libstdc++
Function Objects
Collaboration diagram for Function Objects:

Modules

 Adaptors for pointers to functions
 
 Adaptors for pointers to members
 
 Arithmetic Function Object Classes
 
 Binder Classes
 
 Boolean Operations Classes
 
 Comparison Classes
 
 Hashes
 
 Negators
 

Functions

template<typename _Tp , typename _Class >
constexpr _Mem_fn< _Tp _Class::* > std::mem_fn (_Tp _Class::*__pm) noexcept
 
template<typename _Fn >
constexpr auto std::not_fn (_Fn &&__fn) noexcept(std::is_nothrow_constructible< std::decay_t< _Fn >, _Fn && >::value)
 

Detailed Description

Function objects, or functors, are objects with an operator() defined and accessible. They can be passed as arguments to algorithm templates and used in place of a function pointer. Not only is the resulting expressiveness of the library increased, but the generated code can be more efficient than what you might write by hand. When we refer to functors, then, generally we include function pointers in the description as well.

Often, functors are only created as temporaries passed to algorithm calls, rather than being created as named variables.

Two examples taken from the standard itself follow. To perform a by-element addition of two vectors a and b containing double, and put the result in a, use

transform (a.begin(), a.end(), b.begin(), a.begin(), plus<double>());

To negate every element in a, use

transform(a.begin(), a.end(), a.begin(), negate<double>());

The addition and negation functions will usually be inlined directly.

An adaptable function object is one which provides nested typedefs result_type and either argument_type (for a unary function) or first_argument_type and second_argument_type (for a binary function). Those typedefs are used by function object adaptors such as bind2nd. The standard library provides two class templates, unary_function and binary_function, which define those typedefs and so can be used as base classes of adaptable function objects.

Since C++11 the use of function object adaptors has been superseded by more powerful tools such as lambda expressions, function<>, and more powerful type deduction (using auto and decltype). The helpers for defining adaptable function objects are deprecated since C++11, and no longer part of the standard library since C++17. However, they are still defined and used by libstdc++ after C++17, as a conforming extension.

Function Documentation

◆ mem_fn()

template<typename _Tp , typename _Class >
constexpr _Mem_fn<_Tp _Class::*> std::mem_fn ( _Tp _Class::*  __pm)
inlineconstexprnoexcept

Returns a function object that forwards to the member pointer pointer pm.

This allows a pointer-to-member to be transformed into a function object that can be called with an object expression as its first argument.

For a pointer-to-data-member the result must be called with exactly one argument, the object expression that would be used as the first operand in a obj.*memptr or objp->*memptr expression.

For a pointer-to-member-function the result must be called with an object expression and any additional arguments to pass to the member function, as in an expression like (obj.*memfun)(args...) or (objp->*memfun)(args...).

The object expression can be a pointer, reference, reference_wrapper, or smart pointer, and the call wrapper will dereference it as needed to apply the pointer-to-member.

Since
C++11

Definition at line 234 of file functional.

◆ not_fn()

template<typename _Fn >
constexpr auto std::not_fn ( _Fn &&  __fn)
inlineconstexprnoexcept

Wrap a function object to create one that negates its result.

The function template std::not_fn creates a "forwarding call wrapper", which is a function object that wraps another function object and when called, forwards its arguments to the wrapped function object.

The result of invoking the wrapper is the negation (using !) of the wrapped function object.

Since
C++17

Definition at line 1081 of file functional.