WSJT-X/boost/libs/iterator/doc/quickbook/iterator.qbk

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[library Boost.Iterator
[/ version 1.0.1]
[quickbook 1.6]
[authors [Abrahams, David], [Siek, Jeremy], [Witt, Thomas]]
[copyright 2003 2005 David Abrahams Jeremy Siek Thomas Witt]
[category iterator]
[id iterator]
[dirname iterator]
[purpose
]
[license
Distributed under the Boost Software License, Version 1.0.
(See accompanying file LICENSE_1_0.txt or copy at
<ulink url="http://www.boost.org/LICENSE_1_0.txt">
http://www.boost.org/LICENSE_1_0.txt
</ulink>)
]
]
[/ QuickBook Document version 1.0 ]
[/ Images ]
[def _note_ [$images/note.png]]
[def _alert_ [$images/caution.png]]
[def _detail_ [$images/note.png]]
[def _tip_ [$images/tip.png]]
[/ Links ]
[def _iterator_ [@../../libs/iterator/doc/index.html Boost.Iterator]]
[section:intro Introduction]
[def _concepts_ [@http://www.boost.org/more/generic_programming.html#concept concepts]]
The Boost Iterator Library contains two parts. The first
is a system of _concepts_ which extend the C++ standard
iterator requirements. The second is a framework of
components for building iterators based on these
extended concepts and includes several useful iterator
adaptors. The extended iterator concepts have been
carefully designed so that old-style iterators
can fit in the new concepts and so that new-style
iterators will be compatible with old-style algorithms,
though algorithms may need to be updated if they want to
take full advantage of the new-style iterator
capabilities. Several components of this library have
been accepted into the C++ standard technical report.
The components of the Boost Iterator Library replace the
older Boost Iterator Adaptor Library.
[h2 New-Style Iterators]
[def _N1185_ [@http://www.gotw.ca/publications/N1185.pdf N1185]]
[def _N1211_ [@http://www.gotw.ca/publications/N1211.pdf N1211]]
[def _GOTW_50_ [@http://www.gotw.ca/gotw/050.htm Guru of the Week]]
The iterator categories defined in C++98 are extremely limiting
because they bind together two orthogonal concepts: traversal and
element access. For example, because a random access iterator is
required to return a reference (and not a proxy) when dereferenced,
it is impossible to capture the capabilities of
`vector<bool>::iterator` using the C++98 categories. This is the
infamous "`vector<bool>` is not a container, and its iterators
aren't random access iterators", debacle about which Herb Sutter
wrote two papers for the standards comittee (_N1185_ and _N1211_),
and a _GOTW_50_. New-style iterators go well beyond
patching up `vector<bool>`, though: there are lots of other
iterators already in use which can't be adequately represented by
the existing concepts. For details about the new iterator
concepts, see our [@./new-iter-concepts.html Standard Proposal for New-Style Iterators].
[h2 Iterator Facade and Adaptor]
[def _facade_ [@./iterator_facade.html facade]]
[def _adaptor_ [@./iterator_adaptor.html adaptor]]
Writing standard-conforming iterators is tricky, but the need comes
up often. In order to ease the implementation of new iterators,
the Boost.Iterator library provides the _facade_ class template,
which implements many useful defaults and compile-time checks
designed to help the iterator author ensure that his iterator is
correct.
It is also common to define a new iterator that is similar to some
underlying iterator or iterator-like type, but that modifies some
aspect of the underlying type's behavior. For that purpose, the
library supplies the _adaptor_ class template, which is specially
designed to take advantage of as much of the underlying type's
behavior as possible.
Both _facade_ and _adaptor_ as well as many of the `specialized
adaptors`_ mentioned below have been proposed for standardization
([@./facade-and-adaptor.html Standard Proposal For Iterator Facade and Adaptor]).
[h2 Specialized Adaptors]
The iterator library supplies a useful suite of standard-conforming
iterator templates based on the Boost [link
iterator.intro.iterator_facade_and_adaptor iterator facade and adaptor]
templates.
[def _counting_ [@./counting_iterator.html `counting_iterator`]]
[def _filter_ [@./filter_iterator.html `filter_iterator`]]
[def _function_ [@./function_output_iterator.html `function_output_iterator`]]
[def _indirect_ [@./indirect_iterator.html `indirect_iterator`]]
[def _permutation_ [@./permutation_iterator.html `permutation_iterator`]]
[def _reverse_ [@./reverse_iterator.html `reverse_iterator`]]
[def _shared_ [@./shared_container_iterator.html `shared_container_iterator`]]
[def _transform_ [@./transform_iterator.html `transform_iterator`]]
[def _zip_ [@./zip_iterator.html `zip_iterator`]]
[def _shared_ptr_ [@../../smart_ptr/shared_ptr.htm `shared_ptr`]]
* _counting_: an iterator over a sequence of consecutive values.
Implements a "lazy sequence"
* _filter_: an iterator over the subset of elements of some
sequence which satisfy a given predicate
* _function_: an output iterator wrapping a unary function
object; each time an element is written into the dereferenced
iterator, it is passed as a parameter to the function object.
* _indirect_: an iterator over the objects *pointed-to* by the
elements of some sequence.
* _permutation_: an iterator over the elements of some random-access
sequence, rearranged according to some sequence of integer indices.
* _reverse_: an iterator which traverses the elements of some
bidirectional sequence in reverse. Corrects many of the
shortcomings of C++98's ``std::reverse_iterator``.
* _shared_: an iterator over elements of a container whose
lifetime is maintained by a _shared_ptr_ stored in the iterator.
* _transform_: an iterator over elements which are the result of
applying some functional transformation to the elements of an
underlying sequence. This component also replaces the old
``projection_iterator_adaptor``.
* _zip_: an iterator over tuples of the elements at corresponding
positions of heterogeneous underlying iterators.
[h2 Iterator Utilities]
[h3 Traits]
[def _pointee_ [@./pointee.html `pointee.hpp`]]
[def _iterator_traits_ [@./iterator_traits.html `iterator_traits.hpp`]]
[def _interoperable_ [@./interoperable.html `interoperable.hpp`]]
[def _MPL_ [@../../mpl/doc/index.html [*MPL]]]
* _pointee_: Provides the capability to deduce the referent types
of pointers, smart pointers and iterators in generic code. Used
in _indirect_.
* _iterator_traits_: Provides _MPL_ compatible metafunctions which
retrieve an iterator's traits. Also corrects for the deficiencies
of broken implementations of `std::iterator_traits`.
[\ * |interoperable|_ (PDF__): Provides an _MPL_ compatible metafunction for
testing iterator interoperability
]
[h3 Testing and Concept Checking]
[def _iterator_concepts_ [@./iterator_concepts.html `iterator_concepts.hpp`]]
[def _iterator_archetypes_ [@./iterator_archetypes.html `iterator_archetypes.hpp`]]
* _iterator_concepts_: Concept checking classes for the new iterator concepts.
* _iterator_archetypes_: Concept archetype classes for the new iterators concepts.
[endsect]
[include concepts.qbk]
[section:generic Generic Iterators]
[include facade.qbk]
[include adaptor.qbk]
[endsect]
[include specialized_adaptors.qbk]
[section:utilities Utilities]
[include archetypes.qbk]
[include concept_checking.qbk]
[include traits.qbk]
[include utilities.qbk]
[endsect]
[section:upgrading Upgrading from the old Boost Iterator Adaptor Library]
[def _type_generator_ [@http://www.boost.org/more/generic_programming.html#type_generator type generator]]
If you have been using the old Boost Iterator Adaptor library to
implement iterators, you probably wrote a `Policies` class which
captures the core operations of your iterator. In the new library
design, you'll move those same core operations into the body of the
iterator class itself. If you were writing a family of iterators,
you probably wrote a _type_generator_ to build the
`iterator_adaptor` specialization you needed; in the new library
design you don't need a type generator (though may want to keep it
around as a compatibility aid for older code) because, due to the
use of the Curiously Recurring Template Pattern (CRTP) [Cop95]_,
you can now define the iterator class yourself and acquire
functionality through inheritance from `iterator_facade` or
`iterator_adaptor`. As a result, you also get much finer control
over how your iterator works: you can add additional constructors,
or even override the iterator functionality provided by the
library.
If you're looking for the old `projection_iterator` component,
its functionality has been merged into _transform_iterator_: as
long as the function object's `result_type` (or the `Reference`
template argument, if explicitly specified) is a true reference
type, _transform_iterator_ will behave like
`projection_iterator` used to.
[endsect]
[section:history History]
In 2000 Dave Abrahams was writing an iterator for a container of
pointers, which would access the pointed-to elements when
dereferenced. Naturally, being a library writer, he decided to
generalize the idea and the Boost Iterator Adaptor library was born.
Dave was inspired by some writings of Andrei Alexandrescu and chose a
policy based design (though he probably didn't capture Andrei's idea
very well - there was only one policy class for all the iterator's
orthogonal properties). Soon Jeremy Siek realized he would need the
library and they worked together to produce a "Boostified" version,
which was reviewed and accepted into the library. They wrote a paper
and made several important revisions of the code.
Eventually, several shortcomings of the older library began to make
the need for a rewrite apparent. Dave and Jeremy started working
at the Santa Cruz C++ committee meeting in 2002, and had quickly
generated a working prototype. At the urging of Mat Marcus, they
decided to use the GenVoca/CRTP pattern approach, and moved the
policies into the iterator class itself. Thomas Witt expressed
interest and became the voice of strict compile-time checking for
the project, adding uses of the SFINAE technique to eliminate false
converting constructors and operators from the overload set. He
also recognized the need for a separate `iterator_facade`, and
factored it out of `iterator_adaptor`. Finally, after a
near-complete rewrite of the prototype, they came up with the
library you see today.
[:\[Coplien, 1995\] Coplien, J., Curiously Recurring Template
Patterns, C++ Report, February 1995, pp. 24-27.]
[endsect]