doc/xml/multi_array_ref.xml - RealtimeRoboticsGroup/test - Gitiles

 <sect2 id="multi_array_ref">
 <title><literal>multi_array_ref</literal></title>

 <para>
 <literal>multi_array_ref</literal> is a multi-dimensional container
 adaptor.  It provides the MultiArray interface over any contiguous
 block of elements.  <literal>multi_array_ref</literal> exports the
 same interface as <literal>multi_array</literal>, with the exception
 of the constructors.
 </para>


 <formalpara>
       <title>Model Of.</title>
 <para>
 <literal>multi_array_ref</literal> models
 <link linkend="MultiArray">MultiArray</link>,
 <ulink url="../../../libs/utility/CopyConstructible.html">CopyConstructible</ulink>.
 and depending on the element type, it may also model
 <ulink url="http://www.sgi.com/tech/stl/EqualityComparable.html">EqualityComparable</ulink> and <ulink url="http://www.sgi.com/tech/stl/LessThanComparable.html">LessThanComparable</ulink>.
 Detailed descriptions are provided here only for operations that are
 not described in the <literal>multi_array</literal> reference.
 </para>
 </formalpara>

 <formalpara>
 <title>Synopsis</title>

 <programlisting>
 <![CDATA[
 namespace boost {

 template <typename ValueType,
           std::size_t NumDims>
 class multi_array_ref {
 public:
 // types:
   typedef ValueType                             element;
   typedef *unspecified*                         value_type;
   typedef *unspecified*                         reference;
   typedef *unspecified*                         const_reference;
   typedef *unspecified*                         difference_type;
   typedef *unspecified*                         iterator;
   typedef *unspecified*                         const_iterator;
   typedef *unspecified*                         reverse_iterator;
   typedef *unspecified*                         const_reverse_iterator;
   typedef multi_array_types::size_type          size_type;
   typedef multi_array_types::index              index;
   typedef multi_array_types::index_gen          index_gen;
   typedef multi_array_types::index_range        index_range;
   typedef multi_array_types::extent_gen         extent_gen;
   typedef multi_array_types::extent_range       extent_range;
   typedef *unspecified*                         storage_order_type;

   // template typedefs
   template <std::size_t Dims> struct            subarray;
   template <std::size_t Dims> struct            const_subarray;
   template <std::size_t Dims> struct            array_view;
   template <std::size_t Dims> struct            const_array_view;


   static const std::size_t dimensionality = NumDims;


   // constructors and destructors

   template <typename ExtentList>
   explicit multi_array_ref(element* data, const ExtentList& sizes,
                        const storage_order_type& store = c_storage_order());
   explicit multi_array_ref(element* data, const extents_tuple& ranges,
                        const storage_order_type& store = c_storage_order());
   multi_array_ref(const multi_array_ref& x);
   ~multi_array_ref();

   // modifiers

   multi_array_ref& operator=(const multi_array_ref& x);
   template <class Array> multi_array_ref& operator=(const Array& x);

   // iterators:
   iterator				begin();
   iterator				end();
   const_iterator			begin() const;
   const_iterator			end() const;
   reverse_iterator			rbegin();
   reverse_iterator			rend();
   const_reverse_iterator		rbegin() const;
   const_reverse_iterator		rend() const;

   // capacity:
   size_type				size() const;
   size_type				num_elements() const;
   size_type				num_dimensions() const;

   // element access:
   template <typename IndexList>
     element&			operator()(const IndexList& indices);
   template <typename IndexList>
     const element&		operator()(const IndexList& indices) const;
   reference			operator[](index i);
   const_reference		operator[](index i) const;
   array_view<Dims>::type	operator[](const indices_tuple& r);
   const_array_view<Dims>::type	operator[](const indices_tuple& r) const;

   // queries
   element*			data();
   const element*		data() const;
   element*			origin();
   const element*		origin() const;
   const size_type*		shape() const;
   const index*			strides() const;
   const index*			index_bases() const;
   const storage_order_type&     storage_order() const;

   // comparators
   bool operator==(const multi_array_ref& rhs);
   bool operator!=(const multi_array_ref& rhs);
   bool operator<(const multi_array_ref& rhs);
   bool operator>(const multi_array_ref& rhs);
   bool operator>=(const multi_array_ref& rhs);
   bool operator<=(const multi_array_ref& rhs);

   // modifiers:
   template <typename InputIterator>
     void			assign(InputIterator begin, InputIterator end);
   template <typename SizeList>
     void			reshape(const SizeList& sizes)
   template <typename BaseList>	void reindex(const BaseList& values);
   void				reindex(index value);
 };
 ]]>
 </programlisting>
 </formalpara>

 <formalpara>
 <title>Constructors</title>

 <variablelist>
 <varlistentry>
 <term><programlisting>template &lt;typename ExtentList&gt;
 explicit multi_array_ref(element* data,
                      const ExtentList&amp; sizes,
                      const storage_order&amp; store = c_storage_order(),
                      const Allocator&amp; alloc = Allocator());
 </programlisting></term>
 <listitem>

 <para>
 This constructs a <literal>multi_array_ref</literal> using the specified
 parameters.  <literal>sizes</literal> specifies the shape of the
 constructed <literal>multi_array_ref</literal>.  <literal>store</literal>
 specifies the storage order or layout in memory of the array
 dimensions.  <literal>alloc</literal> is used to
 allocate the contained elements.
 </para>

 <formalpara><title><literal>ExtentList</literal> Requirements</title>
 <para>
 <literal>ExtentList</literal> must model <ulink url="../../utility/Collection.html">Collection</ulink>.
 </para>
 </formalpara>

 <formalpara><title>Preconditions</title>
 <para><literal>sizes.size() == NumDims;</literal></para>
 </formalpara>

 </listitem>
 </varlistentry>

 <varlistentry>
 <term>
 <programlisting><![CDATA[explicit multi_array_ref(element* data,
                      extent_gen::gen_type<NumDims>::type ranges,
                      const storage_order& store = c_storage_order());]]>
 </programlisting></term>
 <listitem>
 <para>
 This constructs a <literal>multi_array_ref</literal> using the specified
     parameters.  <literal>ranges</literal> specifies the shape and
 index bases of the constructed multi_array_ref. It is the result of
 <literal>NumDims</literal> chained calls to
     <literal>extent_gen::operator[]</literal>. <literal>store</literal>
 specifies the storage order or layout in memory of the array
 dimensions.
 </para>
 </listitem>
 </varlistentry>


 <varlistentry>
 <term><programlisting>
 <![CDATA[multi_array_ref(const multi_array_ref& x);]]>
 </programlisting></term>
 <listitem>
 <para>This constructs a shallow copy of <literal>x</literal>.
 </para>

 <formalpara>
 <title>Complexity</title>
 <para> Constant time (for contrast, compare this to
 the <literal>multi_array</literal> class copy constructor.
 </para></formalpara>
 </listitem>
 </varlistentry>

 </variablelist>

 </formalpara>


 <formalpara>
 <title>Modifiers</title>

 <variablelist>
 <varlistentry>

 <term><programlisting>
 <![CDATA[multi_array_ref& operator=(const multi_array_ref& x);
 template <class Array> multi_array_ref& operator=(const Array& x);]]>
 </programlisting>
 </term>

 <listitem>
 <para>This performs an element-wise copy of <literal>x</literal>
 into the current <literal>multi_array_ref</literal>.</para>

 <formalpara>
 <title><literal>Array</literal> Requirements</title>
 <para><literal>Array</literal> must model MultiArray.
 </para></formalpara>

 <formalpara>
 <title>Preconditions</title>
 <para>
 <programlisting>std::equal(this->shape(),this->shape()+this->num_dimensions(),
 x.shape());</programlisting></para>
 </formalpara>


 <formalpara>
 <title>Postconditions</title>
 <para>
 <programlisting>(*.this) == x;</programlisting>
 </para>
 </formalpara>

 <formalpara>
 <title>Complexity</title>
 <para>The assignment operators perform
 O(<literal>x.num_elements()</literal>) calls to <literal>element</literal>'s
 copy constructor.</para></formalpara>
 </listitem>
 </varlistentry>
 </variablelist>

 </formalpara>
 </sect2>
	<sect2 id="multi_array_ref">
	<title><literal>multi_array_ref</literal></title>

	<para>
	<literal>multi_array_ref</literal> is a multi-dimensional container
	adaptor. It provides the MultiArray interface over any contiguous
	block of elements. <literal>multi_array_ref</literal> exports the
	same interface as <literal>multi_array</literal>, with the exception
	of the constructors.
	</para>


	<formalpara>
	<title>Model Of.</title>
	<para>
	<literal>multi_array_ref</literal> models
	<link linkend="MultiArray">MultiArray</link>,
	<ulink url="../../../libs/utility/CopyConstructible.html">CopyConstructible</ulink>.
	and depending on the element type, it may also model
	<ulink url="http://www.sgi.com/tech/stl/EqualityComparable.html">EqualityComparable</ulink> and <ulink url="http://www.sgi.com/tech/stl/LessThanComparable.html">LessThanComparable</ulink>.
	Detailed descriptions are provided here only for operations that are
	not described in the <literal>multi_array</literal> reference.
	</para>
	</formalpara>

	<formalpara>
	<title>Synopsis</title>

	<programlisting>
	<![CDATA[
	namespace boost {

	template <typename ValueType,
	std::size_t NumDims>
	class multi_array_ref {
	public:
	// types:
	typedef ValueType element;
	typedef unspecified value_type;
	typedef unspecified reference;
	typedef unspecified const_reference;
	typedef unspecified difference_type;
	typedef unspecified iterator;
	typedef unspecified const_iterator;
	typedef unspecified reverse_iterator;
	typedef unspecified const_reverse_iterator;
	typedef multi_array_types::size_type size_type;
	typedef multi_array_types::index index;
	typedef multi_array_types::index_gen index_gen;
	typedef multi_array_types::index_range index_range;
	typedef multi_array_types::extent_gen extent_gen;
	typedef multi_array_types::extent_range extent_range;
	typedef unspecified storage_order_type;

	// template typedefs
	template <std::size_t Dims> struct subarray;
	template <std::size_t Dims> struct const_subarray;
	template <std::size_t Dims> struct array_view;
	template <std::size_t Dims> struct const_array_view;


	static const std::size_t dimensionality = NumDims;


	// constructors and destructors

	template <typename ExtentList>
	explicit multi_array_ref(element* data, const ExtentList& sizes,
	const storage_order_type& store = c_storage_order());
	explicit multi_array_ref(element* data, const extents_tuple& ranges,
	const storage_order_type& store = c_storage_order());
	multi_array_ref(const multi_array_ref& x);
	~multi_array_ref();

	// modifiers

	multi_array_ref& operator=(const multi_array_ref& x);
	template <class Array> multi_array_ref& operator=(const Array& x);

	// iterators:
	iterator begin();
	iterator end();
	const_iterator begin() const;
	const_iterator end() const;
	reverse_iterator rbegin();
	reverse_iterator rend();
	const_reverse_iterator rbegin() const;
	const_reverse_iterator rend() const;

	// capacity:
	size_type size() const;
	size_type num_elements() const;
	size_type num_dimensions() const;

	// element access:
	template <typename IndexList>
	element& operator()(const IndexList& indices);
	template <typename IndexList>
	const element& operator()(const IndexList& indices) const;
	reference operator[](index i);
	const_reference operator[](index i) const;
	array_view<Dims>::type operator[](const indices_tuple& r);
	const_array_view<Dims>::type operator[](const indices_tuple& r) const;

	// queries
	element* data();
	const element* data() const;
	element* origin();
	const element* origin() const;
	const size_type* shape() const;
	const index* strides() const;
	const index* index_bases() const;
	const storage_order_type& storage_order() const;

	// comparators
	bool operator==(const multi_array_ref& rhs);
	bool operator!=(const multi_array_ref& rhs);
	bool operator<(const multi_array_ref& rhs);
	bool operator>(const multi_array_ref& rhs);
	bool operator>=(const multi_array_ref& rhs);
	bool operator<=(const multi_array_ref& rhs);

	// modifiers:
	template <typename InputIterator>
	void assign(InputIterator begin, InputIterator end);
	template <typename SizeList>
	void reshape(const SizeList& sizes)
	template <typename BaseList> void reindex(const BaseList& values);
	void reindex(index value);
	};
	]]>
	</programlisting>
	</formalpara>

	<formalpara>
	<title>Constructors</title>

	<variablelist>
	<varlistentry>
	<term><programlisting>template <typename ExtentList>
	explicit multi_array_ref(element* data,
	const ExtentList& sizes,
	const storage_order& store = c_storage_order(),
	const Allocator& alloc = Allocator());
	</programlisting></term>
	<listitem>

	<para>
	This constructs a <literal>multi_array_ref</literal> using the specified
	parameters. <literal>sizes</literal> specifies the shape of the
	constructed <literal>multi_array_ref</literal>. <literal>store</literal>
	specifies the storage order or layout in memory of the array
	dimensions. <literal>alloc</literal> is used to
	allocate the contained elements.
	</para>

	<formalpara><title><literal>ExtentList</literal> Requirements</title>
	<para>
	<literal>ExtentList</literal> must model <ulink url="../../utility/Collection.html">Collection</ulink>.
	</para>
	</formalpara>

	<formalpara><title>Preconditions</title>
	<para><literal>sizes.size() == NumDims;</literal></para>
	</formalpara>

	</listitem>
	</varlistentry>

	<varlistentry>
	<term>
	<programlisting><![CDATA[explicit multi_array_ref(element* data,
	extent_gen::gen_type<NumDims>::type ranges,
	const storage_order& store = c_storage_order());]]>
	</programlisting></term>
	<listitem>
	<para>
	This constructs a <literal>multi_array_ref</literal> using the specified
	parameters. <literal>ranges</literal> specifies the shape and
	index bases of the constructed multi_array_ref. It is the result of
	<literal>NumDims</literal> chained calls to
	<literal>extent_gen::operator[]</literal>. <literal>store</literal>
	specifies the storage order or layout in memory of the array
	dimensions.
	</para>
	</listitem>
	</varlistentry>


	<varlistentry>
	<term><programlisting>
	<![CDATA[multi_array_ref(const multi_array_ref& x);]]>
	</programlisting></term>
	<listitem>
	<para>This constructs a shallow copy of <literal>x</literal>.
	</para>

	<formalpara>
	<title>Complexity</title>
	<para> Constant time (for contrast, compare this to
	the <literal>multi_array</literal> class copy constructor.
	</para></formalpara>
	</listitem>
	</varlistentry>

	</variablelist>

	</formalpara>


	<formalpara>
	<title>Modifiers</title>

	<variablelist>
	<varlistentry>

	<term><programlisting>
	<![CDATA[multi_array_ref& operator=(const multi_array_ref& x);
	template <class Array> multi_array_ref& operator=(const Array& x);]]>
	</programlisting>
	</term>

	<listitem>
	<para>This performs an element-wise copy of <literal>x</literal>
	into the current <literal>multi_array_ref</literal>.</para>

	<formalpara>
	<title><literal>Array</literal> Requirements</title>
	<para><literal>Array</literal> must model MultiArray.
	</para></formalpara>

	<formalpara>
	<title>Preconditions</title>
	<para>
	<programlisting>std::equal(this->shape(),this->shape()+this->num_dimensions(),
	x.shape());</programlisting></para>
	</formalpara>


	<formalpara>
	<title>Postconditions</title>
	<para>
	<programlisting>(*.this) == x;</programlisting>
	</para>
	</formalpara>

	<formalpara>
	<title>Complexity</title>
	<para>The assignment operators perform
	O(<literal>x.num_elements()</literal>) calls to <literal>element</literal>'s
	copy constructor.</para></formalpara>
	</listitem>
	</varlistentry>
	</variablelist>

	</formalpara>
	</sect2>