Eigen/src/Core/Array.h - eigen/fuchsia - Git at Google

 // 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_ARRAY_H
 #define EIGEN_ARRAY_H

 namespace Eigen {

 namespace internal {
 template<typename _Scalar, int _Rows, int _Cols, int _Options, int _MaxRows, int _MaxCols>
 struct traits<Array<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> > : traits<Matrix<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> >
 {
   typedef ArrayXpr XprKind;
   typedef ArrayBase<Array<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> > XprBase;
 };
 }

 /** \class Array
   * \ingroup Core_Module
   *
   * \brief General-purpose arrays with easy API for coefficient-wise operations
   *
   * The %Array class is very similar to the Matrix class. It provides
   * general-purpose one- and two-dimensional arrays. The difference between the
   * %Array and the %Matrix class is primarily in the API: the API for the
   * %Array class provides easy access to coefficient-wise operations, while the
   * API for the %Matrix class provides easy access to linear-algebra
   * operations.
   *
   * See documentation of class Matrix for detailed information on the template parameters
   * storage layout.
   *
   * This class can be extended with the help of the plugin mechanism described on the page
   * \ref TopicCustomizing_Plugins by defining the preprocessor symbol \c EIGEN_ARRAY_PLUGIN.
   *
   * \sa \blank \ref TutorialArrayClass, \ref TopicClassHierarchy
   */
 template<typename _Scalar, int _Rows, int _Cols, int _Options, int _MaxRows, int _MaxCols>
 class Array
   : public PlainObjectBase<Array<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> >
 {
   public:

     typedef PlainObjectBase<Array> Base;
     EIGEN_DENSE_PUBLIC_INTERFACE(Array)

     enum { Options = _Options };
     typedef typename Base::PlainObject PlainObject;

   protected:
     template <typename Derived, typename OtherDerived, bool IsVector>
     friend struct internal::conservative_resize_like_impl;

     using Base::m_storage;

   public:

     using Base::base;
     using Base::coeff;
     using Base::coeffRef;

     /**
       * The usage of
       *   using Base::operator=;
       * fails on MSVC. Since the code below is working with GCC and MSVC, we skipped
       * the usage of 'using'. This should be done only for operator=.
       */
     template<typename OtherDerived>
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array& operator=(const EigenBase<OtherDerived> &other)
     {
       return Base::operator=(other);
     }

     /** Set all the entries to \a value.
       * \sa DenseBase::setConstant(), DenseBase::fill()
       */
     /* This overload is needed because the usage of
       *   using Base::operator=;
       * fails on MSVC. Since the code below is working with GCC and MSVC, we skipped
       * the usage of 'using'. This should be done only for operator=.
       */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array& operator=(const Scalar &value)
     {
       Base::setConstant(value);
       return *this;
     }

     /** Copies the value of the expression \a other into \c *this with automatic resizing.
       *
       * *this might be resized to match the dimensions of \a other. If *this was a null matrix (not already initialized),
       * it will be initialized.
       *
       * Note that copying a row-vector into a vector (and conversely) is allowed.
       * The resizing, if any, is then done in the appropriate way so that row-vectors
       * remain row-vectors and vectors remain vectors.
       */
     template<typename OtherDerived>
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array& operator=(const DenseBase<OtherDerived>& other)
     {
       return Base::_set(other);
     }

     /** This is a special case of the templated operator=. Its purpose is to
       * prevent a default operator= from hiding the templated operator=.
       */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array& operator=(const Array& other)
     {
       return Base::_set(other);
     }

     /** Default constructor.
       *
       * For fixed-size matrices, does nothing.
       *
       * For dynamic-size matrices, creates an empty matrix of size 0. Does not allocate any array. Such a matrix
       * is called a null matrix. This constructor is the unique way to create null matrices: resizing
       * a matrix to 0 is not supported.
       *
       * \sa resize(Index,Index)
       */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array() : Base()
     {
       Base::_check_template_params();
       EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED
     }

 #ifndef EIGEN_PARSED_BY_DOXYGEN
     // FIXME is it still needed ??
     /** \internal */
     EIGEN_DEVICE_FUNC
     Array(internal::constructor_without_unaligned_array_assert)
       : Base(internal::constructor_without_unaligned_array_assert())
     {
       Base::_check_template_params();
       EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED
     }
 #endif

 #if EIGEN_HAS_RVALUE_REFERENCES
     EIGEN_DEVICE_FUNC
     Array(Array&& other) EIGEN_NOEXCEPT_IF(std::is_nothrow_move_constructible<Scalar>::value)
       : Base(std::move(other))
     {
       Base::_check_template_params();
     }
     EIGEN_DEVICE_FUNC
     Array& operator=(Array&& other) EIGEN_NOEXCEPT_IF(std::is_nothrow_move_assignable<Scalar>::value)
     {
       other.swap(*this);
       return *this;
     }
 #endif

     #ifndef EIGEN_PARSED_BY_DOXYGEN
     template<typename T>
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE explicit Array(const T& x)
     {
       Base::_check_template_params();
       Base::template _init1<T>(x);
     }

     template<typename T0, typename T1>
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array(const T0& val0, const T1& val1)
     {
       Base::_check_template_params();
       this->template _init2<T0,T1>(val0, val1);
     }
     #else
     /** \brief Constructs a fixed-sized array initialized with coefficients starting at \a data */
     EIGEN_DEVICE_FUNC explicit Array(const Scalar *data);
     /** Constructs a vector or row-vector with given dimension. \only_for_vectors
       *
       * Note that this is only useful for dynamic-size vectors. For fixed-size vectors,
       * it is redundant to pass the dimension here, so it makes more sense to use the default
       * constructor Array() instead.
       */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE explicit Array(Index dim);
     /** constructs an initialized 1x1 Array with the given coefficient */
     Array(const Scalar& value);
     /** constructs an uninitialized array with \a rows rows and \a cols columns.
       *
       * This is useful for dynamic-size arrays. For fixed-size arrays,
       * it is redundant to pass these parameters, so one should use the default constructor
       * Array() instead. */
     Array(Index rows, Index cols);
     /** constructs an initialized 2D vector with given coefficients */
     Array(const Scalar& val0, const Scalar& val1);
     #endif

     /** constructs an initialized 3D vector with given coefficients */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array(const Scalar& val0, const Scalar& val1, const Scalar& val2)
     {
       Base::_check_template_params();
       EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(Array, 3)
       m_storage.data()[0] = val0;
       m_storage.data()[1] = val1;
       m_storage.data()[2] = val2;
     }
     /** constructs an initialized 4D vector with given coefficients */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array(const Scalar& val0, const Scalar& val1, const Scalar& val2, const Scalar& val3)
     {
       Base::_check_template_params();
       EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(Array, 4)
       m_storage.data()[0] = val0;
       m_storage.data()[1] = val1;
       m_storage.data()[2] = val2;
       m_storage.data()[3] = val3;
     }

     /** Copy constructor */
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array(const Array& other)
             : Base(other)
     { }

   private:
     struct PrivateType {};
   public:

     /** \sa MatrixBase::operator=(const EigenBase<OtherDerived>&) */
     template<typename OtherDerived>
     EIGEN_DEVICE_FUNC
     EIGEN_STRONG_INLINE Array(const EigenBase<OtherDerived> &other,
                               typename internal::enable_if<internal::is_convertible<typename OtherDerived::Scalar,Scalar>::value,
                                                            PrivateType>::type = PrivateType())
       : Base(other.derived())
     { }

     EIGEN_DEVICE_FUNC inline Index innerStride() const { return 1; }
     EIGEN_DEVICE_FUNC inline Index outerStride() const { return this->innerSize(); }

     #ifdef EIGEN_ARRAY_PLUGIN
     #include EIGEN_ARRAY_PLUGIN
     #endif

   private:

     template<typename MatrixType, typename OtherDerived, bool SwapPointers>
     friend struct internal::matrix_swap_impl;
 };

 /** \defgroup arraytypedefs Global array typedefs
   * \ingroup Core_Module
   *
   * Eigen defines several typedef shortcuts for most common 1D and 2D array types.
   *
   * The general patterns are the following:
   *
   * \c ArrayRowsColsType where \c Rows and \c Cols can be \c 2,\c 3,\c 4 for fixed size square matrices or \c X for dynamic size,
   * and where \c Type can be \c i for integer, \c f for float, \c d for double, \c cf for complex float, \c cd
   * for complex double.
   *
   * For example, \c Array33d is a fixed-size 3x3 array type of doubles, and \c ArrayXXf is a dynamic-size matrix of floats.
   *
   * There are also \c ArraySizeType which are self-explanatory. For example, \c Array4cf is
   * a fixed-size 1D array of 4 complex floats.
   *
   * \sa class Array
   */

 #define EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, Size, SizeSuffix)   \
 /** \ingroup arraytypedefs */                                    \
 typedef Array<Type, Size, Size> Array##SizeSuffix##SizeSuffix##TypeSuffix;  \
 /** \ingroup arraytypedefs */                                    \
 typedef Array<Type, Size, 1>    Array##SizeSuffix##TypeSuffix;

 #define EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, Size)         \
 /** \ingroup arraytypedefs */                                    \
 typedef Array<Type, Size, Dynamic> Array##Size##X##TypeSuffix;  \
 /** \ingroup arraytypedefs */                                    \
 typedef Array<Type, Dynamic, Size> Array##X##Size##TypeSuffix;

 #define EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(Type, TypeSuffix) \
 EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, 2, 2) \
 EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, 3, 3) \
 EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, 4, 4) \
 EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, Dynamic, X) \
 EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, 2) \
 EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, 3) \
 EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, 4)

 EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(int,                  i)
 EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(float,                f)
 EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(double,               d)
 EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(std::complex<float>,  cf)
 EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(std::complex<double>, cd)

 #undef EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES
 #undef EIGEN_MAKE_ARRAY_TYPEDEFS

 #undef EIGEN_MAKE_ARRAY_TYPEDEFS_LARGE

 #define EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, SizeSuffix) \
 using Eigen::Matrix##SizeSuffix##TypeSuffix; \
 using Eigen::Vector##SizeSuffix##TypeSuffix; \
 using Eigen::RowVector##SizeSuffix##TypeSuffix;

 #define EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(TypeSuffix) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, 2) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, 3) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, 4) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, X) \

 #define EIGEN_USING_ARRAY_TYPEDEFS \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(i) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(f) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(d) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(cf) \
 EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(cd)

 } // end namespace Eigen

 #endif // EIGEN_ARRAY_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_ARRAY_H
	#define EIGEN_ARRAY_H

	namespace Eigen {

	namespace internal {
	template<typename _Scalar, int _Rows, int _Cols, int _Options, int _MaxRows, int _MaxCols>
	struct traits<Array<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> > : traits<Matrix<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> >
	{
	typedef ArrayXpr XprKind;
	typedef ArrayBase<Array<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> > XprBase;
	};
	}

	/** \class Array
	* \ingroup Core_Module
	*
	* \brief General-purpose arrays with easy API for coefficient-wise operations
	*
	* The %Array class is very similar to the Matrix class. It provides
	* general-purpose one- and two-dimensional arrays. The difference between the
	* %Array and the %Matrix class is primarily in the API: the API for the
	* %Array class provides easy access to coefficient-wise operations, while the
	* API for the %Matrix class provides easy access to linear-algebra
	* operations.
	*
	* See documentation of class Matrix for detailed information on the template parameters
	* storage layout.
	*
	* This class can be extended with the help of the plugin mechanism described on the page
	* \ref TopicCustomizing_Plugins by defining the preprocessor symbol \c EIGEN_ARRAY_PLUGIN.
	*
	* \sa \blank \ref TutorialArrayClass, \ref TopicClassHierarchy
	*/
	template<typename _Scalar, int _Rows, int _Cols, int _Options, int _MaxRows, int _MaxCols>
	class Array
	: public PlainObjectBase<Array<_Scalar, _Rows, _Cols, _Options, _MaxRows, _MaxCols> >
	{
	public:

	typedef PlainObjectBase<Array> Base;
	EIGEN_DENSE_PUBLIC_INTERFACE(Array)

	enum { Options = _Options };
	typedef typename Base::PlainObject PlainObject;

	protected:
	template <typename Derived, typename OtherDerived, bool IsVector>
	friend struct internal::conservative_resize_like_impl;

	using Base::m_storage;

	public:

	using Base::base;
	using Base::coeff;
	using Base::coeffRef;

	/**
	* The usage of
	* using Base::operator=;
	* fails on MSVC. Since the code below is working with GCC and MSVC, we skipped
	* the usage of 'using'. This should be done only for operator=.
	*/
	template<typename OtherDerived>
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array& operator=(const EigenBase<OtherDerived> &other)
	{
	return Base::operator=(other);
	}

	/** Set all the entries to \a value.
	* \sa DenseBase::setConstant(), DenseBase::fill()
	*/
	/* This overload is needed because the usage of
	* using Base::operator=;
	* fails on MSVC. Since the code below is working with GCC and MSVC, we skipped
	* the usage of 'using'. This should be done only for operator=.
	*/
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array& operator=(const Scalar &value)
	{
	Base::setConstant(value);
	return *this;
	}

	/** Copies the value of the expression \a other into \c *this with automatic resizing.
	*
	* this might be resized to match the dimensions of \a other. If this was a null matrix (not already initialized),
	* it will be initialized.
	*
	* Note that copying a row-vector into a vector (and conversely) is allowed.
	* The resizing, if any, is then done in the appropriate way so that row-vectors
	* remain row-vectors and vectors remain vectors.
	*/
	template<typename OtherDerived>
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array& operator=(const DenseBase<OtherDerived>& other)
	{
	return Base::_set(other);
	}

	/** This is a special case of the templated operator=. Its purpose is to
	* prevent a default operator= from hiding the templated operator=.
	*/
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array& operator=(const Array& other)
	{
	return Base::_set(other);
	}

	/** Default constructor.
	*
	* For fixed-size matrices, does nothing.
	*
	* For dynamic-size matrices, creates an empty matrix of size 0. Does not allocate any array. Such a matrix
	* is called a null matrix. This constructor is the unique way to create null matrices: resizing
	* a matrix to 0 is not supported.
	*
	* \sa resize(Index,Index)
	*/
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array() : Base()
	{
	Base::_check_template_params();
	EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED
	}

	#ifndef EIGEN_PARSED_BY_DOXYGEN
	// FIXME is it still needed ??
	/** \internal */
	EIGEN_DEVICE_FUNC
	Array(internal::constructor_without_unaligned_array_assert)
	: Base(internal::constructor_without_unaligned_array_assert())
	{
	Base::_check_template_params();
	EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED
	}
	#endif

	#if EIGEN_HAS_RVALUE_REFERENCES
	EIGEN_DEVICE_FUNC
	Array(Array&& other) EIGEN_NOEXCEPT_IF(std::is_nothrow_move_constructible<Scalar>::value)
	: Base(std::move(other))
	{
	Base::_check_template_params();
	}
	EIGEN_DEVICE_FUNC
	Array& operator=(Array&& other) EIGEN_NOEXCEPT_IF(std::is_nothrow_move_assignable<Scalar>::value)
	{
	other.swap(*this);
	return *this;
	}
	#endif

	#ifndef EIGEN_PARSED_BY_DOXYGEN
	template<typename T>
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE explicit Array(const T& x)
	{
	Base::_check_template_params();
	Base::template _init1<T>(x);
	}

	template<typename T0, typename T1>
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array(const T0& val0, const T1& val1)
	{
	Base::_check_template_params();
	this->template _init2<T0,T1>(val0, val1);
	}
	#else
	/** \brief Constructs a fixed-sized array initialized with coefficients starting at \a data */
	EIGEN_DEVICE_FUNC explicit Array(const Scalar *data);
	/** Constructs a vector or row-vector with given dimension. \only_for_vectors
	*
	* Note that this is only useful for dynamic-size vectors. For fixed-size vectors,
	* it is redundant to pass the dimension here, so it makes more sense to use the default
	* constructor Array() instead.
	*/
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE explicit Array(Index dim);
	/** constructs an initialized 1x1 Array with the given coefficient */
	Array(const Scalar& value);
	/** constructs an uninitialized array with \a rows rows and \a cols columns.
	*
	* This is useful for dynamic-size arrays. For fixed-size arrays,
	* it is redundant to pass these parameters, so one should use the default constructor
	* Array() instead. */
	Array(Index rows, Index cols);
	/** constructs an initialized 2D vector with given coefficients */
	Array(const Scalar& val0, const Scalar& val1);
	#endif

	/** constructs an initialized 3D vector with given coefficients */
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array(const Scalar& val0, const Scalar& val1, const Scalar& val2)
	{
	Base::_check_template_params();
	EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(Array, 3)
	m_storage.data()[0] = val0;
	m_storage.data()[1] = val1;
	m_storage.data()[2] = val2;
	}
	/** constructs an initialized 4D vector with given coefficients */
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array(const Scalar& val0, const Scalar& val1, const Scalar& val2, const Scalar& val3)
	{
	Base::_check_template_params();
	EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(Array, 4)
	m_storage.data()[0] = val0;
	m_storage.data()[1] = val1;
	m_storage.data()[2] = val2;
	m_storage.data()[3] = val3;
	}

	/** Copy constructor */
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array(const Array& other)
	: Base(other)
	{ }

	private:
	struct PrivateType {};
	public:

	/** \sa MatrixBase::operator=(const EigenBase<OtherDerived>&) */
	template<typename OtherDerived>
	EIGEN_DEVICE_FUNC
	EIGEN_STRONG_INLINE Array(const EigenBase<OtherDerived> &other,
	typename internal::enable_if<internal::is_convertible<typename OtherDerived::Scalar,Scalar>::value,
	PrivateType>::type = PrivateType())
	: Base(other.derived())
	{ }

	EIGEN_DEVICE_FUNC inline Index innerStride() const { return 1; }
	EIGEN_DEVICE_FUNC inline Index outerStride() const { return this->innerSize(); }

	#ifdef EIGEN_ARRAY_PLUGIN
	#include EIGEN_ARRAY_PLUGIN
	#endif

	private:

	template<typename MatrixType, typename OtherDerived, bool SwapPointers>
	friend struct internal::matrix_swap_impl;
	};

	/** \defgroup arraytypedefs Global array typedefs
	* \ingroup Core_Module
	*
	* Eigen defines several typedef shortcuts for most common 1D and 2D array types.
	*
	* The general patterns are the following:
	*
	* \c ArrayRowsColsType where \c Rows and \c Cols can be \c 2,\c 3,\c 4 for fixed size square matrices or \c X for dynamic size,
	* and where \c Type can be \c i for integer, \c f for float, \c d for double, \c cf for complex float, \c cd
	* for complex double.
	*
	* For example, \c Array33d is a fixed-size 3x3 array type of doubles, and \c ArrayXXf is a dynamic-size matrix of floats.
	*
	* There are also \c ArraySizeType which are self-explanatory. For example, \c Array4cf is
	* a fixed-size 1D array of 4 complex floats.
	*
	* \sa class Array
	*/

	#define EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, Size, SizeSuffix) \
	/** \ingroup arraytypedefs */ \
	typedef Array<Type, Size, Size> Array##SizeSuffix##SizeSuffix##TypeSuffix; \
	/** \ingroup arraytypedefs */ \
	typedef Array<Type, Size, 1> Array##SizeSuffix##TypeSuffix;

	#define EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, Size) \
	/** \ingroup arraytypedefs */ \
	typedef Array<Type, Size, Dynamic> Array##Size##X##TypeSuffix; \
	/** \ingroup arraytypedefs */ \
	typedef Array<Type, Dynamic, Size> Array##X##Size##TypeSuffix;

	#define EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(Type, TypeSuffix) \
	EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, 2, 2) \
	EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, 3, 3) \
	EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, 4, 4) \
	EIGEN_MAKE_ARRAY_TYPEDEFS(Type, TypeSuffix, Dynamic, X) \
	EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, 2) \
	EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, 3) \
	EIGEN_MAKE_ARRAY_FIXED_TYPEDEFS(Type, TypeSuffix, 4)

	EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(int, i)
	EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(float, f)
	EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(double, d)
	EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(std::complex<float>, cf)
	EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES(std::complex<double>, cd)

	#undef EIGEN_MAKE_ARRAY_TYPEDEFS_ALL_SIZES
	#undef EIGEN_MAKE_ARRAY_TYPEDEFS

	#undef EIGEN_MAKE_ARRAY_TYPEDEFS_LARGE

	#define EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, SizeSuffix) \
	using Eigen::Matrix##SizeSuffix##TypeSuffix; \
	using Eigen::Vector##SizeSuffix##TypeSuffix; \
	using Eigen::RowVector##SizeSuffix##TypeSuffix;

	#define EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(TypeSuffix) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, 2) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, 3) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, 4) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE_AND_SIZE(TypeSuffix, X) \

	#define EIGEN_USING_ARRAY_TYPEDEFS \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(i) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(f) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(d) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(cf) \
	EIGEN_USING_ARRAY_TYPEDEFS_FOR_TYPE(cd)

	} // end namespace Eigen

	#endif // EIGEN_ARRAY_H