boost_1_45_0/libs/iterator/doc/iterator_adaptor_tutorial.rst - nest-learning-thermostat/5.0/boost - Git at Google

 .. Copyright David Abrahams 2004. Use, modification and distribution is
 .. subject to 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)

 In this section we'll further refine the ``node_iter`` class
 template we developed in the |fac_tut|_.  If you haven't already
 read that material, you should go back now and check it out because
 we're going to pick up right where it left off.

 .. |fac_tut| replace:: ``iterator_facade`` tutorial
 .. _fac_tut: iterator_facade.html#tutorial-example

 .. sidebar:: ``node_base*`` really *is* an iterator

    It's not really a very interesting iterator, since ``node_base``
    is an abstract class: a pointer to a ``node_base`` just points
    at some base subobject of an instance of some other class, and
    incrementing a ``node_base*`` moves it past this base subobject
    to who-knows-where?  The most we can do with that incremented
    position is to compare another ``node_base*`` to it.  In other
    words, the original iterator traverses a one-element array.

 You probably didn't think of it this way, but the ``node_base*``
 object that underlies ``node_iterator`` is itself an iterator,
 just like all other pointers.  If we examine that pointer closely
 from an iterator perspective, we can see that it has much in common
 with the ``node_iterator`` we're building.  First, they share most
 of the same associated types (``value_type``, ``reference``,
 ``pointer``, and ``difference_type``).  Second, even some of the
 core functionality is the same: ``operator*`` and ``operator==`` on
 the ``node_iterator`` return the result of invoking the same
 operations on the underlying pointer, via the ``node_iterator``\ 's
 |dereference_and_equal|_).  The only real behavioral difference
 between ``node_base*`` and ``node_iterator`` can be observed when
 they are incremented: ``node_iterator`` follows the
 ``m_next`` pointer, while ``node_base*`` just applies an address offset.

 .. |dereference_and_equal| replace:: ``dereference`` and ``equal`` member functions
 .. _dereference_and_equal: iterator_facade.html#implementing-the-core-operations

 It turns out that the pattern of building an iterator on another
 iterator-like type (the ``Base`` [#base]_ type) while modifying
 just a few aspects of the underlying type's behavior is an
 extremely common one, and it's the pattern addressed by
 ``iterator_adaptor``.  Using ``iterator_adaptor`` is very much like
 using ``iterator_facade``, but because iterator_adaptor tries to
 mimic as much of the ``Base`` type's behavior as possible, we
 neither have to supply a ``Value`` argument, nor implement any core
 behaviors other than ``increment``.  The implementation of
 ``node_iter`` is thus reduced to::

   template <class Value>
   class node_iter
     : public boost::iterator_adaptor<
           node_iter<Value>                // Derived
         , Value*                          // Base
         , boost::use_default              // Value
         , boost::forward_traversal_tag    // CategoryOrTraversal
       >
   {
    private:
       struct enabler {};  // a private type avoids misuse

    public:
       node_iter()
         : node_iter::iterator_adaptor_(0) {}

       explicit node_iter(Value* p)
         : node_iter::iterator_adaptor_(p) {}

       template <class OtherValue>
       node_iter(
           node_iter<OtherValue> const& other
         , typename boost::enable_if<
               boost::is_convertible<OtherValue*,Value*>
             , enabler
           >::type = enabler()
       )
         : node_iter::iterator_adaptor_(other.base()) {}

    private:
       friend class boost::iterator_core_access;
       void increment() { this->base_reference() = this->base()->next(); }
   };

 Note the use of ``node_iter::iterator_adaptor_`` here: because
 ``iterator_adaptor`` defines a nested ``iterator_adaptor_`` type
 that refers to itself, that gives us a convenient way to refer to
 the complicated base class type of ``node_iter<Value>``. [Note:
 this technique is known not to work with Borland C++ 5.6.4 and
 Metrowerks CodeWarrior versions prior to 9.0]

 You can see an example program that exercises this version of the
 node iterators `here`__.

 __ ../example/node_iterator3.cpp

 In the case of ``node_iter``, it's not very compelling to pass
 ``boost::use_default`` as ``iterator_adaptor``\ 's ``Value``
 argument; we could have just passed ``node_iter``\ 's ``Value``
 along to ``iterator_adaptor``, and that'd even be shorter!  Most
 iterator class templates built with ``iterator_adaptor`` are
 parameterized on another iterator type, rather than on its
 ``value_type``.  For example, ``boost::reverse_iterator`` takes an
 iterator type argument and reverses its direction of traversal,
 since the original iterator and the reversed one have all the same
 associated types, ``iterator_adaptor``\ 's delegation of default
 types to its ``Base`` saves the implementor of
 ``boost::reverse_iterator`` from writing:

 .. parsed-literal::

    std::iterator_traits<Iterator>::*some-associated-type*

 at least four times.

 We urge you to review the documentation and implementations of
 |reverse_iterator|_ and the other Boost `specialized iterator
 adaptors`__ to get an idea of the sorts of things you can do with
 ``iterator_adaptor``.  In particular, have a look at
 |transform_iterator|_, which is perhaps the most straightforward
 adaptor, and also |counting_iterator|_, which demonstrates that
 ``iterator_adaptor``\ 's ``Base`` type needn't be an iterator.

 .. |reverse_iterator| replace:: ``reverse_iterator``
 .. _reverse_iterator: reverse_iterator.html

 .. |counting_iterator| replace:: ``counting_iterator``
 .. _counting_iterator: counting_iterator.html

 .. |transform_iterator| replace:: ``transform_iterator``
 .. _transform_iterator: transform_iterator.html

 __ index.html#specialized-adaptors
	.. Copyright David Abrahams 2004. Use, modification and distribution is
	.. subject to 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)

	In this section we'll further refine the ``node_iter`` class
	template we developed in the \|fac_tut\|_. If you haven't already
	read that material, you should go back now and check it out because
	we're going to pick up right where it left off.

	.. \|fac_tut\| replace:: ``iterator_facade`` tutorial
	.. _fac_tut: iterator_facade.html#tutorial-example

	.. sidebar:: ``node_base`` really is* an iterator

	It's not really a very interesting iterator, since ``node_base``
	is an abstract class: a pointer to a ``node_base`` just points
	at some base subobject of an instance of some other class, and
	incrementing a ``node_base*`` moves it past this base subobject
	to who-knows-where? The most we can do with that incremented
	position is to compare another ``node_base*`` to it. In other
	words, the original iterator traverses a one-element array.

	You probably didn't think of it this way, but the ``node_base*``
	object that underlies ``node_iterator`` is itself an iterator,
	just like all other pointers. If we examine that pointer closely
	from an iterator perspective, we can see that it has much in common
	with the ``node_iterator`` we're building. First, they share most
	of the same associated types (``value_type``, ``reference``,
	``pointer``, and ``difference_type``). Second, even some of the
	core functionality is the same: ``operator*`` and ``operator==`` on
	the ``node_iterator`` return the result of invoking the same
	operations on the underlying pointer, via the ``node_iterator``\ 's
	\|dereference_and_equal\|_). The only real behavioral difference
	between ``node_base*`` and ``node_iterator`` can be observed when
	they are incremented: ``node_iterator`` follows the
	``m_next`` pointer, while ``node_base*`` just applies an address offset.

	.. \|dereference_and_equal\| replace:: ``dereference`` and ``equal`` member functions
	.. _dereference_and_equal: iterator_facade.html#implementing-the-core-operations

	It turns out that the pattern of building an iterator on another
	iterator-like type (the ``Base`` [#base]_ type) while modifying
	just a few aspects of the underlying type's behavior is an
	extremely common one, and it's the pattern addressed by
	``iterator_adaptor``. Using ``iterator_adaptor`` is very much like
	using ``iterator_facade``, but because iterator_adaptor tries to
	mimic as much of the ``Base`` type's behavior as possible, we
	neither have to supply a ``Value`` argument, nor implement any core
	behaviors other than ``increment``. The implementation of
	``node_iter`` is thus reduced to::

	template <class Value>
	class node_iter
	: public boost::iterator_adaptor<
	node_iter<Value> // Derived
	, Value* // Base
	, boost::use_default // Value
	, boost::forward_traversal_tag // CategoryOrTraversal
	>
	{
	private:
	struct enabler {}; // a private type avoids misuse

	public:
	node_iter()
	: node_iter::iterator_adaptor_(0) {}

	explicit node_iter(Value* p)
	: node_iter::iterator_adaptor_(p) {}

	template <class OtherValue>
	node_iter(
	node_iter<OtherValue> const& other
	, typename boost::enable_if<
	boost::is_convertible<OtherValue,Value>
	, enabler
	>::type = enabler()
	)
	: node_iter::iterator_adaptor_(other.base()) {}

	private:
	friend class boost::iterator_core_access;
	void increment() { this->base_reference() = this->base()->next(); }
	};

	Note the use of ``node_iter::iterator_adaptor_`` here: because
	``iterator_adaptor`` defines a nested ``iterator_adaptor_`` type
	that refers to itself, that gives us a convenient way to refer to
	the complicated base class type of ``node_iter<Value>``. [Note:
	this technique is known not to work with Borland C++ 5.6.4 and
	Metrowerks CodeWarrior versions prior to 9.0]

	You can see an example program that exercises this version of the
	node iterators `here`__.

	__ ../example/node_iterator3.cpp

	In the case of ``node_iter``, it's not very compelling to pass
	``boost::use_default`` as ``iterator_adaptor``\ 's ``Value``
	argument; we could have just passed ``node_iter``\ 's ``Value``
	along to ``iterator_adaptor``, and that'd even be shorter! Most
	iterator class templates built with ``iterator_adaptor`` are
	parameterized on another iterator type, rather than on its
	``value_type``. For example, ``boost::reverse_iterator`` takes an
	iterator type argument and reverses its direction of traversal,
	since the original iterator and the reversed one have all the same
	associated types, ``iterator_adaptor``\ 's delegation of default
	types to its ``Base`` saves the implementor of
	``boost::reverse_iterator`` from writing:

	.. parsed-literal::

	std::iterator_traits<Iterator>::some-associated-type

	at least four times.

	We urge you to review the documentation and implementations of
	\|reverse_iterator\|_ and the other Boost `specialized iterator
	adaptors`__ to get an idea of the sorts of things you can do with
	``iterator_adaptor``. In particular, have a look at
	\|transform_iterator\|_, which is perhaps the most straightforward
	adaptor, and also \|counting_iterator\|_, which demonstrates that
	``iterator_adaptor``\ 's ``Base`` type needn't be an iterator.

	.. \|reverse_iterator\| replace:: ``reverse_iterator``
	.. _reverse_iterator: reverse_iterator.html

	.. \|counting_iterator\| replace:: ``counting_iterator``
	.. _counting_iterator: counting_iterator.html

	.. \|transform_iterator\| replace:: ``transform_iterator``
	.. _transform_iterator: transform_iterator.html

	__ index.html#specialized-adaptors