Categories: iterators, adaptors | Component type: type |
template <class T> void forw(const list<T>& L) { list<T>::iterator first = L.begin(); list<T>::iterator last = L.end(); while (first != last) cout << *first++ << endl; } template <class T> void rev(const list<T>& L) { typedef reverse_bidirectional_iterator<list<T>::iterator, T, list<T>::reference_type, list<T>::difference_type> reverse_iterator; [2] reverse_iterator rfirst(L.end()); reverse_iterator rlast(L.begin()); while (rfirst != rlast) cout << *rfirst++ << endl; }In the function forw, the elements are printed in the order *first, *(first+1), ..., *(last-1). In the function rev, they are printed in the order *(last - 1), *(last-2), ..., *first. [3]
Parameter | Description | Default |
---|---|---|
BidirectionalIterator | The base iterator class. Incrementing an object of class reverse_bidirectional_iterator<BidirectionalIterator> corresponds to decrementing an object of class BidirectionalIterator. | |
T | The reverse iterator's value type. This should always be the same as the base iterator's value type. | |
Reference | The reverse iterator's reference type. This should always be the same as the base iterator's reference type. | T& |
Distance | The reverse iterator's distance type. This should always be the same as the base iterator's distance type. | ptrdiff_t |
Member | Where defined | Description |
---|---|---|
self | reverse_bidirectional_iterator | See below |
reverse_bidirectional_iterator() | Trivial Iterator | The default constructor |
reverse_bidirectional_iterator(const reverse_bidirectional_iterator& x) | Trivial Iterator | The copy constructor |
reverse_bidirectional_iterator& operator=(const reverse_bidirectional_iterator& x) | Trivial Iterator | The assignment operator |
reverse_bidirectional_iterator(BidirectionalIterator x) | reverse_bidirectional_iterator | See below. |
BidirectionalIterator base() | reverse_bidirectional_iterator | See below. |
Reference operator*() const | Trivial Iterator | The dereference operator |
reverse_bidirectional_iterator& operator++() | Forward Iterator | Preincrement |
reverse_bidirectional_iterator operator++(int) | Forward Iterator | Postincrement |
reverse_bidirectional_iterator& operator--() | Bidirectional Iterator | Predecrement |
reverse_bidirectional_iterator operator--(int) | Bidirectional Iterator | Postdecrement |
bool operator==(const reverse_bidirectional_iterator&, const reverse_bidirectional_iterator&) | Trivial Iterator | Compares two iterators for equality. This is a global function, not a member function. |
bidirectional_iterator_tag iterator_category(const reverse_bidirectional_iterator&) | Iterator tags | Returns the iterator's category. This is a global function, not a member function. |
T* value_type(const reverse_bidirectional_iterator&) | Iterator tags | Returns the iterator's value type. This is a global function, not a member function. |
Distance* distance_type(const reverse_bidirectional_iterator&) | Iterator tags | Returns the iterator's distance type. This is a global function, not a member function. |
Member | Description |
---|---|
self | A typedef for reverse_bidirectional_iterator<BidirectionalIterator, T, Reference, Distance>. |
BidirectionalIterator base() | Returns the current value of the reverse_bidirectional_iterator's base iterator. If ri is a reverse iterator and i is any iterator, the two fundamental identities of reverse iterators can be written as reverse_bidirectional_iterator(i).base() == i and &*ri == &*(ri.base() - 1). |
reverse_bidirectional_iterator(BidirectionalIterator i) | Constructs a reverse_bidirectional_iterator whose base iterator is i. |
[1] There isn't really any good reason to have two separate classes: this separation is purely because of a technical limitation in some of today's C++ compilers. If the two classes were combined into one, then there would be no way to declare the return types of the iterator tag functions iterator_category, distance_type and value_type correctly. The iterator traits class solves this problem: it addresses the same issues as the iterator tag functions, but in a cleaner and more flexible manner. Iterator traits, however, rely on partial specialization, and many C++ compilers do not yet implement partial specialization. Once compilers that support partial specialization become more common, these two different reverse iterator classes will be combined into a single class.
[2] The declarations for rfirst and rlast are written in this clumsy form simply as an illustration of how to declare a reverse_bidirectional_iterator. List is a Reversible Container, so it provides a typedef for the appropriate instantiation of reverse_bidirectional_iterator. The usual way of declaring these variables is much simpler:
list<T>::reverse_bidirectional_iterator rfirst = rbegin(); list<T>::reverse_bidirectional_iterator rlast = rend();
[3] Note the implications of this remark. The variable rfirst is initialized as reverse_bidirectional_iterator<...> rfirst(V.end());. The value obtained when it is dereferenced, however, is *(V.end() - 1). This is a general property: the fundamental identity of reverse iterators is &*(reverse_bidirectional_iterator(i)) == &*(i - 1). This code sample shows why this identity is important: if [f, l) is a valid range, then it allows [reverse_bidirectional_iterator(l), reverse_bidirectional_iterator(f)) to be a valid range as well. Note that the iterator l is not part of the range, but it is required to be dereferenceable or past-the-end. There is no requirement that any such iterator precedes f.