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utility(3C++std)


make_pair , operator!= , operator> , operator>= , operator< , operator<= , operator== , pair - defines several templates of general utility (standard template library)

Synopsis

   namespace std {
   template<class T, class U>
       struct pair;

           // TEMPLATE FUNCTIONS
   template<class T, class U>
       pair<T, U> make_pair(const T& x, const U& y);
   template<class T, class U>
       bool operator==(const pair<T, U>& x,
           const pair<T, U>& y);
   template<class T, class U>
       bool operator!=(const pair<T, U>& x,
           const pair<T, U>& y);
   template<class T, class U>
       bool operator<(const pair<T, U>& x,
           const pair<T, U>& y);
   template<class T, class U>
       bool operator>(const pair<T, U>& x,
           const pair<T, U>& y);
   template<class T, class U>
       bool operator<=(const pair<T, U>& x,
           const pair<T, U>& y);
   template<class T, class U>
       bool operator>=(const pair<T, U>& x,
           const pair<T, U>& y);

   namespace rel_ops {
       template<class T>
           bool operator!=(const T& x, const T& y);
       template<class T>
           bool operator<=(const T& x, const T& y);
       template<class T>
           bool operator>(const T& x, const T& y);
       template<class T>
           bool operator>=(const T& x, const T& y);
           };
       };

Description

Include the STL standard header <utility> to define several templates of general use throughout the Standard Template Library.

Four template operators -- operator!=, operator<=, operator>, and operator>= -- define a total ordering on pairs of operands of the same type, given definitions of operator== and operator<.

If an implementation supports namespaces, these template operators are defined in the rel_ops namespace, nested within the std namespace. If you wish to make use of these template operators, write the declaration:

   using namespace std::rel_ops;

which promotes the template operators into the current namespace.

make_pair

   template<class T, class U>
       pair<T, U> make_pair(const T& x, const U& y);

The template function returns pair<T, U>(x, y).

operator!=

   template<class T>
       bool operator!=(const T& x, const T& y);
   template<class T, class U>
       bool operator!=(const pair<T, U>& x,
           const pair<T, U>& y);

The template function returns !(x == y).

operator==

   template<class T, class U>
       bool operator==(const pair<T, U>& x,
           const pair<T, U>& y);

The template function returns x.first == y.first && x.second == y.second.

operator<

   template<class T, class U>
       bool operator<(const pair<T, U>& x,
           const pair<T, U>& y);

The template function returns x.first < y.first || !(y.first < x.first && x.second < y.second).

operator<=

   template<class T>
       bool operator<=(const T& x, const T& y);
   template<class T, class U>
       bool operator<=(const pair<T, U>& x,
           const pair<T, U>& y);

The template function returns !(y < x).

operator>

   template<class T>
       bool operator>(const T& x, const T& y);
   template<class T, class U>
       bool operator>(const pair<T, U>& x,
           const pair<T, U>& y);

The template function returns y < x.

operator>=

   template<class T>
       bool operator>=(const T& x, const T& y);
   template<class T, class U>
       bool operator>=(const pair<T, U>& x,
           const pair<T, U>& y);

The template function returns !(x < y).

pair

   template<class T, class U>
       struct pair {
       typedef T first_type;
       typedef U second_type
       T first;
       U second;
       pair();
       pair(const T& x, const U& y);
       template<class V, class W>
           pair(const pair<V, W>& pr);
       };

The template class stores a pair of objects, first, of type T, and second, of type U. The type definition first_type, is the same as the template parameter T, while second_type, is the same as the template parameter U.

The first (default) constructor initializes first to T() and second to U(). The second constructor initializes first to x and second to y. The third (template) constructor initializes first to pr.first and second to pr.second. T and U each need supply only a default constructor, single-argument constructor, and a destructor.

References


18 February 2000
© 2000 The Santa Cruz Operation, Inc. All rights reserved.

Copyright © 1992-1996 by P.J. Plauger. Portions derived from work copyright © 1994 by Hewlett-Packard Company. All rights reserved.