boost_1_45_0/libs/iterator/doc/quickbook/adaptor.qbk - nest-learning-thermostat/5.1.3/boost - Git at Google


 [section:adaptor Iterator Adaptor]

 The `iterator_adaptor` class template adapts some `Base` [#base]_
 type to create a new iterator.  Instantiations of `iterator_adaptor`
 are derived from a corresponding instantiation of `iterator_facade`
 and implement the core behaviors in terms of the `Base` type. In
 essence, `iterator_adaptor` merely forwards all operations to an
 instance of the `Base` type, which it stores as a member.

 .. [#base] The term "Base" here does not refer to a base class and is
    not meant to imply the use of derivation. We have followed the lead
    of the standard library, which provides a base() function to access
    the underlying iterator object of a `reverse_iterator` adaptor.

 The user of `iterator_adaptor` creates a class derived from an
 instantiation of `iterator_adaptor` and then selectively
 redefines some of the core member functions described in the
 `iterator_facade` core requirements table. The `Base` type need
 not meet the full requirements for an iterator; it need only
 support the operations used by the core interface functions of
 `iterator_adaptor` that have not been redefined in the user's
 derived class.

 Several of the template parameters of `iterator_adaptor` default
 to `use_default`. This allows the
 user to make use of a default parameter even when she wants to
 specify a parameter later in the parameter list.  Also, the
 defaults for the corresponding associated types are somewhat
 complicated, so metaprogramming is required to compute them, and
 `use_default` can help to simplify the implementation.  Finally,
 the identity of the `use_default` type is not left unspecified
 because specification helps to highlight that the `Reference`
 template parameter may not always be identical to the iterator's
 `reference` type, and will keep users from making mistakes based on
 that assumption.

 [section:adaptor_reference Reference]

 [h2 Synopsis]

   template <
       class Derived
     , class Base
     , class Value               = use_default
     , class CategoryOrTraversal = use_default
     , class Reference           = use_default
     , class Difference = use_default
   >
   class iterator_adaptor
     : public iterator_facade<Derived, *V'*, *C'*, *R'*, *D'*> // see details
   {
       friend class iterator_core_access;
    public:
       iterator_adaptor();
       explicit iterator_adaptor(Base const& iter);
       typedef Base base_type;
       Base const& base() const;
    protected:
       typedef iterator_adaptor iterator_adaptor\_;
       Base const& base_reference() const;
       Base& base_reference();
    private: // Core iterator interface for iterator_facade.
       typename iterator_adaptor::reference dereference() const;

       template <
       class OtherDerived, class OtherIterator, class V, class C, class R, class D
       >
       bool equal(iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& x) const;

       void advance(typename iterator_adaptor::difference_type n);
       void increment();
       void decrement();

       template <
           class OtherDerived, class OtherIterator, class V, class C, class R, class D
       >
       typename iterator_adaptor::difference_type distance_to(
           iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& y) const;

    private:
       Base m_iterator; // exposition only
   };

 __ base_parameters_

 .. _requirements:

 [h2 Requirements]

 `static_cast<Derived*>(iterator_adaptor*)` shall be well-formed.
 The `Base` argument shall be Assignable and Copy Constructible.


 .. _base_parameters:

 [h2 Base Class Parameters]

 The *V'*, *C'*, *R'*, and *D'* parameters of the `iterator_facade`
 used as a base class in the summary of `iterator_adaptor`
 above are defined as follows:

 [pre
    *V'* = if (Value is use_default)
              return iterator_traits<Base>::value_type
          else
              return Value

    *C'* = if (CategoryOrTraversal is use_default)
              return iterator_traversal<Base>::type
          else
              return CategoryOrTraversal

    *R'* = if (Reference is use_default)
              if (Value is use_default)
                  return iterator_traits<Base>::reference
              else
                  return Value&
          else
              return Reference

    *D'* = if (Difference is use_default)
              return iterator_traits<Base>::difference_type
          else
              return Difference
 ]

 [h2 Operations]

 [h3 Public]


   iterator_adaptor();

 [*Requires:] The `Base` type must be Default Constructible.\n
 [*Returns:] An instance of `iterator_adaptor` with
     `m_iterator` default constructed.


   explicit iterator_adaptor(Base const& iter);

 [*Returns:] An instance of `iterator_adaptor` with
     `m_iterator` copy constructed from `iter`.

   Base const& base() const;

 [*Returns:] `m_iterator`


 [h3 Protected]

   Base const& base_reference() const;

 [*Returns:] A const reference to `m_iterator`.


   Base& base_reference();

 [*Returns:] A non-const reference to `m_iterator`.

 [h3 Private]

   typename iterator_adaptor::reference dereference() const;

 [*Returns:] `*m_iterator`


   template <
   class OtherDerived, class OtherIterator, class V, class C, class R, class D
   >
   bool equal(iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& x) const;

 [*Returns:] `m_iterator == x.base()`


   void advance(typename iterator_adaptor::difference_type n);

 [*Effects:] `m_iterator += n;`

   void increment();

 [*Effects:] `++m_iterator;`

   void decrement();

 [*Effects:] `--m_iterator;`


   template <
       class OtherDerived, class OtherIterator, class V, class C, class R, class D
   >
   typename iterator_adaptor::difference_type distance_to(
       iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& y) const;

 [*Returns:] `y.base() - m_iterator`

 [endsect]

 [section:adaptor_tutorial Tutorial]

 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

 [blurb [*`node_base*` really *is* an iterator]\n\n
   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
 [@../example/node_iterator3.cpp `here`].


 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:

    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


 [endsect]

 [endsect]

	[section:adaptor Iterator Adaptor]

	The `iterator_adaptor` class template adapts some `Base` [#base]_
	type to create a new iterator. Instantiations of `iterator_adaptor`
	are derived from a corresponding instantiation of `iterator_facade`
	and implement the core behaviors in terms of the `Base` type. In
	essence, `iterator_adaptor` merely forwards all operations to an
	instance of the `Base` type, which it stores as a member.

	.. [#base] The term "Base" here does not refer to a base class and is
	not meant to imply the use of derivation. We have followed the lead
	of the standard library, which provides a base() function to access
	the underlying iterator object of a `reverse_iterator` adaptor.

	The user of `iterator_adaptor` creates a class derived from an
	instantiation of `iterator_adaptor` and then selectively
	redefines some of the core member functions described in the
	`iterator_facade` core requirements table. The `Base` type need
	not meet the full requirements for an iterator; it need only
	support the operations used by the core interface functions of
	`iterator_adaptor` that have not been redefined in the user's
	derived class.

	Several of the template parameters of `iterator_adaptor` default
	to `use_default`. This allows the
	user to make use of a default parameter even when she wants to
	specify a parameter later in the parameter list. Also, the
	defaults for the corresponding associated types are somewhat
	complicated, so metaprogramming is required to compute them, and
	`use_default` can help to simplify the implementation. Finally,
	the identity of the `use_default` type is not left unspecified
	because specification helps to highlight that the `Reference`
	template parameter may not always be identical to the iterator's
	`reference` type, and will keep users from making mistakes based on
	that assumption.

	[section:adaptor_reference Reference]

	[h2 Synopsis]

	template <
	class Derived
	, class Base
	, class Value = use_default
	, class CategoryOrTraversal = use_default
	, class Reference = use_default
	, class Difference = use_default
	>
	class iterator_adaptor
	: public iterator_facade<Derived, V', C', R', D'> // see details
	{
	friend class iterator_core_access;
	public:
	iterator_adaptor();
	explicit iterator_adaptor(Base const& iter);
	typedef Base base_type;
	Base const& base() const;
	protected:
	typedef iterator_adaptor iterator_adaptor\_;
	Base const& base_reference() const;
	Base& base_reference();
	private: // Core iterator interface for iterator_facade.
	typename iterator_adaptor::reference dereference() const;

	template <
	class OtherDerived, class OtherIterator, class V, class C, class R, class D
	>
	bool equal(iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& x) const;

	void advance(typename iterator_adaptor::difference_type n);
	void increment();
	void decrement();

	template <
	class OtherDerived, class OtherIterator, class V, class C, class R, class D
	>
	typename iterator_adaptor::difference_type distance_to(
	iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& y) const;

	private:
	Base m_iterator; // exposition only
	};

	__ base_parameters_

	.. _requirements:

	[h2 Requirements]

	`static_cast<Derived>(iterator_adaptor)` shall be well-formed.
	The `Base` argument shall be Assignable and Copy Constructible.


	.. _base_parameters:

	[h2 Base Class Parameters]

	The V', C', R', and D' parameters of the `iterator_facade`
	used as a base class in the summary of `iterator_adaptor`
	above are defined as follows:

	[pre
	V' = if (Value is use_default)
	return iterator_traits<Base>::value_type
	else
	return Value

	C' = if (CategoryOrTraversal is use_default)
	return iterator_traversal<Base>::type
	else
	return CategoryOrTraversal

	R' = if (Reference is use_default)
	if (Value is use_default)
	return iterator_traits<Base>::reference
	else
	return Value&
	else
	return Reference

	D' = if (Difference is use_default)
	return iterator_traits<Base>::difference_type
	else
	return Difference
	]

	[h2 Operations]

	[h3 Public]


	iterator_adaptor();

	[*Requires:] The `Base` type must be Default Constructible.\n
	[*Returns:] An instance of `iterator_adaptor` with
	`m_iterator` default constructed.


	explicit iterator_adaptor(Base const& iter);

	[*Returns:] An instance of `iterator_adaptor` with
	`m_iterator` copy constructed from `iter`.

	Base const& base() const;

	[*Returns:] `m_iterator`


	[h3 Protected]

	Base const& base_reference() const;

	[*Returns:] A const reference to `m_iterator`.


	Base& base_reference();

	[*Returns:] A non-const reference to `m_iterator`.

	[h3 Private]

	typename iterator_adaptor::reference dereference() const;

	[Returns:] `m_iterator`


	template <
	class OtherDerived, class OtherIterator, class V, class C, class R, class D
	>
	bool equal(iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& x) const;

	[*Returns:] `m_iterator == x.base()`


	void advance(typename iterator_adaptor::difference_type n);

	[*Effects:] `m_iterator += n;`

	void increment();

	[*Effects:] `++m_iterator;`

	void decrement();

	[*Effects:] `--m_iterator;`


	template <
	class OtherDerived, class OtherIterator, class V, class C, class R, class D
	>
	typename iterator_adaptor::difference_type distance_to(
	iterator_adaptor<OtherDerived, OtherIterator, V, C, R, D> const& y) const;

	[*Returns:] `y.base() - m_iterator`

	[endsect]

	[section:adaptor_tutorial Tutorial]

	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

	[blurb [`node_base` really is an iterator]\n\n
	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
	[@../example/node_iterator3.cpp `here`].


	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:

	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


	[endsect]

	[endsect]