Eigen/src/Core/Ref.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2012 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_REF_H
 #define EIGEN_REF_H

 namespace Eigen {

 namespace internal {

 template<typename _PlainObjectType, int _Options, typename _StrideType>
 struct traits<Ref<_PlainObjectType, _Options, _StrideType> >
   : public traits<Map<_PlainObjectType, _Options, _StrideType> >
 {
   typedef _PlainObjectType PlainObjectType;
   typedef _StrideType StrideType;
   enum {
     Options = _Options,
     Flags = traits<Map<_PlainObjectType, _Options, _StrideType> >::Flags | NestByRefBit,
     Alignment = traits<Map<_PlainObjectType, _Options, _StrideType> >::Alignment
   };

   template<typename Derived> struct match {
     enum {
       IsVectorAtCompileTime = PlainObjectType::IsVectorAtCompileTime || Derived::IsVectorAtCompileTime,
       HasDirectAccess = internal::has_direct_access<Derived>::ret,
       StorageOrderMatch = IsVectorAtCompileTime || ((PlainObjectType::Flags&RowMajorBit)==(Derived::Flags&RowMajorBit)),
       InnerStrideMatch = int(StrideType::InnerStrideAtCompileTime)==int(Dynamic)
                       || int(StrideType::InnerStrideAtCompileTime)==int(Derived::InnerStrideAtCompileTime)
                       || (int(StrideType::InnerStrideAtCompileTime)==0 && int(Derived::InnerStrideAtCompileTime)==1),
       OuterStrideMatch = IsVectorAtCompileTime
                       || int(StrideType::OuterStrideAtCompileTime)==int(Dynamic) || int(StrideType::OuterStrideAtCompileTime)==int(Derived::OuterStrideAtCompileTime),
       // NOTE, this indirection of evaluator<Derived>::Alignment is needed
       // to workaround a very strange bug in MSVC related to the instantiation
       // of has_*ary_operator in evaluator<CwiseNullaryOp>.
       // This line is surprisingly very sensitive. For instance, simply adding parenthesis
       // as "DerivedAlignment = (int(evaluator<Derived>::Alignment))," will make MSVC fail...
       DerivedAlignment = int(evaluator<Derived>::Alignment),
       AlignmentMatch = (int(traits<PlainObjectType>::Alignment)==int(Unaligned)) || (DerivedAlignment >= int(Alignment)), // FIXME the first condition is not very clear, it should be replaced by the required alignment
       ScalarTypeMatch = internal::is_same<typename PlainObjectType::Scalar, typename Derived::Scalar>::value,
       MatchAtCompileTime = HasDirectAccess && StorageOrderMatch && InnerStrideMatch && OuterStrideMatch && AlignmentMatch && ScalarTypeMatch
     };
     typedef typename internal::conditional<MatchAtCompileTime,internal::true_type,internal::false_type>::type type;
   };

 };

 template<typename Derived>
 struct traits<RefBase<Derived> > : public traits<Derived> {};

 }

 template<typename Derived> class RefBase
  : public MapBase<Derived>
 {
   typedef typename internal::traits<Derived>::PlainObjectType PlainObjectType;
   typedef typename internal::traits<Derived>::StrideType StrideType;

 public:

   typedef MapBase<Derived> Base;
   EIGEN_DENSE_PUBLIC_INTERFACE(RefBase)

   EIGEN_DEVICE_FUNC inline Index innerStride() const
   {
     return StrideType::InnerStrideAtCompileTime != 0 ? m_stride.inner() : 1;
   }

   EIGEN_DEVICE_FUNC inline Index outerStride() const
   {
     return StrideType::OuterStrideAtCompileTime != 0 ? m_stride.outer()
          : IsVectorAtCompileTime ? this->size()
          : int(Flags)&RowMajorBit ? this->cols()
          : this->rows();
   }

   EIGEN_DEVICE_FUNC RefBase()
     : Base(0,RowsAtCompileTime==Dynamic?0:RowsAtCompileTime,ColsAtCompileTime==Dynamic?0:ColsAtCompileTime),
       // Stride<> does not allow default ctor for Dynamic strides, so let' initialize it with dummy values:
       m_stride(StrideType::OuterStrideAtCompileTime==Dynamic?0:StrideType::OuterStrideAtCompileTime,
                StrideType::InnerStrideAtCompileTime==Dynamic?0:StrideType::InnerStrideAtCompileTime)
   {}

   EIGEN_INHERIT_ASSIGNMENT_OPERATORS(RefBase)

 protected:

   typedef Stride<StrideType::OuterStrideAtCompileTime,StrideType::InnerStrideAtCompileTime> StrideBase;

   template<typename Expression>
   EIGEN_DEVICE_FUNC void construct(Expression& expr)
   {
     EIGEN_STATIC_ASSERT_SAME_MATRIX_SIZE(PlainObjectType,Expression);

     if(PlainObjectType::RowsAtCompileTime==1)
     {
       eigen_assert(expr.rows()==1 || expr.cols()==1);
       ::new (static_cast<Base*>(this)) Base(expr.data(), 1, expr.size());
     }
     else if(PlainObjectType::ColsAtCompileTime==1)
     {
       eigen_assert(expr.rows()==1 || expr.cols()==1);
       ::new (static_cast<Base*>(this)) Base(expr.data(), expr.size(), 1);
     }
     else
       ::new (static_cast<Base*>(this)) Base(expr.data(), expr.rows(), expr.cols());

     if(Expression::IsVectorAtCompileTime && (!PlainObjectType::IsVectorAtCompileTime) && ((Expression::Flags&RowMajorBit)!=(PlainObjectType::Flags&RowMajorBit)))
       ::new (&m_stride) StrideBase(expr.innerStride(), StrideType::InnerStrideAtCompileTime==0?0:1);
     else
       ::new (&m_stride) StrideBase(StrideType::OuterStrideAtCompileTime==0?0:expr.outerStride(),
                                    StrideType::InnerStrideAtCompileTime==0?0:expr.innerStride());
   }

   StrideBase m_stride;
 };

 /** \class Ref
   * \ingroup Core_Module
   *
   * \brief A matrix or vector expression mapping an existing expression
   *
   * \tparam PlainObjectType the equivalent matrix type of the mapped data
   * \tparam Options specifies the pointer alignment in bytes. It can be: \c #Aligned128, , \c #Aligned64, \c #Aligned32, \c #Aligned16, \c #Aligned8 or \c #Unaligned.
   *                 The default is \c #Unaligned.
   * \tparam StrideType optionally specifies strides. By default, Ref implies a contiguous storage along the inner dimension (inner stride==1),
   *                   but accepts a variable outer stride (leading dimension).
   *                   This can be overridden by specifying strides.
   *                   The type passed here must be a specialization of the Stride template, see examples below.
   *
   * This class provides a way to write non-template functions taking Eigen objects as parameters while limiting the number of copies.
   * A Ref<> object can represent either a const expression or a l-value:
   * \code
   * // in-out argument:
   * void foo1(Ref<VectorXf> x);
   *
   * // read-only const argument:
   * void foo2(const Ref<const VectorXf>& x);
   * \endcode
   *
   * In the in-out case, the input argument must satisfy the constraints of the actual Ref<> type, otherwise a compilation issue will be triggered.
   * By default, a Ref<VectorXf> can reference any dense vector expression of float having a contiguous memory layout.
   * Likewise, a Ref<MatrixXf> can reference any column-major dense matrix expression of float whose column's elements are contiguously stored with
   * the possibility to have a constant space in-between each column, i.e. the inner stride must be equal to 1, but the outer stride (or leading dimension)
   * can be greater than the number of rows.
   *
   * In the const case, if the input expression does not match the above requirement, then it is evaluated into a temporary before being passed to the function.
   * Here are some examples:
   * \code
   * MatrixXf A;
   * VectorXf a;
   * foo1(a.head());             // OK
   * foo1(A.col());              // OK
   * foo1(A.row());              // Compilation error because here innerstride!=1
   * foo2(A.row());              // Compilation error because A.row() is a 1xN object while foo2 is expecting a Nx1 object
   * foo2(A.row().transpose());  // The row is copied into a contiguous temporary
   * foo2(2*a);                  // The expression is evaluated into a temporary
   * foo2(A.col().segment(2,4)); // No temporary
   * \endcode
   *
   * The range of inputs that can be referenced without temporary can be enlarged using the last two template parameters.
   * Here is an example accepting an innerstride!=1:
   * \code
   * // in-out argument:
   * void foo3(Ref<VectorXf,0,InnerStride<> > x);
   * foo3(A.row());              // OK
   * \endcode
   * The downside here is that the function foo3 might be significantly slower than foo1 because it won't be able to exploit vectorization, and will involve more
   * expensive address computations even if the input is contiguously stored in memory. To overcome this issue, one might propose to overload internally calling a
   * template function, e.g.:
   * \code
   * // in the .h:
   * void foo(const Ref<MatrixXf>& A);
   * void foo(const Ref<MatrixXf,0,Stride<> >& A);
   *
   * // in the .cpp:
   * template<typename TypeOfA> void foo_impl(const TypeOfA& A) {
   *     ... // crazy code goes here
   * }
   * void foo(const Ref<MatrixXf>& A) { foo_impl(A); }
   * void foo(const Ref<MatrixXf,0,Stride<> >& A) { foo_impl(A); }
   * \endcode
   *
   * See also the following stackoverflow questions for further references:
   *  - <a href="http://stackoverflow.com/questions/21132538/correct-usage-of-the-eigenref-class">Correct usage of the Eigen::Ref<> class</a>
   *
   * \sa PlainObjectBase::Map(), \ref TopicStorageOrders
   */
 template<typename PlainObjectType, int Options, typename StrideType> class Ref
   : public RefBase<Ref<PlainObjectType, Options, StrideType> >
 {
   private:
     typedef internal::traits<Ref> Traits;
     template<typename Derived>
     EIGEN_DEVICE_FUNC inline Ref(const PlainObjectBase<Derived>& expr,
                                  typename internal::enable_if<bool(Traits::template match<Derived>::MatchAtCompileTime),Derived>::type* = 0);
   public:

     typedef RefBase<Ref> Base;
     EIGEN_DENSE_PUBLIC_INTERFACE(Ref)


     #ifndef EIGEN_PARSED_BY_DOXYGEN
     template<typename Derived>
     EIGEN_DEVICE_FUNC inline Ref(PlainObjectBase<Derived>& expr,
                                  typename internal::enable_if<bool(Traits::template match<Derived>::MatchAtCompileTime),Derived>::type* = 0)
     {
       EIGEN_STATIC_ASSERT(bool(Traits::template match<Derived>::MatchAtCompileTime), STORAGE_LAYOUT_DOES_NOT_MATCH);
       Base::construct(expr.derived());
     }
     template<typename Derived>
     EIGEN_DEVICE_FUNC inline Ref(const DenseBase<Derived>& expr,
                                  typename internal::enable_if<bool(Traits::template match<Derived>::MatchAtCompileTime),Derived>::type* = 0)
     #else
     /** Implicit constructor from any dense expression */
     template<typename Derived>
     inline Ref(DenseBase<Derived>& expr)
     #endif
     {
       EIGEN_STATIC_ASSERT(bool(internal::is_lvalue<Derived>::value), THIS_EXPRESSION_IS_NOT_A_LVALUE__IT_IS_READ_ONLY);
       EIGEN_STATIC_ASSERT(bool(Traits::template match<Derived>::MatchAtCompileTime), STORAGE_LAYOUT_DOES_NOT_MATCH);
       EIGEN_STATIC_ASSERT(!Derived::IsPlainObjectBase,THIS_EXPRESSION_IS_NOT_A_LVALUE__IT_IS_READ_ONLY);
       Base::construct(expr.const_cast_derived());
     }

     EIGEN_INHERIT_ASSIGNMENT_OPERATORS(Ref)

 };

 // this is the const ref version
 template<typename TPlainObjectType, int Options, typename StrideType> class Ref<const TPlainObjectType, Options, StrideType>
   : public RefBase<Ref<const TPlainObjectType, Options, StrideType> >
 {
     typedef internal::traits<Ref> Traits;
   public:

     typedef RefBase<Ref> Base;
     EIGEN_DENSE_PUBLIC_INTERFACE(Ref)

     template<typename Derived>
     EIGEN_DEVICE_FUNC inline Ref(const DenseBase<Derived>& expr,
                                  typename internal::enable_if<bool(Traits::template match<Derived>::ScalarTypeMatch),Derived>::type* = 0)
     {
 //      std::cout << match_helper<Derived>::HasDirectAccess << "," << match_helper<Derived>::OuterStrideMatch << "," << match_helper<Derived>::InnerStrideMatch << "\n";
 //      std::cout << int(StrideType::OuterStrideAtCompileTime) << " - " << int(Derived::OuterStrideAtCompileTime) << "\n";
 //      std::cout << int(StrideType::InnerStrideAtCompileTime) << " - " << int(Derived::InnerStrideAtCompileTime) << "\n";
       construct(expr.derived(), typename Traits::template match<Derived>::type());
     }

     EIGEN_DEVICE_FUNC inline Ref(const Ref& other) : Base(other) {
       // copy constructor shall not copy the m_object, to avoid unnecessary malloc and copy
     }

     template<typename OtherRef>
     EIGEN_DEVICE_FUNC inline Ref(const RefBase<OtherRef>& other) {
       construct(other.derived(), typename Traits::template match<OtherRef>::type());
     }

   protected:

     template<typename Expression>
     EIGEN_DEVICE_FUNC void construct(const Expression& expr,internal::true_type)
     {
       Base::construct(expr);
     }

     template<typename Expression>
     EIGEN_DEVICE_FUNC void construct(const Expression& expr, internal::false_type)
     {
       internal::call_assignment_no_alias(m_object,expr,internal::assign_op<Scalar,Scalar>());
       Base::construct(m_object);
     }

   protected:
     TPlainObjectType m_object;
 };

 } // end namespace Eigen

 #endif // EIGEN_REF_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2012 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_REF_H
	#define EIGEN_REF_H

	namespace Eigen {

	namespace internal {

	template<typename _PlainObjectType, int _Options, typename _StrideType>
	struct traits<Ref<_PlainObjectType, _Options, _StrideType> >
	: public traits<Map<_PlainObjectType, _Options, _StrideType> >
	{
	typedef _PlainObjectType PlainObjectType;
	typedef _StrideType StrideType;
	enum {
	Options = _Options,
	Flags = traits<Map<_PlainObjectType, _Options, _StrideType> >::Flags \| NestByRefBit,
	Alignment = traits<Map<_PlainObjectType, _Options, _StrideType> >::Alignment
	};

	template<typename Derived> struct match {
	enum {
	IsVectorAtCompileTime = PlainObjectType::IsVectorAtCompileTime \|\| Derived::IsVectorAtCompileTime,
	HasDirectAccess = internal::has_direct_access<Derived>::ret,
	StorageOrderMatch = IsVectorAtCompileTime \|\| ((PlainObjectType::Flags&RowMajorBit)==(Derived::Flags&RowMajorBit)),
	InnerStrideMatch = int(StrideType::InnerStrideAtCompileTime)==int(Dynamic)
	\|\| int(StrideType::InnerStrideAtCompileTime)==int(Derived::InnerStrideAtCompileTime)
	\|\| (int(StrideType::InnerStrideAtCompileTime)==0 && int(Derived::InnerStrideAtCompileTime)==1),
	OuterStrideMatch = IsVectorAtCompileTime
	\|\| int(StrideType::OuterStrideAtCompileTime)==int(Dynamic) \|\| int(StrideType::OuterStrideAtCompileTime)==int(Derived::OuterStrideAtCompileTime),
	// NOTE, this indirection of evaluator<Derived>::Alignment is needed
	// to workaround a very strange bug in MSVC related to the instantiation
	// of has_*ary_operator in evaluator<CwiseNullaryOp>.
	// This line is surprisingly very sensitive. For instance, simply adding parenthesis
	// as "DerivedAlignment = (int(evaluator<Derived>::Alignment))," will make MSVC fail...
	DerivedAlignment = int(evaluator<Derived>::Alignment),
	AlignmentMatch = (int(traits<PlainObjectType>::Alignment)==int(Unaligned)) \|\| (DerivedAlignment >= int(Alignment)), // FIXME the first condition is not very clear, it should be replaced by the required alignment
	ScalarTypeMatch = internal::is_same<typename PlainObjectType::Scalar, typename Derived::Scalar>::value,
	MatchAtCompileTime = HasDirectAccess && StorageOrderMatch && InnerStrideMatch && OuterStrideMatch && AlignmentMatch && ScalarTypeMatch
	};
	typedef typename internal::conditional<MatchAtCompileTime,internal::true_type,internal::false_type>::type type;
	};

	};

	template<typename Derived>
	struct traits<RefBase<Derived> > : public traits<Derived> {};

	}

	template<typename Derived> class RefBase
	: public MapBase<Derived>
	{
	typedef typename internal::traits<Derived>::PlainObjectType PlainObjectType;
	typedef typename internal::traits<Derived>::StrideType StrideType;

	public:

	typedef MapBase<Derived> Base;
	EIGEN_DENSE_PUBLIC_INTERFACE(RefBase)

	EIGEN_DEVICE_FUNC inline Index innerStride() const
	{
	return StrideType::InnerStrideAtCompileTime != 0 ? m_stride.inner() : 1;
	}

	EIGEN_DEVICE_FUNC inline Index outerStride() const
	{
	return StrideType::OuterStrideAtCompileTime != 0 ? m_stride.outer()
	: IsVectorAtCompileTime ? this->size()
	: int(Flags)&RowMajorBit ? this->cols()
	: this->rows();
	}

	EIGEN_DEVICE_FUNC RefBase()
	: Base(0,RowsAtCompileTime==Dynamic?0:RowsAtCompileTime,ColsAtCompileTime==Dynamic?0:ColsAtCompileTime),
	// Stride<> does not allow default ctor for Dynamic strides, so let' initialize it with dummy values:
	m_stride(StrideType::OuterStrideAtCompileTime==Dynamic?0:StrideType::OuterStrideAtCompileTime,
	StrideType::InnerStrideAtCompileTime==Dynamic?0:StrideType::InnerStrideAtCompileTime)
	{}

	EIGEN_INHERIT_ASSIGNMENT_OPERATORS(RefBase)

	protected:

	typedef Stride<StrideType::OuterStrideAtCompileTime,StrideType::InnerStrideAtCompileTime> StrideBase;

	template<typename Expression>
	EIGEN_DEVICE_FUNC void construct(Expression& expr)
	{
	EIGEN_STATIC_ASSERT_SAME_MATRIX_SIZE(PlainObjectType,Expression);

	if(PlainObjectType::RowsAtCompileTime==1)
	{
	eigen_assert(expr.rows()==1 \|\| expr.cols()==1);
	::new (static_cast<Base*>(this)) Base(expr.data(), 1, expr.size());
	}
	else if(PlainObjectType::ColsAtCompileTime==1)
	{
	eigen_assert(expr.rows()==1 \|\| expr.cols()==1);
	::new (static_cast<Base*>(this)) Base(expr.data(), expr.size(), 1);
	}
	else
	::new (static_cast<Base*>(this)) Base(expr.data(), expr.rows(), expr.cols());

	if(Expression::IsVectorAtCompileTime && (!PlainObjectType::IsVectorAtCompileTime) && ((Expression::Flags&RowMajorBit)!=(PlainObjectType::Flags&RowMajorBit)))
	::new (&m_stride) StrideBase(expr.innerStride(), StrideType::InnerStrideAtCompileTime==0?0:1);
	else
	::new (&m_stride) StrideBase(StrideType::OuterStrideAtCompileTime==0?0:expr.outerStride(),
	StrideType::InnerStrideAtCompileTime==0?0:expr.innerStride());
	}

	StrideBase m_stride;
	};

	/** \class Ref
	* \ingroup Core_Module
	*
	* \brief A matrix or vector expression mapping an existing expression
	*
	* \tparam PlainObjectType the equivalent matrix type of the mapped data
	* \tparam Options specifies the pointer alignment in bytes. It can be: \c #Aligned128, , \c #Aligned64, \c #Aligned32, \c #Aligned16, \c #Aligned8 or \c #Unaligned.
	* The default is \c #Unaligned.
	* \tparam StrideType optionally specifies strides. By default, Ref implies a contiguous storage along the inner dimension (inner stride==1),
	* but accepts a variable outer stride (leading dimension).
	* This can be overridden by specifying strides.
	* The type passed here must be a specialization of the Stride template, see examples below.
	*
	* This class provides a way to write non-template functions taking Eigen objects as parameters while limiting the number of copies.
	* A Ref<> object can represent either a const expression or a l-value:
	* \code
	* // in-out argument:
	* void foo1(Ref<VectorXf> x);
	*
	* // read-only const argument:
	* void foo2(const Ref<const VectorXf>& x);
	* \endcode
	*
	* In the in-out case, the input argument must satisfy the constraints of the actual Ref<> type, otherwise a compilation issue will be triggered.
	* By default, a Ref<VectorXf> can reference any dense vector expression of float having a contiguous memory layout.
	* Likewise, a Ref<MatrixXf> can reference any column-major dense matrix expression of float whose column's elements are contiguously stored with
	* the possibility to have a constant space in-between each column, i.e. the inner stride must be equal to 1, but the outer stride (or leading dimension)
	* can be greater than the number of rows.
	*
	* In the const case, if the input expression does not match the above requirement, then it is evaluated into a temporary before being passed to the function.
	* Here are some examples:
	* \code
	* MatrixXf A;
	* VectorXf a;
	* foo1(a.head()); // OK
	* foo1(A.col()); // OK
	* foo1(A.row()); // Compilation error because here innerstride!=1
	* foo2(A.row()); // Compilation error because A.row() is a 1xN object while foo2 is expecting a Nx1 object
	* foo2(A.row().transpose()); // The row is copied into a contiguous temporary
	* foo2(2*a); // The expression is evaluated into a temporary
	* foo2(A.col().segment(2,4)); // No temporary
	* \endcode
	*
	* The range of inputs that can be referenced without temporary can be enlarged using the last two template parameters.
	* Here is an example accepting an innerstride!=1:
	* \code
	* // in-out argument:
	* void foo3(Ref<VectorXf,0,InnerStride<> > x);
	* foo3(A.row()); // OK
	* \endcode
	* The downside here is that the function foo3 might be significantly slower than foo1 because it won't be able to exploit vectorization, and will involve more
	* expensive address computations even if the input is contiguously stored in memory. To overcome this issue, one might propose to overload internally calling a
	* template function, e.g.:
	* \code
	* // in the .h:
	* void foo(const Ref<MatrixXf>& A);
	* void foo(const Ref<MatrixXf,0,Stride<> >& A);
	*
	* // in the .cpp:
	* template<typename TypeOfA> void foo_impl(const TypeOfA& A) {
	* ... // crazy code goes here
	* }
	* void foo(const Ref<MatrixXf>& A) { foo_impl(A); }
	* void foo(const Ref<MatrixXf,0,Stride<> >& A) { foo_impl(A); }
	* \endcode
	*
	* See also the following stackoverflow questions for further references:
	* - <a href="http://stackoverflow.com/questions/21132538/correct-usage-of-the-eigenref-class">Correct usage of the Eigen::Ref<> class</a>
	*
	* \sa PlainObjectBase::Map(), \ref TopicStorageOrders
	*/
	template<typename PlainObjectType, int Options, typename StrideType> class Ref
	: public RefBase<Ref<PlainObjectType, Options, StrideType> >
	{
	private:
	typedef internal::traits<Ref> Traits;
	template<typename Derived>
	EIGEN_DEVICE_FUNC inline Ref(const PlainObjectBase<Derived>& expr,
	typename internal::enable_if<bool(Traits::template match<Derived>::MatchAtCompileTime),Derived>::type* = 0);
	public:

	typedef RefBase<Ref> Base;
	EIGEN_DENSE_PUBLIC_INTERFACE(Ref)


	#ifndef EIGEN_PARSED_BY_DOXYGEN
	template<typename Derived>
	EIGEN_DEVICE_FUNC inline Ref(PlainObjectBase<Derived>& expr,
	typename internal::enable_if<bool(Traits::template match<Derived>::MatchAtCompileTime),Derived>::type* = 0)
	{
	EIGEN_STATIC_ASSERT(bool(Traits::template match<Derived>::MatchAtCompileTime), STORAGE_LAYOUT_DOES_NOT_MATCH);
	Base::construct(expr.derived());
	}
	template<typename Derived>
	EIGEN_DEVICE_FUNC inline Ref(const DenseBase<Derived>& expr,
	typename internal::enable_if<bool(Traits::template match<Derived>::MatchAtCompileTime),Derived>::type* = 0)
	#else
	/** Implicit constructor from any dense expression */
	template<typename Derived>
	inline Ref(DenseBase<Derived>& expr)
	#endif
	{
	EIGEN_STATIC_ASSERT(bool(internal::is_lvalue<Derived>::value), THIS_EXPRESSION_IS_NOT_A_LVALUE__IT_IS_READ_ONLY);
	EIGEN_STATIC_ASSERT(bool(Traits::template match<Derived>::MatchAtCompileTime), STORAGE_LAYOUT_DOES_NOT_MATCH);
	EIGEN_STATIC_ASSERT(!Derived::IsPlainObjectBase,THIS_EXPRESSION_IS_NOT_A_LVALUE__IT_IS_READ_ONLY);
	Base::construct(expr.const_cast_derived());
	}

	EIGEN_INHERIT_ASSIGNMENT_OPERATORS(Ref)

	};

	// this is the const ref version
	template<typename TPlainObjectType, int Options, typename StrideType> class Ref<const TPlainObjectType, Options, StrideType>
	: public RefBase<Ref<const TPlainObjectType, Options, StrideType> >
	{
	typedef internal::traits<Ref> Traits;
	public:

	typedef RefBase<Ref> Base;
	EIGEN_DENSE_PUBLIC_INTERFACE(Ref)

	template<typename Derived>
	EIGEN_DEVICE_FUNC inline Ref(const DenseBase<Derived>& expr,
	typename internal::enable_if<bool(Traits::template match<Derived>::ScalarTypeMatch),Derived>::type* = 0)
	{
	// std::cout << match_helper<Derived>::HasDirectAccess << "," << match_helper<Derived>::OuterStrideMatch << "," << match_helper<Derived>::InnerStrideMatch << "\n";
	// std::cout << int(StrideType::OuterStrideAtCompileTime) << " - " << int(Derived::OuterStrideAtCompileTime) << "\n";
	// std::cout << int(StrideType::InnerStrideAtCompileTime) << " - " << int(Derived::InnerStrideAtCompileTime) << "\n";
	construct(expr.derived(), typename Traits::template match<Derived>::type());
	}

	EIGEN_DEVICE_FUNC inline Ref(const Ref& other) : Base(other) {
	// copy constructor shall not copy the m_object, to avoid unnecessary malloc and copy
	}

	template<typename OtherRef>
	EIGEN_DEVICE_FUNC inline Ref(const RefBase<OtherRef>& other) {
	construct(other.derived(), typename Traits::template match<OtherRef>::type());
	}

	protected:

	template<typename Expression>
	EIGEN_DEVICE_FUNC void construct(const Expression& expr,internal::true_type)
	{
	Base::construct(expr);
	}

	template<typename Expression>
	EIGEN_DEVICE_FUNC void construct(const Expression& expr, internal::false_type)
	{
	internal::call_assignment_no_alias(m_object,expr,internal::assign_op<Scalar,Scalar>());
	Base::construct(m_object);
	}

	protected:
	TPlainObjectType m_object;
	};

	} // end namespace Eigen

	#endif // EIGEN_REF_H