boost_1_45_0/libs/bimap/doc/reference/bimap.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [/license

 Boost.Bimap

 Copyright (c) 2006-2007 Matias Capeletto

 Distributed under the Boost Software License, Version 1.0.
 (See accompanying file LICENSE_1_0.txt or copy at
 http://www.boost.org/LICENSE_1_0.txt)

 ]

 [/ QuickBook Document version 1.4 ]

 [section Bimap Reference]

 [section View concepts]

 `bimap` instantiations comprise two side views and an view of the relation
 specified at compile time. Each view allows read-write access to the elements contained
 in a definite manner, mathing an STL container signature.

 Views are not isolated objects and so cannot be constructed on their
 own; rather they are an integral part of a `bimap`. The name of the view
 class implementation proper is never directly exposed to the user, who
 has access only to the associated view type specifier.

 Insertion and deletion of elements are always performed through the
 appropriate interface of any of the three views of the `bimap`; these
 operations do, however, have an impact on all other views as well: for
 instance, insertion through a given view may fail because there exists
 another view that forbids the operation in order to preserve its
 invariant (such as uniqueness of elements). The global operations
 performed jointly in the any view can be reduced to six primitives:

 * copying
 * insertion of an element
 * hinted insertion, where a pre-existing element is suggested in order to improve
 the efficiency of the operation
 * deletion of an element
 * replacement of the value of an element, which may trigger the
 rearrangement of this element in one or more views, or may forbid the
 replacement
 * modification of an element, and its subsequent
 rearrangement/banning by the various views

 The last two primitives deserve some further explanation: in order to
 guarantee the invariants associated to each view (e.g. some definite
 ordering) elements of a `bimap` are not mutable. To overcome this
 restriction, the views expose member functions for updating and
 modifying, which allows for the mutation of elements in a controlled
 fashion.

 [endsect]

 [#complexity_signature_explanation]

 [section Complexity signature]

 Some member functions of a view interface are implemented by global
 primitives from the above list. The complexity of these operations thus
 depends on all views of a given `bimap`, not just the currently used view.

 In order to establish complexity estimates, a view is characterised by
 its complexity signature, consisting of the following associated
 functions on the number of elements:

 * `c(n)`: copying
 * `i(n)`: insertion
 * `h(n)`: hinted insertion
 * `d(n)`: deletion
 * `r(n)`: replacement
 * `m(n)`: modifying

 If the collection type of the relation is `left_based` or `right_based`, and we use
 an `l` subscript to denote the left view and an `r` for the right view, then
 the insertion of an element in such a container is of complexity
 `O(i_l(n)+i_r(n))`, where n is the number of elements. If the collection type of
 relation is not side-based, then there is an additional term to add that
 is contributed by the collection type of relation view. Using `a` to denote the
 above view, the complexity of insertion will now be
 `O(i_l(n)+i_r(n)+i_a(n))`. To abbreviate the notation, we adopt the
 following definitions:

 * `C(n) = c_l(n) + c_r(n) [ + c_a(n) ]`
 * `I(n) = i_l(n) + i_r(n) [ + i_a(n) ]`
 * `H(n) = h_l(n) + h_r(n) [ + h_a(n) ]`
 * `D(n) = d_l(n) + d_r(n) [ + d_a(n) ]`
 * `R(n) = r_l(n) + r_r(n) [ + r_a(n) ]`
 * `M(n) = m_l(n) + m_r(n) [ + m_a(n) ]`

 [endsect]

 [section Set type specification]

 Set type specifiers are passed as instantiation arguments to `bimap` and
 provide the information needed to incorporate the corresponding views.
 Currently, Boost.Bimap provides the collection type specifiers. The ['side collection type]
 specifiers define the constraints of the two map views of the
 bimap. The ['collection type of relation] specifier defines the main set view
 constraints. If `left_based` (the default parameter) or `right_based` is
 used, then the collection type of relation will be based on the left or right
 collection type correspondingly.

 [table
 [[Side collection type      ][Collection type of relation       ][Include                                 ]]
 [[`set_of`                  ][`set_of_relation`               ][`boost/bimap/set_of.hpp`                ]]
 [[`multiset_of`             ][`multiset_of_relation`          ][`boost/bimap/multiset_of.hpp`           ]]
 [[`unordered_set_of`        ][`unordered_set_of_relation`     ][`boost/bimap/unordered_set_of.hpp`      ]]
 [[`unordered_multiset_of`   ][`unordered_multiset_of_relation`][`boost/bimap/unordered_multiset_of.hpp` ]]
 [[`list_of`                 ][`list_of_relation`              ][`boost/bimap/list_of.hpp`               ]]
 [[`vector_of`               ][`vector_of_relation`            ][`boost/bimap/vector_of.hpp`             ]]
 [[`unconstrained_set_of`    ][`unconstrained_set_of_relation` ][`boost/bimap/unconstrained_set_of.hpp`  ]]
 [[                          ][`left_based`                    ][`boost/bimap/bimap.hpp`                 ]]
 [[                          ][`right_based`                   ][`boost/bimap/bimap.hpp`                 ]]
 ]

 [endsect]

 [section Tags]

 Tags are just conventional types used as mnemonics for the types stored
 in a `bimap`. Boost.Bimap uses the tagged idiom to let the user specify
 this tags.

 [endsect]

 [section Header "boost/bimap/bimap.hpp" synopsis]

     namespace boost {
     namespace bimaps {

     template< class Type, typename Tag >
     struct tagged;

     // bimap template class

     template
     <
         class LeftCollectionType, class RightCollectionType,

         class AdditionalParameter_1 = detail::not_specified,
         class AdditionalParameter_2 = detail::not_specified
     >
     class bimap ``['- implementation defined { : public SetView } -]``
     {
         public:

         // Metadata

         typedef ``['-unspecified-]`` left_tag;
         typedef ``['-unspecified-]`` left_map;

         typedef ``['-unspecified-]`` right_tag;
         typedef ``['-unspecified-]`` right_map;

         // Shortcuts
         // typedef -side-_map::-type- -side-_-type-;

         typedef ``['-unspecified-]`` info_type;

         // Map views

          left_map  left;
         right_map right;

         // Constructors

         bimap();

         template< class InputIterator >
         bimap(InputIterator first,InputIterator last);

         bimap(const bimap &);

         bimap& operator=(const bimap& b);

         // Projection of iterators

         template< class IteratorType >
         left_iterator project_left(IteratorType iter);

         template< class IteratorType >
         left_const_iterator project_left(IteratorType iter) const;

         template< class IteratorType >
         right_iterator project_right(IteratorType iter);

         template< class IteratorType >
         right_const_iterator project_right(IteratorType iter) const;

         template< class IteratorType >
         iterator project_up(IteratorType iter);

         template< class IteratorType >
         const_iterator project_up(IteratorType iter) const;

         // Support for tags

         template< class Tag >
         struct map_by;

         template< class Tag >
         map_by<Tag>::type by();

         template< class Tag >
         const map_by<Tag>::type & by() const;

         template< class Tag, class IteratorType >
         map_by<Tag>::iterator project(IteratorType iter);

         template< class Tag, class IteratorType >
         map_by<Tag>::const_iterator project(IteratorType iter) const

     };


     } // namespace bimap
     } // namespace boost


 [/
     // Metafunctions for a bimap

     template< class Tag, class Bimap > struct value_type_by;
     template< class Tag, class Bimap > struct key_type_by;
     template< class Tag, class Bimap > struct data_type_by;
     template< class Tag, class Bimap > struct iterator_type_by;
     template< class Tag, class Bimap > struct const_iterator_type_by;
     template< class Tag, class Bimap > struct reverse_iterator_type_by;
     template< class Tag, class Bimap > struct const_reverse_iterator_type_by;
     template< class Tag, class Bimap > struct local_iterator_type_by;
     template< class Tag, class Bimap > struct const_local_iterator_type_by;

     // Functions for a bimap

     template<class Tag, class Relation>
     result_of::map_by< Tag, Bimap>::type map_by(Bimap &);

     // Metafunctions for a relation

     template< class Tag, class Relation > struct value_type_of;
     template< class Tag, class Relation > struct pair_type_by;

     // Functions for a relation

     template<class Tag, class Relation>
     result_of::get< Tag, Relation>::type get(Relation &r);

     template<class Tag, class Relation>
     result_of::pair_by< Tag, Relation>::type pair_by(Relation &);

 ]

 [endsect]

 [section Class template bimap]

 This is the main component of Boost.Bimap.

 [section Complexity]

 In the descriptions of the operations of `bimap`, we adopt the scheme
 outlined in the complexity signature section.

 [endsect]

 [section Instantiation types]

 `bimap` is instantiated with the following types:

 # LeftCollectionType and RightCollectionType are collection type specifications
 optionally tagged, or any type optionally tagged, in which case that
 side acts as a set.
 # AdditionalParameter_{1/2} can be any ordered subset of:
     * CollectionTypeOfRelation specification
     * Allocator

 [endsect]

 [section Nested types]

     left_tag, right_tag

 [:  Tags for each side of the bimap. If the user has not specified any tag the
     tags default to `member_at::left` and `member_at::right`.
 ]

     left_key_type, right_key_type

 [:  Key type of each side. In a `bimap<A,B> ` `left_key_type` is `A` and
     `right_key_type` is `B`.
     If there are tags, it is better to use: `Bimap::map_by<Tag>::key_type`.
 ]

     left_data_type, right_data_type

 [:  Data type of each side. In a bimap<A,B> left_key_type is B and
     right_key_type is A.
     If there are tags, it is better to use: `Bimap::map_by<Tag>::data_type`.
 ]

     left_value_type, right_value_type

 [:  Value type used for the views.
     If there are tags, it is better to use: `Bimap::map_by<Tag>::value_type`.
 ]


     left_iterator, right_iterator
     left_const_iterator, right_const_iterator

 [:  Iterators of the views.
     If there are tags, it is better to use:
     `Bimap::map_by<Tag>::iterator` and
     `Bimap::map_by<Tag>::const_iterator`
 ]


     left_map, right_map

 [:  Map view type of each side.
     If there are tags, it is better to use:
     `Bimap::map_by<Tag>::type`.
 ]

 [endsect]

 [section Constructors, copy and assignment]

     bimap();

 * [*Effects:] Constructs an empty `bimap`.
 * [*Complexity:] Constant.

     template<typename InputIterator>
     bimap(InputIterator first,InputIterator last);

 * [*Requires: ] `InputIterator` is a model of Input Iterator over elements of
 type `relation` or a type convertible to `relation`. last is reachable from `first`.
 * [*Effects:] Constructs an empty `bimap` and fills it with the elements in the range
 `[first,last)`. Insertion of each element may or may not succeed depending on
 acceptance by the collection types of the `bimap`.
 * [link complexity_signature_explanation
 [*Complexity:]] O(m*H(m)), where m is the number of elements in `[first,last)`.


     bimap(const bimap & x);

 * [*Effects:] Constructs a copy of x, copying its elements as well as its
 internal objects (key extractors, comparison objects, allocator.)
 * [*Postconditions:] `*this == x`. The order of the views of the `bimap`
 is preserved as well.
 * [*Complexity:] O(x.size()*log(x.size()) + C(x.size()))


     ~bimap()

 * [*Effects:] Destroys the `bimap` and all the elements contained.
 The order in which the elements are destroyed is not specified.
 * [*Complexity:] O(n).


     bimap& operator=(const bimap& x);

 * [*Effects:] Replaces the elements and internal objects of the `bimap`
 with copies from x.
 * [*Postconditions:] `*this==x`. The order on the views of the `bimap`
 is preserved as well.
 * [*Returns: ] `*this`.
 * [*Complexity:] O(n + x.size()*log(x.size()) + C(x.size())).
 * [*Exception safety:] Strong, provided the copy and assignment operations
 of the types of `ctor_args_list` do not throw.

 [/
     allocator_type get_allocator() const;

 * [*Effects:] Returns a copy of the `allocator_type` object used to construct
 the `bimap`.
 * [*Complexity:] Constant.
 ]

 [endsect]

 [#reference_projection_operations]

 [section Projection operations]

 Given a `bimap` with views v1 and v2, we say than an v1-iterator
 it1 and an v2-iterator it2 are equivalent if:

 * `it1 == i1.end()` AND `it2 == i2.end()`,
 * OR `it1` and `it2` point to the same element.


     template< class IteratorType >
     left_iterator project_left(IteratorType iter);

     template< class IteratorType >
     left_const_iterator project_left(IteratorType iter) const;

 * [*Requires:] `IteratorType` is a bimap view iterator. it is a
 valid iterator of some view of `*this` (i.e. does not refer to some other
 `bimap`.)
 * [*Effects:] Returns a left map view iterator equivalent to `it`.
 * [*Complexity:] Constant.
 * [*Exception safety:] nothrow.


     template< class IteratorType >
     right_iterator project_right(IteratorType iter);

     template< class IteratorType >
     right_const_iterator project_right(IteratorType iter) const;

 * [*Requires:] `IteratorType` is a bimap view iterator. it is a
 valid iterator of some view of `*this` (i.e. does not refer to some other
 `bimap`.)
 * [*Effects:] Returns a right map view iterator equivalent to `it`.
 * [*Complexity:] Constant.
 * [*Exception safety:] nothrow.


     template< class IteratorType >
     iterator project_up(IteratorType iter);

     template< class IteratorType >
     const_iterator project_up(IteratorType iter) const;

 * [*Requires:] `IteratorType` is a bimap view iterator. it is a
 valid iterator of some view of `*this` (i.e. does not refer to some other
 `bimap`.)
 * [*Effects:] Returns a collection of relations view iterator equivalent to `it`.
 * [*Complexity:] Constant.
 * [*Exception safety:] nothrow.

 [endsect]

 [#reference_support_for_used_defined_names]

 [section Support for user defined names]

     template< class Tag >
     struct map_by;

 * `map_by<Tag>::type` yields the type of the map view tagged with `Tag`.
 `map_by<Tag>::`['-type name-] is the same as `map_by<Tag>::type::`['-type name-].
 * [*Requires: ] `Tag` is a valid user defined name of the bimap.


     template< class Tag >
     map_by<Tag>::type by();

     template< class Tag >
     const map_by<Tag>::type & by() const;


 * [*Requires: ] `Tag` is a valid user defined name of the bimap.
 * [*Effects:] Returns a reference to the map view tagged with `Tag` held by
 `*this`.
 * [*Complexity:] Constant.
 * [*Exception safety:] nothrow.


     template< class Tag, class IteratorType >
     map_by<Tag>::iterator project(IteratorType iter);

     template< class Tag, class IteratorType >
     map_by<Tag>::const_iterator project(IteratorType iter) const

 * [*Requires: ] `Tag` is a valid user defined name of the bimap. `IteratorType`
 is a bimap view iterator. it is a valid iterator of some view of `*this`
 (i.e. does not refer to some other `bimap`.)
 * [*Effects:] Returns a reference to the map view tagged with `Tag` held by
 `*this`.
 * [*Complexity:] Constant.
 * [*Exception safety:] nothrow.


 [endsect]

 [section Serialization]

 A `bimap` can be archived and retrieved by means of __BOOST_SERIALIZATION__.
 Boost.Bimap does not expose a public serialisation interface, as this is
 provided by Boost.Serialization itself. Both regular and XML archives
 are supported.

 Each of the set specifications comprising a given `bimap` contributes its
 own preconditions as well as guarantees on the retrieved containers. In describing
 these, the following concepts are used. A type `T` is ['serializable]
 (resp. XML-serializable) if any object of type `T` can be saved to an output
 archive (XML archive) and later retrieved from an input archive (XML archive)
 associated to the same storage. If `x`' of type `T` is loaded from the serialization
 information saved from another object x, we say that x' is a ['restored copy] of x.
 Given a __SGI_BINARY_PREDICATE__ `Pred` over `(T, T)`, and objects `p` and `q` of
 type `Pred`, we say that `q` is ['serialization-compatible] with `p` if

 * `p(x,y) == q(x`'`,y`'`)`

 for every `x` and `y` of type `T` and `x`' and `y`' being restored copies of `x`
 and `y`, respectively.

 [blurb [*Operation:] saving of a `bimap b` to an output archive
 (XML archive) ar.]

 * [*Requires:] Value is serializable (XML-serializable). Additionally, each
 of the views of b can impose other requirements.
 * [*Exception safety:] Strong with respect to `b`. If an exception is thrown, ar
 may be left in an inconsistent state.

 [blurb [*Operation:] loading of a `bimap` m' from an input archive
 (XML archive) ar.]

 * [*Requires:] Value is serializable (XML-serializable). Additionally, each of
 the views of `b`' can impose other requirements.
 * [*Exception safety:] Basic. If an exception is thrown, ar may be left in an
 inconsistent state.

 [endsect]
 [endsect]

 [endsect]
	[/license

	Boost.Bimap

	Copyright (c) 2006-2007 Matias Capeletto

	Distributed under the Boost Software License, Version 1.0.
	(See accompanying file LICENSE_1_0.txt or copy at
	http://www.boost.org/LICENSE_1_0.txt)

	]

	[/ QuickBook Document version 1.4 ]

	[section Bimap Reference]

	[section View concepts]

	`bimap` instantiations comprise two side views and an view of the relation
	specified at compile time. Each view allows read-write access to the elements contained
	in a definite manner, mathing an STL container signature.

	Views are not isolated objects and so cannot be constructed on their
	own; rather they are an integral part of a `bimap`. The name of the view
	class implementation proper is never directly exposed to the user, who
	has access only to the associated view type specifier.

	Insertion and deletion of elements are always performed through the
	appropriate interface of any of the three views of the `bimap`; these
	operations do, however, have an impact on all other views as well: for
	instance, insertion through a given view may fail because there exists
	another view that forbids the operation in order to preserve its
	invariant (such as uniqueness of elements). The global operations
	performed jointly in the any view can be reduced to six primitives:

	* copying
	* insertion of an element
	* hinted insertion, where a pre-existing element is suggested in order to improve
	the efficiency of the operation
	* deletion of an element
	* replacement of the value of an element, which may trigger the
	rearrangement of this element in one or more views, or may forbid the
	replacement
	* modification of an element, and its subsequent
	rearrangement/banning by the various views

	The last two primitives deserve some further explanation: in order to
	guarantee the invariants associated to each view (e.g. some definite
	ordering) elements of a `bimap` are not mutable. To overcome this
	restriction, the views expose member functions for updating and
	modifying, which allows for the mutation of elements in a controlled
	fashion.

	[endsect]

	[#complexity_signature_explanation]

	[section Complexity signature]

	Some member functions of a view interface are implemented by global
	primitives from the above list. The complexity of these operations thus
	depends on all views of a given `bimap`, not just the currently used view.

	In order to establish complexity estimates, a view is characterised by
	its complexity signature, consisting of the following associated
	functions on the number of elements:

	* `c(n)`: copying
	* `i(n)`: insertion
	* `h(n)`: hinted insertion
	* `d(n)`: deletion
	* `r(n)`: replacement
	* `m(n)`: modifying

	If the collection type of the relation is `left_based` or `right_based`, and we use
	an `l` subscript to denote the left view and an `r` for the right view, then
	the insertion of an element in such a container is of complexity
	`O(i_l(n)+i_r(n))`, where n is the number of elements. If the collection type of
	relation is not side-based, then there is an additional term to add that
	is contributed by the collection type of relation view. Using `a` to denote the
	above view, the complexity of insertion will now be
	`O(i_l(n)+i_r(n)+i_a(n))`. To abbreviate the notation, we adopt the
	following definitions:

	* `C(n) = c_l(n) + c_r(n) [ + c_a(n) ]`
	* `I(n) = i_l(n) + i_r(n) [ + i_a(n) ]`
	* `H(n) = h_l(n) + h_r(n) [ + h_a(n) ]`
	* `D(n) = d_l(n) + d_r(n) [ + d_a(n) ]`
	* `R(n) = r_l(n) + r_r(n) [ + r_a(n) ]`
	* `M(n) = m_l(n) + m_r(n) [ + m_a(n) ]`

	[endsect]

	[section Set type specification]

	Set type specifiers are passed as instantiation arguments to `bimap` and
	provide the information needed to incorporate the corresponding views.
	Currently, Boost.Bimap provides the collection type specifiers. The ['side collection type]
	specifiers define the constraints of the two map views of the
	bimap. The ['collection type of relation] specifier defines the main set view
	constraints. If `left_based` (the default parameter) or `right_based` is
	used, then the collection type of relation will be based on the left or right
	collection type correspondingly.

	[table
	[[Side collection type ][Collection type of relation ][Include ]]
	[[`set_of` ][`set_of_relation` ][`boost/bimap/set_of.hpp` ]]
	[[`multiset_of` ][`multiset_of_relation` ][`boost/bimap/multiset_of.hpp` ]]
	[[`unordered_set_of` ][`unordered_set_of_relation` ][`boost/bimap/unordered_set_of.hpp` ]]
	[[`unordered_multiset_of` ][`unordered_multiset_of_relation`][`boost/bimap/unordered_multiset_of.hpp` ]]
	[[`list_of` ][`list_of_relation` ][`boost/bimap/list_of.hpp` ]]
	[[`vector_of` ][`vector_of_relation` ][`boost/bimap/vector_of.hpp` ]]
	[[`unconstrained_set_of` ][`unconstrained_set_of_relation` ][`boost/bimap/unconstrained_set_of.hpp` ]]
	[[ ][`left_based` ][`boost/bimap/bimap.hpp` ]]
	[[ ][`right_based` ][`boost/bimap/bimap.hpp` ]]
	]

	[endsect]

	[section Tags]

	Tags are just conventional types used as mnemonics for the types stored
	in a `bimap`. Boost.Bimap uses the tagged idiom to let the user specify
	this tags.

	[endsect]

	[section Header "boost/bimap/bimap.hpp" synopsis]

	namespace boost {
	namespace bimaps {

	template< class Type, typename Tag >
	struct tagged;

	// bimap template class

	template
	<
	class LeftCollectionType, class RightCollectionType,

	class AdditionalParameter_1 = detail::not_specified,
	class AdditionalParameter_2 = detail::not_specified
	>
	class bimap ``['- implementation defined { : public SetView } -]``
	{
	public:

	// Metadata

	typedef ``['-unspecified-]`` left_tag;
	typedef ``['-unspecified-]`` left_map;

	typedef ``['-unspecified-]`` right_tag;
	typedef ``['-unspecified-]`` right_map;

	// Shortcuts
	// typedef -side-_map::-type- -side-_-type-;

	typedef ``['-unspecified-]`` info_type;

	// Map views

	left_map left;
	right_map right;

	// Constructors

	bimap();

	template< class InputIterator >
	bimap(InputIterator first,InputIterator last);

	bimap(const bimap &);

	bimap& operator=(const bimap& b);

	// Projection of iterators

	template< class IteratorType >
	left_iterator project_left(IteratorType iter);

	template< class IteratorType >
	left_const_iterator project_left(IteratorType iter) const;

	template< class IteratorType >
	right_iterator project_right(IteratorType iter);

	template< class IteratorType >
	right_const_iterator project_right(IteratorType iter) const;

	template< class IteratorType >
	iterator project_up(IteratorType iter);

	template< class IteratorType >
	const_iterator project_up(IteratorType iter) const;

	// Support for tags

	template< class Tag >
	struct map_by;

	template< class Tag >
	map_by<Tag>::type by();

	template< class Tag >
	const map_by<Tag>::type & by() const;

	template< class Tag, class IteratorType >
	map_by<Tag>::iterator project(IteratorType iter);

	template< class Tag, class IteratorType >
	map_by<Tag>::const_iterator project(IteratorType iter) const

	};


	} // namespace bimap
	} // namespace boost


	[/
	// Metafunctions for a bimap

	template< class Tag, class Bimap > struct value_type_by;
	template< class Tag, class Bimap > struct key_type_by;
	template< class Tag, class Bimap > struct data_type_by;
	template< class Tag, class Bimap > struct iterator_type_by;
	template< class Tag, class Bimap > struct const_iterator_type_by;
	template< class Tag, class Bimap > struct reverse_iterator_type_by;
	template< class Tag, class Bimap > struct const_reverse_iterator_type_by;
	template< class Tag, class Bimap > struct local_iterator_type_by;
	template< class Tag, class Bimap > struct const_local_iterator_type_by;

	// Functions for a bimap

	template<class Tag, class Relation>
	result_of::map_by< Tag, Bimap>::type map_by(Bimap &);

	// Metafunctions for a relation

	template< class Tag, class Relation > struct value_type_of;
	template< class Tag, class Relation > struct pair_type_by;

	// Functions for a relation

	template<class Tag, class Relation>
	result_of::get< Tag, Relation>::type get(Relation &r);

	template<class Tag, class Relation>
	result_of::pair_by< Tag, Relation>::type pair_by(Relation &);

	]

	[endsect]

	[section Class template bimap]

	This is the main component of Boost.Bimap.

	[section Complexity]

	In the descriptions of the operations of `bimap`, we adopt the scheme
	outlined in the complexity signature section.

	[endsect]

	[section Instantiation types]

	`bimap` is instantiated with the following types:

	# LeftCollectionType and RightCollectionType are collection type specifications
	optionally tagged, or any type optionally tagged, in which case that
	side acts as a set.
	# AdditionalParameter_{1/2} can be any ordered subset of:
	* CollectionTypeOfRelation specification
	* Allocator

	[endsect]

	[section Nested types]

	left_tag, right_tag

	[: Tags for each side of the bimap. If the user has not specified any tag the
	tags default to `member_at::left` and `member_at::right`.
	]

	left_key_type, right_key_type

	[: Key type of each side. In a `bimap<A,B> ` `left_key_type` is `A` and
	`right_key_type` is `B`.
	If there are tags, it is better to use: `Bimap::map_by<Tag>::key_type`.
	]

	left_data_type, right_data_type

	[: Data type of each side. In a bimap<A,B> left_key_type is B and
	right_key_type is A.
	If there are tags, it is better to use: `Bimap::map_by<Tag>::data_type`.
	]

	left_value_type, right_value_type

	[: Value type used for the views.
	If there are tags, it is better to use: `Bimap::map_by<Tag>::value_type`.
	]


	left_iterator, right_iterator
	left_const_iterator, right_const_iterator

	[: Iterators of the views.
	If there are tags, it is better to use:
	`Bimap::map_by<Tag>::iterator` and
	`Bimap::map_by<Tag>::const_iterator`
	]


	left_map, right_map

	[: Map view type of each side.
	If there are tags, it is better to use:
	`Bimap::map_by<Tag>::type`.
	]

	[endsect]

	[section Constructors, copy and assignment]

	bimap();

	* [*Effects:] Constructs an empty `bimap`.
	* [*Complexity:] Constant.

	template<typename InputIterator>
	bimap(InputIterator first,InputIterator last);

	* [*Requires: ] `InputIterator` is a model of Input Iterator over elements of
	type `relation` or a type convertible to `relation`. last is reachable from `first`.
	* [*Effects:] Constructs an empty `bimap` and fills it with the elements in the range
	`[first,last)`. Insertion of each element may or may not succeed depending on
	acceptance by the collection types of the `bimap`.
	* [link complexity_signature_explanation
	[Complexity:]] O(mH(m)), where m is the number of elements in `[first,last)`.


	bimap(const bimap & x);

	* [*Effects:] Constructs a copy of x, copying its elements as well as its
	internal objects (key extractors, comparison objects, allocator.)
	* [Postconditions:] `this == x`. The order of the views of the `bimap`
	is preserved as well.
	* [Complexity:] O(x.size()log(x.size()) + C(x.size()))


	~bimap()

	* [*Effects:] Destroys the `bimap` and all the elements contained.
	The order in which the elements are destroyed is not specified.
	* [*Complexity:] O(n).


	bimap& operator=(const bimap& x);

	* [*Effects:] Replaces the elements and internal objects of the `bimap`
	with copies from x.
	* [Postconditions:] `this==x`. The order on the views of the `bimap`
	is preserved as well.
	* [Returns: ] `this`.
	* [Complexity:] O(n + x.size()log(x.size()) + C(x.size())).
	* [*Exception safety:] Strong, provided the copy and assignment operations
	of the types of `ctor_args_list` do not throw.

	[/
	allocator_type get_allocator() const;

	* [*Effects:] Returns a copy of the `allocator_type` object used to construct
	the `bimap`.
	* [*Complexity:] Constant.
	]

	[endsect]

	[#reference_projection_operations]

	[section Projection operations]

	Given a `bimap` with views v1 and v2, we say than an v1-iterator
	it1 and an v2-iterator it2 are equivalent if:

	* `it1 == i1.end()` AND `it2 == i2.end()`,
	* OR `it1` and `it2` point to the same element.


	template< class IteratorType >
	left_iterator project_left(IteratorType iter);

	template< class IteratorType >
	left_const_iterator project_left(IteratorType iter) const;

	* [*Requires:] `IteratorType` is a bimap view iterator. it is a
	valid iterator of some view of `*this` (i.e. does not refer to some other
	`bimap`.)
	* [*Effects:] Returns a left map view iterator equivalent to `it`.
	* [*Complexity:] Constant.
	* [*Exception safety:] nothrow.


	template< class IteratorType >
	right_iterator project_right(IteratorType iter);

	template< class IteratorType >
	right_const_iterator project_right(IteratorType iter) const;

	* [*Requires:] `IteratorType` is a bimap view iterator. it is a
	valid iterator of some view of `*this` (i.e. does not refer to some other
	`bimap`.)
	* [*Effects:] Returns a right map view iterator equivalent to `it`.
	* [*Complexity:] Constant.
	* [*Exception safety:] nothrow.


	template< class IteratorType >
	iterator project_up(IteratorType iter);

	template< class IteratorType >
	const_iterator project_up(IteratorType iter) const;

	* [*Requires:] `IteratorType` is a bimap view iterator. it is a
	valid iterator of some view of `*this` (i.e. does not refer to some other
	`bimap`.)
	* [*Effects:] Returns a collection of relations view iterator equivalent to `it`.
	* [*Complexity:] Constant.
	* [*Exception safety:] nothrow.

	[endsect]

	[#reference_support_for_used_defined_names]

	[section Support for user defined names]

	template< class Tag >
	struct map_by;

	* `map_by<Tag>::type` yields the type of the map view tagged with `Tag`.
	`map_by<Tag>::`['-type name-] is the same as `map_by<Tag>::type::`['-type name-].
	* [*Requires: ] `Tag` is a valid user defined name of the bimap.


	template< class Tag >
	map_by<Tag>::type by();

	template< class Tag >
	const map_by<Tag>::type & by() const;


	* [*Requires: ] `Tag` is a valid user defined name of the bimap.
	* [*Effects:] Returns a reference to the map view tagged with `Tag` held by
	`*this`.
	* [*Complexity:] Constant.
	* [*Exception safety:] nothrow.


	template< class Tag, class IteratorType >
	map_by<Tag>::iterator project(IteratorType iter);

	template< class Tag, class IteratorType >
	map_by<Tag>::const_iterator project(IteratorType iter) const

	* [*Requires: ] `Tag` is a valid user defined name of the bimap. `IteratorType`
	is a bimap view iterator. it is a valid iterator of some view of `*this`
	(i.e. does not refer to some other `bimap`.)
	* [*Effects:] Returns a reference to the map view tagged with `Tag` held by
	`*this`.
	* [*Complexity:] Constant.
	* [*Exception safety:] nothrow.


	[endsect]

	[section Serialization]

	A `bimap` can be archived and retrieved by means of __BOOST_SERIALIZATION__.
	Boost.Bimap does not expose a public serialisation interface, as this is
	provided by Boost.Serialization itself. Both regular and XML archives
	are supported.

	Each of the set specifications comprising a given `bimap` contributes its
	own preconditions as well as guarantees on the retrieved containers. In describing
	these, the following concepts are used. A type `T` is ['serializable]
	(resp. XML-serializable) if any object of type `T` can be saved to an output
	archive (XML archive) and later retrieved from an input archive (XML archive)
	associated to the same storage. If `x`' of type `T` is loaded from the serialization
	information saved from another object x, we say that x' is a ['restored copy] of x.
	Given a __SGI_BINARY_PREDICATE__ `Pred` over `(T, T)`, and objects `p` and `q` of
	type `Pred`, we say that `q` is ['serialization-compatible] with `p` if

	* `p(x,y) == q(x`'`,y`'`)`

	for every `x` and `y` of type `T` and `x`' and `y`' being restored copies of `x`
	and `y`, respectively.

	[blurb [*Operation:] saving of a `bimap b` to an output archive
	(XML archive) ar.]

	* [*Requires:] Value is serializable (XML-serializable). Additionally, each
	of the views of b can impose other requirements.
	* [*Exception safety:] Strong with respect to `b`. If an exception is thrown, ar
	may be left in an inconsistent state.

	[blurb [*Operation:] loading of a `bimap` m' from an input archive
	(XML archive) ar.]

	* [*Requires:] Value is serializable (XML-serializable). Additionally, each of
	the views of `b`' can impose other requirements.
	* [*Exception safety:] Basic. If an exception is thrown, ar may be left in an
	inconsistent state.

	[endsect]
	[endsect]

	[endsect]