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


 [section:reverse Reverse Iterator]

 The reverse iterator adaptor iterates through the adapted iterator
 range in the opposite direction.

 [h2 Example]

 The following example prints an array of characters in reverse order
 using `reverse_iterator`.


     char letters_[] = "hello world!";
     const int N = sizeof(letters_)/sizeof(char) - 1;
     typedef char* base_iterator;
     base_iterator letters(letters_);
     std::cout << "original sequence of letters:\t\t\t" << letters_ << std::endl;

     boost::reverse_iterator<base_iterator>
       reverse_letters_first(letters + N),
       reverse_letters_last(letters);

     std::cout << "sequence in reverse order:\t\t\t";
     std::copy(reverse_letters_first, reverse_letters_last,
               std::ostream_iterator<char>(std::cout));
     std::cout << std::endl;

     std::cout << "sequence in double-reversed (normal) order:\t";
     std::copy(boost::make_reverse_iterator(reverse_letters_last),
               boost::make_reverse_iterator(reverse_letters_first),
               std::ostream_iterator<char>(std::cout));
     std::cout << std::endl;


 The output is:

     original sequence of letters:                   hello world!
     sequence in reverse order:                      !dlrow olleh
     sequence in double-reversed (normal) order:     hello world!


 The source code for this example can be found
 [@../example/reverse_iterator_example.cpp here].

 [h2 Reference]

 [h3 Synopsis]

   template <class Iterator>
   class reverse_iterator
   {
   public:
     typedef iterator_traits<Iterator>::value_type value_type;
     typedef iterator_traits<Iterator>::reference reference;
     typedef iterator_traits<Iterator>::pointer pointer;
     typedef iterator_traits<Iterator>::difference_type difference_type;
     typedef /* see below */ iterator_category;

     reverse_iterator() {}
     explicit reverse_iterator(Iterator x) ;

     template<class OtherIterator>
     reverse_iterator(
         reverse_iterator<OtherIterator> const& r
       , typename enable_if_convertible<OtherIterator, Iterator>::type* = 0 // exposition
     );
     Iterator const& base() const;
     reference operator*() const;
     reverse_iterator& operator++();
     reverse_iterator& operator--();
   private:
     Iterator m_iterator; // exposition
   };


 If `Iterator` models Random Access Traversal Iterator and Readable
 Lvalue Iterator, then `iterator_category` is convertible to
 `random_access_iterator_tag`. Otherwise, if
 `Iterator` models Bidirectional Traversal Iterator and Readable
 Lvalue Iterator, then `iterator_category` is convertible to
 `bidirectional_iterator_tag`. Otherwise, `iterator_category` is
 convertible to `input_iterator_tag`.

 [h3 Requirements]

 `Iterator` must be a model of Bidirectional Traversal Iterator.  The
 type `iterator_traits<Iterator>::reference` must be the type of
 `*i`, where `i` is an object of type `Iterator`.

 [h3 Concepts]

 A specialization of `reverse_iterator` models the same iterator
 traversal and iterator access concepts modeled by its `Iterator`
 argument.  In addition, it may model old iterator concepts
 specified in the following table:

 [table Categories
   [[If `I` models                 ][then `reverse_iterator<I>` models]]
   [[Readable Lvalue Iterator, Bidirectional Traversal Iterator][Bidirectional Iterator]]
   [[Writable Lvalue Iterator, Bidirectional Traversal Iterator][Mutable Bidirectional Iterator]]
   [[Readable Lvalue Iterator, Random Access Traversal Iterator][Random Access Iterator]]
   [[Writable Lvalue Iterator, Random Access Traversal Iterator][Mutable Random Access Iterator]]
 ]

 `reverse_iterator<X>` is interoperable with
 `reverse_iterator<Y>` if and only if `X` is interoperable with
 `Y`.

 [h3 Operations]

 In addition to the operations required by the concepts modeled by
 `reverse_iterator`, `reverse_iterator` provides the following
 operations.

   reverse_iterator();

 [*Requires: ] `Iterator` must be Default Constructible.\n
 [*Effects: ] Constructs an instance of `reverse_iterator` with `m_iterator`
   default constructed.

   explicit reverse_iterator(Iterator x);

 [*Effects: ] Constructs an instance of `reverse_iterator` with
     `m_iterator` copy constructed from `x`.


     template<class OtherIterator>
     reverse_iterator(
         reverse_iterator<OtherIterator> const& r
       , typename enable_if_convertible<OtherIterator, Iterator>::type* = 0 // exposition
     );

 [*Requires: ] `OtherIterator` is implicitly convertible to `Iterator`.\n
 [*Effects: ] Constructs instance of `reverse_iterator` whose
     `m_iterator` subobject is constructed from `y.base()`.


   Iterator const& base() const;

 [*Returns: ] `m_iterator`


   reference operator*() const;

 [*Effects: ]  Iterator tmp = m_iterator; return *--tmp;


   reverse_iterator& operator++();

 [*Effects: ] `--m_iterator`\n
 [*Returns: ] `*this`

   reverse_iterator& operator--();

 [*Effects: ] `++m_iterator`\n
 [*Returns: ] `*this`

 [endsect]

	[section:reverse Reverse Iterator]

	The reverse iterator adaptor iterates through the adapted iterator
	range in the opposite direction.

	[h2 Example]

	The following example prints an array of characters in reverse order
	using `reverse_iterator`.


	char letters_[] = "hello world!";
	const int N = sizeof(letters_)/sizeof(char) - 1;
	typedef char* base_iterator;
	base_iterator letters(letters_);
	std::cout << "original sequence of letters:\t\t\t" << letters_ << std::endl;

	boost::reverse_iterator<base_iterator>
	reverse_letters_first(letters + N),
	reverse_letters_last(letters);

	std::cout << "sequence in reverse order:\t\t\t";
	std::copy(reverse_letters_first, reverse_letters_last,
	std::ostream_iterator<char>(std::cout));
	std::cout << std::endl;

	std::cout << "sequence in double-reversed (normal) order:\t";
	std::copy(boost::make_reverse_iterator(reverse_letters_last),
	boost::make_reverse_iterator(reverse_letters_first),
	std::ostream_iterator<char>(std::cout));
	std::cout << std::endl;



	The output is:

	original sequence of letters: hello world!
	sequence in reverse order: !dlrow olleh
	sequence in double-reversed (normal) order: hello world!


	The source code for this example can be found
	[@../example/reverse_iterator_example.cpp here].

	[h2 Reference]

	[h3 Synopsis]

	template <class Iterator>
	class reverse_iterator
	{
	public:
	typedef iterator_traits<Iterator>::value_type value_type;
	typedef iterator_traits<Iterator>::reference reference;
	typedef iterator_traits<Iterator>::pointer pointer;
	typedef iterator_traits<Iterator>::difference_type difference_type;
	typedef /* see below */ iterator_category;

	reverse_iterator() {}
	explicit reverse_iterator(Iterator x) ;

	template<class OtherIterator>
	reverse_iterator(
	reverse_iterator<OtherIterator> const& r
	, typename enable_if_convertible<OtherIterator, Iterator>::type* = 0 // exposition
	);
	Iterator const& base() const;
	reference operator*() const;
	reverse_iterator& operator++();
	reverse_iterator& operator--();
	private:
	Iterator m_iterator; // exposition
	};


	If `Iterator` models Random Access Traversal Iterator and Readable
	Lvalue Iterator, then `iterator_category` is convertible to
	`random_access_iterator_tag`. Otherwise, if
	`Iterator` models Bidirectional Traversal Iterator and Readable
	Lvalue Iterator, then `iterator_category` is convertible to
	`bidirectional_iterator_tag`. Otherwise, `iterator_category` is
	convertible to `input_iterator_tag`.

	[h3 Requirements]

	`Iterator` must be a model of Bidirectional Traversal Iterator. The
	type `iterator_traits<Iterator>::reference` must be the type of
	`*i`, where `i` is an object of type `Iterator`.

	[h3 Concepts]

	A specialization of `reverse_iterator` models the same iterator
	traversal and iterator access concepts modeled by its `Iterator`
	argument. In addition, it may model old iterator concepts
	specified in the following table:

	[table Categories
	[[If `I` models ][then `reverse_iterator<I>` models]]
	[[Readable Lvalue Iterator, Bidirectional Traversal Iterator][Bidirectional Iterator]]
	[[Writable Lvalue Iterator, Bidirectional Traversal Iterator][Mutable Bidirectional Iterator]]
	[[Readable Lvalue Iterator, Random Access Traversal Iterator][Random Access Iterator]]
	[[Writable Lvalue Iterator, Random Access Traversal Iterator][Mutable Random Access Iterator]]
	]

	`reverse_iterator<X>` is interoperable with
	`reverse_iterator<Y>` if and only if `X` is interoperable with
	`Y`.

	[h3 Operations]

	In addition to the operations required by the concepts modeled by
	`reverse_iterator`, `reverse_iterator` provides the following
	operations.

	reverse_iterator();

	[*Requires: ] `Iterator` must be Default Constructible.\n
	[*Effects: ] Constructs an instance of `reverse_iterator` with `m_iterator`
	default constructed.

	explicit reverse_iterator(Iterator x);

	[*Effects: ] Constructs an instance of `reverse_iterator` with
	`m_iterator` copy constructed from `x`.


	template<class OtherIterator>
	reverse_iterator(
	reverse_iterator<OtherIterator> const& r
	, typename enable_if_convertible<OtherIterator, Iterator>::type* = 0 // exposition
	);

	[*Requires: ] `OtherIterator` is implicitly convertible to `Iterator`.\n
	[*Effects: ] Constructs instance of `reverse_iterator` whose
	`m_iterator` subobject is constructed from `y.base()`.



	Iterator const& base() const;

	[*Returns: ] `m_iterator`


	reference operator*() const;

	[Effects: ] Iterator tmp = m_iterator; return --tmp;


	reverse_iterator& operator++();

	[*Effects: ] `--m_iterator`\n
	[Returns: ] `this`

	reverse_iterator& operator--();

	[*Effects: ] `++m_iterator`\n
	[Returns: ] `this`

	[endsect]