boost_1_45_0/libs/iterator/doc/quickbook/utilities.qbk - nest-learning-thermostat/5.0/boost - Git at Google


 [section:utilities Iterator Utilities]

 [section:utilities_traits Traits]

 [h2 Overview]

 Have you ever wanted to write a generic function that can operate
 on any kind of dereferenceable object?  If you have, you've
 probably run into the problem of how to determine the type that the
 object "points at":

    template <class Dereferenceable>
    void f(Dereferenceable p)
    {
        *what-goes-here?* value = \*p;
        ...
    }


 [h2 `pointee`]

 It turns out to be impossible to come up with a fully-general
 algorithm to do determine *what-goes-here* directly, but it is
 possible to require that `pointee<Dereferenceable>::type` is
 correct. Naturally, `pointee` has the same difficulty: it can't
 determine the appropriate `::type` reliably for all
 `Dereferenceable`\ s, but it makes very good guesses (it works
 for all pointers, standard and boost smart pointers, and
 iterators), and when it guesses wrongly, it can be specialized as
 necessary:

   namespace boost
   {
     template <class T>
     struct pointee<third_party_lib::smart_pointer<T> >
     {
         typedef T type;
     };
   }

 [h2 `indirect_reference`]

 `indirect_reference<T>::type` is rather more specialized than
 `pointee`, and is meant to be used to forward the result of
 dereferencing an object of its argument type.  Most dereferenceable
 types just return a reference to their pointee, but some return
 proxy references or return the pointee by value.  When that
 information is needed, call on `indirect_reference`.

 Both of these templates are essential to the correct functioning of
 [link indirecct `indirect_iterator`].

 [h2 Reference]

 [h3 `pointeee`]

   template <class Dereferenceable>
   struct pointee
   {
       typedef /* see below */ type;
   };

 [*Requires:] For an object `x` of type `Dereferenceable`, `*x`
   is well-formed.  If `++x` is ill-formed it shall neither be
   ambiguous nor shall it violate access control, and
   `Dereferenceable::element_type` shall be an accessible type.
   Otherwise `iterator_traits<Dereferenceable>::value_type` shall
   be well formed. \[Note: These requirements need not apply to
   explicit or partial specializations of `pointee`\]

 `type` is determined according to the following algorithm, where
 `x` is an object of type `Dereferenceable`:

   if ( ++x is ill-formed )
   {
       return `Dereferenceable::element_type`
   }
   else if (`*x` is a mutable reference to
            std::iterator_traits<Dereferenceable>::value_type)
   {
       return iterator_traits<Dereferenceable>::value_type
   }
   else
   {
       return iterator_traits<Dereferenceable>::value_type const
   }

 [h3 `indirect_reference`]

   template <class Dereferenceable>
   struct indirect_reference
   {
       typedef /* see below */ type;
   };

 [*Requires:] For an object `x` of type `Dereferenceable`, `*x`
   is well-formed.  If `++x` is ill-formed it shall neither be
   ambiguous nor shall it violate access control, and
   `pointee<Dereferenceable>::type&` shall be well-formed.
   Otherwise `iterator_traits<Dereferenceable>::reference` shall
   be well formed.  \[Note: These requirements need not apply to
   explicit or partial specializations of `indirect_reference`\]

 `type` is determined according to the following algorithm, where
 `x` is an object of type `Dereferenceable`:

   if ( ++x is ill-formed )
       return `pointee<Dereferenceable>::type&`
   else
       std::iterator_traits<Dereferenceable>::reference


 [endsect]

 [section:utilities_testing Testing and Concept Checking]

 The iterator concept checking classes provide a mechanism for a
 template to report better error messages when a user instantiates
 the template with a type that does not meet the requirements of the
 template.

 For an introduction to using concept checking classes, see
 the documentation for the
 [@../../concept_check/index.html `boost::concept_check`] library.


 [h2 Reference]

 [h3 Iterator Access Concepts]

 * |Readable|_
 * |Writable|_
 * |Swappable|_
 * |Lvalue|_

 [/ .. |Readable| replace:: *Readable Iterator* ]
 [/ .. _Readable: ReadableIterator.html            ]
 [/                                                ]
 [/ .. |Writable| replace:: *Writable Iterator*    ]
 [/ .. _Writable: WritableIterator.html            ]
 [/                                                ]
 [/ .. |Swappable| replace:: *Swappable Iterator*  ]
 [/ .. _Swappable: SwappableIterator.html          ]
 [/                                                ]
 [/ .. |Lvalue| replace:: *Lvalue Iterator*        ]
 [/ .. _Lvalue: LvalueIterator.html                ]


 Iterator Traversal Concepts
 ...........................

 * |Incrementable|_
 * |SinglePass|_
 * |Forward|_
 * |Bidir|_
 * |Random|_


 [/ .. |Incrementable| replace:: *Incrementable Iterator* ]
 [/ .. _Incrementable: IncrementableIterator.html         ]
 [/                                                       ]
 [/ .. |SinglePass| replace:: *Single Pass Iterator*      ]
 [/ .. _SinglePass: SinglePassIterator.html               ]
 [/                                                       ]
 [/ .. |Forward| replace:: *Forward Traversal*            ]
 [/ .. _Forward: ForwardTraversal.html                    ]
 [/                                                       ]
 [/ .. |Bidir| replace:: *Bidirectional Traversal*        ]
 [/ .. _Bidir: BidirectionalTraversal.html                ]
 [/                                                       ]
 [/ .. |Random| replace:: *Random Access Traversal*       ]
 [/ .. _Random: RandomAccessTraversal.html                ]


 [h3 `iterator_concepts.hpp` Synopsis]

     namespace boost_concepts {

         // Iterator Access Concepts

         template <typename Iterator>
         class ReadableIteratorConcept;

         template <
             typename Iterator
           , typename ValueType = std::iterator_traits<Iterator>::value_type
         >
         class WritableIteratorConcept;

         template <typename Iterator>
         class SwappableIteratorConcept;

         template <typename Iterator>
         class LvalueIteratorConcept;

         // Iterator Traversal Concepts

         template <typename Iterator>
         class IncrementableIteratorConcept;

         template <typename Iterator>
         class SinglePassIteratorConcept;

         template <typename Iterator>
         class ForwardTraversalConcept;

         template <typename Iterator>
         class BidirectionalTraversalConcept;

         template <typename Iterator>
         class RandomAccessTraversalConcept;

         // Interoperability

         template <typename Iterator, typename ConstIterator>
         class InteroperableIteratorConcept;

     }

 [endsect]

 [endsect]

	[section:utilities Iterator Utilities]

	[section:utilities_traits Traits]

	[h2 Overview]

	Have you ever wanted to write a generic function that can operate
	on any kind of dereferenceable object? If you have, you've
	probably run into the problem of how to determine the type that the
	object "points at":

	template <class Dereferenceable>
	void f(Dereferenceable p)
	{
	what-goes-here? value = \*p;
	...
	}


	[h2 `pointee`]

	It turns out to be impossible to come up with a fully-general
	algorithm to do determine what-goes-here directly, but it is
	possible to require that `pointee<Dereferenceable>::type` is
	correct. Naturally, `pointee` has the same difficulty: it can't
	determine the appropriate `::type` reliably for all
	`Dereferenceable`\ s, but it makes very good guesses (it works
	for all pointers, standard and boost smart pointers, and
	iterators), and when it guesses wrongly, it can be specialized as
	necessary:

	namespace boost
	{
	template <class T>
	struct pointee<third_party_lib::smart_pointer<T> >
	{
	typedef T type;
	};
	}

	[h2 `indirect_reference`]

	`indirect_reference<T>::type` is rather more specialized than
	`pointee`, and is meant to be used to forward the result of
	dereferencing an object of its argument type. Most dereferenceable
	types just return a reference to their pointee, but some return
	proxy references or return the pointee by value. When that
	information is needed, call on `indirect_reference`.

	Both of these templates are essential to the correct functioning of
	[link indirecct `indirect_iterator`].

	[h2 Reference]

	[h3 `pointeee`]

	template <class Dereferenceable>
	struct pointee
	{
	typedef /* see below */ type;
	};

	[Requires:] For an object `x` of type `Dereferenceable`, `x`
	is well-formed. If `++x` is ill-formed it shall neither be
	ambiguous nor shall it violate access control, and
	`Dereferenceable::element_type` shall be an accessible type.
	Otherwise `iterator_traits<Dereferenceable>::value_type` shall
	be well formed. \[Note: These requirements need not apply to
	explicit or partial specializations of `pointee`\]

	`type` is determined according to the following algorithm, where
	`x` is an object of type `Dereferenceable`:

	if ( ++x is ill-formed )
	{
	return `Dereferenceable::element_type`
	}
	else if (`*x` is a mutable reference to
	std::iterator_traits<Dereferenceable>::value_type)
	{
	return iterator_traits<Dereferenceable>::value_type
	}
	else
	{
	return iterator_traits<Dereferenceable>::value_type const
	}

	[h3 `indirect_reference`]

	template <class Dereferenceable>
	struct indirect_reference
	{
	typedef /* see below */ type;
	};

	[Requires:] For an object `x` of type `Dereferenceable`, `x`
	is well-formed. If `++x` is ill-formed it shall neither be
	ambiguous nor shall it violate access control, and
	`pointee<Dereferenceable>::type&` shall be well-formed.
	Otherwise `iterator_traits<Dereferenceable>::reference` shall
	be well formed. \[Note: These requirements need not apply to
	explicit or partial specializations of `indirect_reference`\]

	`type` is determined according to the following algorithm, where
	`x` is an object of type `Dereferenceable`:

	if ( ++x is ill-formed )
	return `pointee<Dereferenceable>::type&`
	else
	std::iterator_traits<Dereferenceable>::reference


	[endsect]

	[section:utilities_testing Testing and Concept Checking]

	The iterator concept checking classes provide a mechanism for a
	template to report better error messages when a user instantiates
	the template with a type that does not meet the requirements of the
	template.

	For an introduction to using concept checking classes, see
	the documentation for the
	[@../../concept_check/index.html `boost::concept_check`] library.


	[h2 Reference]

	[h3 Iterator Access Concepts]

	* \|Readable\|_
	* \|Writable\|_
	* \|Swappable\|_
	* \|Lvalue\|_

	[/ .. \|Readable\| replace:: Readable Iterator ]
	[/ .. _Readable: ReadableIterator.html ]
	[/ ]
	[/ .. \|Writable\| replace:: Writable Iterator ]
	[/ .. _Writable: WritableIterator.html ]
	[/ ]
	[/ .. \|Swappable\| replace:: Swappable Iterator ]
	[/ .. _Swappable: SwappableIterator.html ]
	[/ ]
	[/ .. \|Lvalue\| replace:: Lvalue Iterator ]
	[/ .. _Lvalue: LvalueIterator.html ]


	Iterator Traversal Concepts
	...........................

	* \|Incrementable\|_
	* \|SinglePass\|_
	* \|Forward\|_
	* \|Bidir\|_
	* \|Random\|_


	[/ .. \|Incrementable\| replace:: Incrementable Iterator ]
	[/ .. _Incrementable: IncrementableIterator.html ]
	[/ ]
	[/ .. \|SinglePass\| replace:: Single Pass Iterator ]
	[/ .. _SinglePass: SinglePassIterator.html ]
	[/ ]
	[/ .. \|Forward\| replace:: Forward Traversal ]
	[/ .. _Forward: ForwardTraversal.html ]
	[/ ]
	[/ .. \|Bidir\| replace:: Bidirectional Traversal ]
	[/ .. _Bidir: BidirectionalTraversal.html ]
	[/ ]
	[/ .. \|Random\| replace:: Random Access Traversal ]
	[/ .. _Random: RandomAccessTraversal.html ]



	[h3 `iterator_concepts.hpp` Synopsis]

	namespace boost_concepts {

	// Iterator Access Concepts

	template <typename Iterator>
	class ReadableIteratorConcept;

	template <
	typename Iterator
	, typename ValueType = std::iterator_traits<Iterator>::value_type
	>
	class WritableIteratorConcept;

	template <typename Iterator>
	class SwappableIteratorConcept;

	template <typename Iterator>
	class LvalueIteratorConcept;

	// Iterator Traversal Concepts

	template <typename Iterator>
	class IncrementableIteratorConcept;

	template <typename Iterator>
	class SinglePassIteratorConcept;

	template <typename Iterator>
	class ForwardTraversalConcept;

	template <typename Iterator>
	class BidirectionalTraversalConcept;

	template <typename Iterator>
	class RandomAccessTraversalConcept;

	// Interoperability

	template <typename Iterator, typename ConstIterator>
	class InteroperableIteratorConcept;

	}

	[endsect]

	[endsect]