfAdjointTimeDenseProduct;

	template<typename Lhs, typename Rhs, int UpLo>
	class DenseTimeSparseSelfAdjointProduct;

	namespace internal {

	template<typename MatrixType, unsigned int UpLo>
	struct traits<SparseSelfAdjointView<MatrixType,UpLo> > : traits<MatrixType> {
	};

	template<int SrcUpLo,int DstUpLo,typename MatrixType,int DestOrder>
	void permute_symm_to_symm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DestOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm = 0);

	template<int UpLo,typename MatrixType,int DestOrder>
	void permute_symm_to_fullsymm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DestOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm = 0);

	}

	template<typename MatrixType, unsigned int UpLo> class SparseSelfAdjointView
	: public EigenBase<SparseSelfAdjointView<MatrixType,UpLo> >
	{
	public:

	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::Index Index;
	typedef Matrix<Index,Dynamic,1> VectorI;
	typedef typename MatrixType::Nested MatrixTypeNested;
	typedef typename internal::remove_all<MatrixTypeNested>::type _MatrixTypeNested;

	inline SparseSelfAdjointView(const MatrixType& matrix) : m_matrix(matrix)
	{
	eigen_assert(rows()==cols() && "SelfAdjointView is only for squared matrices");
	}

	inline Index rows() const { return m_matrix.rows(); }
	inline Index cols() const { return m_matrix.cols(); }

	/** \internal \returns a reference to the nested matrix */
	const _MatrixTypeNested& matrix() const { return m_matrix; }
	_MatrixTypeNested& matrix() { return m_matrix.const_cast_derived(); }

	/** \returns an expression of the matrix product between a sparse self-adjoint matrix \c *this and a sparse matrix \a rhs.
	*
	* Note that there is no algorithmic advantage of performing such a product compared to a general sparse-sparse matrix product.
	* Indeed, the SparseSelfadjointView operand is first copied into a temporary SparseMatrix before computing the product.
	*/
	template<typename OtherDerived>
	SparseSparseProduct<typename OtherDerived::PlainObject, OtherDerived>
	operator*(const SparseMatrixBase<OtherDerived>& rhs) const
	{
	return SparseSparseProduct<typename OtherDerived::PlainObject, OtherDerived>(*this, rhs.derived());
	}

	/** \returns an expression of the matrix product between a sparse matrix \a lhs and a sparse self-adjoint matrix \a rhs.
	*
	* Note that there is no algorithmic advantage of performing such a product compared to a general sparse-sparse matrix product.
	* Indeed, the SparseSelfadjointView operand is first copied into a temporary SparseMatrix before computing the product.
	*/
	template<typename OtherDerived> friend
	SparseSparseProduct<OtherDerived, typename OtherDerived::PlainObject >
	operator*(const SparseMatrixBase<OtherDerived>& lhs, const SparseSelfAdjointView& rhs)
	{
	return SparseSparseProduct<OtherDerived, typename OtherDerived::PlainObject>(lhs.derived(), rhs);
	}

	/** Efficient sparse self-adjoint matrix times dense vector/matrix product */
	template<typename OtherDerived>
	SparseSelfAdjointTimeDenseProduct<MatrixType,OtherDerived,UpLo>
	operator*(const MatrixBase<OtherDerived>& rhs) const
	{
	return SparseSelfAdjointTimeDenseProduct<MatrixType,OtherDerived,UpLo>(m_matrix, rhs.derived());
	}

	/** Efficient dense vector/matrix times sparse self-adjoint matrix product */
	template<typename OtherDerived> friend
	DenseTimeSparseSelfAdjointProduct<OtherDerived,MatrixType,UpLo>
	operator*(const MatrixBase<OtherDerived>& lhs, const SparseSelfAdjointView& rhs)
	{
	return DenseTimeSparseSelfAdjointProduct<OtherDerived,_MatrixTypeNested,UpLo>(lhs.derived(), rhs.m_matrix);
	}

	/** Perform a symmetric rank K update of the selfadjoint matrix \c *this:
	* \f$ this = this + \alpha ( u u^* ) \f$ where \a u is a vector or matrix.
	*
	* \returns a reference to \c *this
	*
	* To perform \f$ this = this + \alpha ( u^* u ) \f$ you can simply
	* call this function with u.adjoint().
	*/
	template<typename DerivedU>
	SparseSelfAdjointView& rankUpdate(const SparseMatrixBase<DerivedU>& u, const Scalar& alpha = Scalar(1));

	/** \internal triggered by sparse_matrix = SparseSelfadjointView; */
	template<typename DestScalar,int StorageOrder> void evalTo(SparseMatrix<DestScalar,StorageOrder,Index>& _dest) const
	{
	internal::permute_symm_to_fullsymm<UpLo>(m_matrix, _dest);
	}

	template<typename DestScalar> void evalTo(DynamicSparseMatrix<DestScalar,ColMajor,Index>& _dest) const
	{
	// TODO directly evaluate into _dest;
	SparseMatrix<DestScalar,ColMajor,Index> tmp(_dest.rows(),_dest.cols());
	internal::permute_symm_to_fullsymm<UpLo>(m_matrix, tmp);
	_dest = tmp;
	}

	/** \returns an expression of P H P^-1 */
	SparseSymmetricPermutationProduct<_MatrixTypeNested,UpLo> twistedBy(const PermutationMatrix<Dynamic,Dynamic,Index>& perm) const
	{
	return SparseSymmetricPermutationProduct<_MatrixTypeNested,UpLo>(m_matrix, perm);
	}

	template<typename SrcMatrixType,int SrcUpLo>
	SparseSelfAdjointView& operator=(const SparseSymmetricPermutationProduct<SrcMatrixType,SrcUpLo>& permutedMatrix)
	{
	permutedMatrix.evalTo(*this);
	return *this;
	}


	SparseSelfAdjointView& operator=(const SparseSelfAdjointView& src)
	{
	PermutationMatrix<Dynamic> pnull;
	return *this = src.twistedBy(pnull);
	}

	template<typename SrcMatrixType,unsigned int SrcUpLo>
	SparseSelfAdjointView& operator=(const SparseSelfAdjointView<SrcMatrixType,SrcUpLo>& src)
	{
	PermutationMatrix<Dynamic> pnull;
	return *this = src.twistedBy(pnull);
	}


	// const SparseLLT<PlainObject, UpLo> llt() const;
	// const SparseLDLT<PlainObject, UpLo> ldlt() const;

	protected:

	typename MatrixType::Nested m_matrix;
	mutable VectorI m_countPerRow;
	mutable VectorI m_countPerCol;
	};

	/***************************************************************************
	* Implementation of SparseMatrixBase methods
	***************************************************************************/

	template<typename Derived>
	template<unsigned int UpLo>
	const SparseSelfAdjointView<Derived, UpLo> SparseMatrixBase<Derived>::selfadjointView() const
	{
	return derived();
	}

	template<typename Derived>
	template<unsigned int UpLo>
	SparseSelfAdjointView<Derived, UpLo> SparseMatrixBase<Derived>::selfadjointView()
	{
	return derived();
	}

	/***************************************************************************
	* Implementation of SparseSelfAdjointView methods
	***************************************************************************/

	template<typename MatrixType, unsigned int UpLo>
	template<typename DerivedU>
	SparseSelfAdjointView<MatrixType,UpLo>&
	SparseSelfAdjointView<MatrixType,UpLo>::rankUpdate(const SparseMatrixBase<DerivedU>& u, const Scalar& alpha)
	{
	SparseMatrix<Scalar,MatrixType::Flags&RowMajorBit?RowMajor:ColMajor> tmp = u * u.adjoint();
	if(alpha==Scalar(0))
	m_matrix.const_cast_derived() = tmp.template triangularView<UpLo>();
	else
	m_matrix.const_cast_derived() += alpha * tmp.template triangularView<UpLo>();

	return *this;
	}

	/***************************************************************************
	* Implementation of sparse self-adjoint time dense matrix
	***************************************************************************/

	namespace internal {
	template<typename Lhs, typename Rhs, int UpLo>
	struct traits<SparseSelfAdjointTimeDenseProduct<Lhs,Rhs,UpLo> >
	: traits<ProductBase<SparseSelfAdjointTimeDenseProduct<Lhs,Rhs,UpLo>, Lhs, Rhs> >
	{
	typedef Dense StorageKind;
	};
	}

	template<typename Lhs, typename Rhs, int UpLo>
	class SparseSelfAdjointTimeDenseProduct
	: public ProductBase<SparseSelfAdjointTimeDenseProduct<Lhs,Rhs,UpLo>, Lhs, Rhs>
	{
	public:
	EIGEN_PRODUCT_PUBLIC_INTERFACE(SparseSelfAdjointTimeDenseProduct)

	SparseSelfAdjointTimeDenseProduct(const Lhs& lhs, const Rhs& rhs) : Base(lhs,rhs)
	{}

	template<typename Dest> void scaleAndAddTo(Dest& dest, const Scalar& alpha) const
	{
	EIGEN_ONLY_USED_FOR_DEBUG(alpha);
	// TODO use alpha
	eigen_assert(alpha==Scalar(1) && "alpha != 1 is not implemented yet, sorry");
	typedef typename internal::remove_all<Lhs>::type _Lhs;
	typedef typename _Lhs::InnerIterator LhsInnerIterator;
	enum {
	LhsIsRowMajor = (_Lhs::Flags&RowMajorBit)==RowMajorBit,
	ProcessFirstHalf =
	((UpLo&(Upper\|Lower))==(Upper\|Lower))
	\|\| ( (UpLo&Upper) && !LhsIsRowMajor)
	\|\| ( (UpLo&Lower) && LhsIsRowMajor),
	ProcessSecondHalf = !ProcessFirstHalf
	};
	for (Index j=0; j<m_lhs.outerSize(); ++j)
	{
	LhsInnerIterator i(m_lhs,j);
	if (ProcessSecondHalf)
	{
	while (i && i.index()<j) ++i;
	if(i && i.index()==j)
	{
	dest.row(j) += i.value() * m_rhs.row(j);
	++i;
	}
	}
	for(; (ProcessFirstHalf ? i && i.index() < j : i) ; ++i)
	{
	Index a = LhsIsRowMajor ? j : i.index();
	Index b = LhsIsRowMajor ? i.index() : j;
	typename Lhs::Scalar v = i.value();
	dest.row(a) += (v) * m_rhs.row(b);
	dest.row(b) += numext::conj(v) * m_rhs.row(a);
	}
	if (ProcessFirstHalf && i && (i.index()==j))
	dest.row(j) += i.value() * m_rhs.row(j);
	}
	}

	private:
	SparseSelfAdjointTimeDenseProduct& operator=(const SparseSelfAdjointTimeDenseProduct&);
	};

	namespace internal {
	template<typename Lhs, typename Rhs, int UpLo>
	struct traits<DenseTimeSparseSelfAdjointProduct<Lhs,Rhs,UpLo> >
	: traits<ProductBase<DenseTimeSparseSelfAdjointProduct<Lhs,Rhs,UpLo>, Lhs, Rhs> >
	{};
	}

	template<typename Lhs, typename Rhs, int UpLo>
	class DenseTimeSparseSelfAdjointProduct
	: public ProductBase<DenseTimeSparseSelfAdjointProduct<Lhs,Rhs,UpLo>, Lhs, Rhs>
	{
	public:
	EIGEN_PRODUCT_PUBLIC_INTERFACE(DenseTimeSparseSelfAdjointProduct)

	DenseTimeSparseSelfAdjointProduct(const Lhs& lhs, const Rhs& rhs) : Base(lhs,rhs)
	{}

	template<typename Dest> void scaleAndAddTo(Dest& /dest/, const Scalar& /alpha/) const
	{
	// TODO
	}

	private:
	DenseTimeSparseSelfAdjointProduct& operator=(const DenseTimeSparseSelfAdjointProduct&);
	};

	/***************************************************************************
	* Implementation of symmetric copies and permutations
	***************************************************************************/
	namespace internal {

	template<typename MatrixType, int UpLo>
	struct traits<SparseSymmetricPermutationProduct<MatrixType,UpLo> > : traits<MatrixType> {
	};

	template<int UpLo,typename MatrixType,int DestOrder>
	void permute_symm_to_fullsymm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DestOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm)
	{
	typedef typename MatrixType::Index Index;
	typedef typename MatrixType::Scalar Scalar;
	typedef SparseMatrix<Scalar,DestOrder,Index> Dest;
	typedef Matrix<Index,Dynamic,1> VectorI;

	Dest& dest(_dest.derived());
	enum {
	StorageOrderMatch = int(Dest::IsRowMajor) == int(MatrixType::IsRowMajor)
	};

	Index size = mat.rows();
	VectorI count;
	count.resize(size);
	count.setZero();
	dest.resize(size,size);
	for(Index j = 0; j<size; ++j)
	{
	Index jp = perm ? perm[j] : j;
	for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
	{
	Index i = it.index();
	Index r = it.row();
	Index c = it.col();
	Index ip = perm ? perm[i] : i;
	if(UpLo==(Upper\|Lower))
	count[StorageOrderMatch ? jp : ip]++;
	else if(r==c)
	count[ip]++;
	else if(( UpLo==Lower && r>c) \|\| ( UpLo==Upper && r<c))
	{
	count[ip]++;
	count[jp]++;
	}
	}
	}
	Index nnz = count.sum();

	// reserve space
	dest.resizeNonZeros(nnz);
	dest.outerIndexPtr()[0] = 0;
	for(Index j=0; j<size; ++j)
	dest.outerIndexPtr()[j+1] = dest.outerIndexPtr()[j] + count[j];
	for(Index j=0; j<size; ++j)
	count[j] = dest.outerIndexPtr()[j];

	// copy data
	for(Index j = 0; j<size; ++j)
	{
	for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
	{
	Index i = it.index();
	Index r = it.row();
	Index c = it.col();

	Index jp = perm ? perm[j] : j;
	Index ip = perm ? perm[i] : i;

	if(UpLo==(Upper\|Lower))
	{
	Index k = count[StorageOrderMatch ? jp : ip]++;
	dest.innerIndexPtr()[k] = StorageOrderMatch ? ip : jp;
	dest.valuePtr()[k] = it.value();
	}
	else if(r==c)
	{
	Index k = count[ip]++;
	dest.innerIndexPtr()[k] = ip;
	dest.valuePtr()[k] = it.value();
	}
	else if(( (UpLo&Lower)==Lower && r>c) \|\| ( (UpLo&Upper)==Upper && r<c))
	{
	if(!StorageOrderMatch)
	std::swap(ip,jp);
	Index k = count[jp]++;
	dest.innerIndexPtr()[k] = ip;
	dest.valuePtr()[k] = it.value();
	k = count[ip]++;
	dest.innerIndexPtr()[k] = jp;
	dest.valuePtr()[k] = numext::conj(it.value());
	}
	}
	}
	}

	template<int _SrcUpLo,int _DstUpLo,typename MatrixType,int DstOrder>
	void permute_symm_to_symm(const MatrixType& mat, SparseMatrix<typename MatrixType::Scalar,DstOrder,typename MatrixType::Index>& _dest, const typename MatrixType::Index* perm)
	{
	typedef typename MatrixType::Index Index;
	typedef typename MatrixType::Scalar Scalar;
	SparseMatrix<Scalar,DstOrder,Index>& dest(_dest.derived());
	typedef Matrix<Index,Dynamic,1> VectorI;
	enum {
	SrcOrder = MatrixType::IsRowMajor ? RowMajor : ColMajor,
	StorageOrderMatch = int(SrcOrder) == int(DstOrder),
	DstUpLo = DstOrder==RowMajor ? (_DstUpLo==Upper ? Lower : Upper) : _DstUpLo,
	SrcUpLo = SrcOrder==RowMajor ? (_SrcUpLo==Upper ? Lower : Upper) : _SrcUpLo
	};

	Index size = mat.rows();
	VectorI count(size);
	count.setZero();
	dest.resize(size,size);
	for(Index j = 0; j<size; ++j)
	{
	Index jp = perm ? perm[j] : j;
	for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
	{
	Index i = it.index();
	if((int(SrcUpLo)==int(Lower) && i<j) \|\| (int(SrcUpLo)==int(Upper) && i>j))
	continue;

	Index ip = perm ? perm[i] : i;
	count[int(DstUpLo)==int(Lower) ? (std::min)(ip,jp) : (std::max)(ip,jp)]++;
	}
	}
	dest.outerIndexPtr()[0] = 0;
	for(Index j=0; j<size; ++j)
	dest.outerIndexPtr()[j+1] = dest.outerIndexPtr()[j] + count[j];
	dest.resizeNonZeros(dest.outerIndexPtr()[size]);
	for(Index j=0; j<size; ++j)
	count[j] = dest.outerIndexPtr()[j];

	for(Index j = 0; j<size; ++j)
	{

	for(typename MatrixType::InnerIterator it(mat,j); it; ++it)
	{
	Index i = it.index();
	if((int(SrcUpLo)==int(Lower) && i<j) \|\| (int(SrcUpLo)==int(Upper) && i>j))
	continue;

	Index jp = perm ? perm[j] : j;
	Index ip = perm? perm[i] : i;

	Index k = count[int(DstUpLo)==int(Lower) ? (std::min)(ip,jp) : (std::max)(ip,jp)]++;
	dest.innerIndexPtr()[k] = int(DstUpLo)==int(Lower) ? (std::max)(ip,jp) : (std::min)(ip,jp);

	if(!StorageOrderMatch) std::swap(ip,jp);
	if( ((int(DstUpLo)==int(Lower) && ip<jp) \|\| (int(DstUpLo)==int(Upper) && ip>jp)))
	dest.valuePtr()[k] = numext::conj(it.value());
	else
	dest.valuePtr()[k] = it.value();
	}
	}
	}

	}

	template<typename MatrixType,int UpLo>
	class SparseSymmetricPermutationProduct
	: public EigenBase<SparseSymmetricPermutationProduct<MatrixType,UpLo> >
	{
	public:
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::Index Index;
	protected:
	typedef PermutationMatrix<Dynamic,Dynamic,Index> Perm;
	public:
	typedef Matrix<Index,Dynamic,1> VectorI;
	typedef typename MatrixType::Nested MatrixTypeNested;
	typedef typename internal::remove_all<MatrixTypeNested>::type _MatrixTypeNested;

	SparseSymmetricPermutationProduct(const MatrixType& mat, const Perm& perm)
	: m_matrix(mat), m_perm(perm)
	{}

	inline Index rows() const { return m_matrix.rows(); }
	inline Index cols() const { return m_matrix.cols(); }

	template<typename DestScalar, int Options, typename DstIndex>
	void evalTo(SparseMatrix<DestScalar,Options,DstIndex>& _dest) const
	{
	// internal::permute_symm_to_fullsymm<UpLo>(m_matrix,_dest,m_perm.indices().data());
	SparseMatrix<DestScalar,(Options&RowMajor)==RowMajor ? ColMajor : RowMajor, DstIndex> tmp;
	internal::permute_symm_to_fullsymm<UpLo>(m_matrix,tmp,m_perm.indices().data());
	_dest = tmp;
	}

	template<typename DestType,unsigned int DestUpLo> void evalTo(SparseSelfAdjointView<DestType,DestUpLo>& dest) const
	{
	internal::permute_symm_to_symm<UpLo,DestUpLo>(m_matrix,dest.matrix(),m_perm.indices().data());
	}

	protected:
	MatrixTypeNested m_matrix;
	const Perm& m_perm;

	};

	} // end namespace Eigen

	#endif // EIGEN_SPARSE_SELFADJOINTVIEW_H