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C++ language
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inline specifier
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Boolean - Integer - Floating-point
Character - String - nullptr (C++11)
User-defined (C++11)
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Type alias declaration (C++11)
Implicit conversions - Explicit conversions
static_cast - dynamic_cast
const_cast - reinterpret_cast
Memory allocation
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Special member functions

Introduces a name that is defined elsewhere into the declarative region where this using-declaration appears.

using typename(optional) Template:sparam Template:sparam ; (1)
using :: Template:sparam ; (2)
Template:sparam - a sequence of names and scope resolution operators ::, ending with a scope resolution operator. A single :: refers to the global namespace.
Template:sparam - an id-expression
Template:sparam - the keyword typename may be used as necessary to resolve dependent names, when the using-declaration introduces a type



Using-declarations can be used to introduce namespace members into other namespaces and block scopes, or to introduce base class members into derived class definitions.

In namespace and block scope

Using-declaration introduces a member of another namespace into current namespace or block scope

#include <iostream>
using std::string;
int main()
    std::string str = "Example";
    using std::cout;
    cout << str;

See namespace for details.

In class definition

1) Using-declaration introduces a member of a base class into the derived class definition, such as to expose a protected member of base as public member of derived. In this case, Template:sparam must name a base class of the one being defined. If the name is the name of an overloaded member function of the base class, all base class member functions with that name are introduced. If the derived class already has a member with the same name, parameter list, and qualifications, the derived class member hides or overrides (doesn't conflict with) the member that is introduced from the base class.
#include <iostream>
struct B {
    virtual void f(int) { std::cout << "B::f\n"; }
    void g(char)        { std::cout << "B::g\n"; }
    void h(int)         { std::cout << "B::h\n"; }
    int m; // B::m is protected
    typedef int value_type;
struct D : B {
    using B::m; // D::m is public
    using B::value_type; // D::value_type is public
    using B::f;
    void f(int) { std::cout << "D::f\n"; } // D::f(int) overrides B::f(int)
    using B::g;
    void g(int) { std::cout << "D::g\n"; } // both g(int) and g(char) are visible
                                           // as members of D
    using B::h;
    void h(int) { std::cout << "D::h\n"; } // D::h(int) hides B::h(int)
int main()
    D d;
    B& b = d;
//    b.m = 2; // error, B::m is protected
    d.m = 1; // protected B::m is accessible as public D::m
    b.f(1); // calls derived f()
    d.f(1); // calls derived f()
    d.g(1); // calls derived g(int)
    d.g('a'); // calls base g(char)
    b.h(1); // calls base h()
    d.h(1); // calls derived h()


2) (since C++11) If the using-declaration refers to a constructor of a direct base of the class being defined (e.g. using Base::Base;), constructors of that base class are inherited, according to the following rules:
a) A set of inheriting constructors is composed of
*) All non-template constructors of the base class
*) For each constructor with default arguments or the ellipsis parameter, all constructor signatures that are formed by dropping the ellipsis and omitting default arguments from the ends of argument lists one by one
*) All constructor templates of the base class
*) For each constructor template with default arguments or the ellipsis, all constructor signatures that are formed by dropping the ellipsis and omitting default arguments from the ends of argument lists one by one
b) All inherited constructors that aren't the default constructor or the copy/move constructor and whose signatures do not match user-defined constructors in the derived class, are implicitly declared in the derived class. The default parameters are not inherited:
struct B1 {
struct D1 : B1 {
    using B1::B1;
// The set of inherited constructors is 
// 1. B1(const B1&)
// 2. B1(B1&&)
// 3. B1(int)
// D1 has the following constructors:
// 1. D1()
// 2. D1(const D1&) 
// 3. D1(D1&&)
// 4. D1(int) <- inherited
struct B2 {
    B2(int = 13, int = 42);
struct D2 : B2 {
    using B2::B2;
// The set of inherited constructors is
// 1. B2(const B2&)
// 2. B2(B2&&)
// 3. B2(int = 13, int = 42)
// 4. B2(int = 13)
// 5. B2()
// D2 has the following constructors:
// 1. D2()
// 2. D2(const D2&)
// 3. D2(D2&&)
// 4. D2(int, int) <- inherited
// 5. D2(int) <- inherited
The inherited constructors are equivalent to user-defined constructors with an empty body and with a member initializer list consisting of a single Template:sparam, which forwards all of its arguments to the base class constructor.


Only the name explicitly mentioned in the using-declaration is transferred into the declarative scope: in particular, enumerators are not transferred when the enumeration type name is using-declared.

A using-declaration cannot refer to a template-id, to a namespace, to a scoped enumerator, to a destructor of a base class or to a specialization of a member template for a user-defined conversion function.

If a using-declaration brings the base class assignment operator into derived class, whose signature happens to match the derived class's copy-assignment or move-assignment operator, that operator is hidden by the implicitly-declared copy/move assignment operator of the derived class.

If two using-declarations inherit the constructor with the same signature (from two direct base classes), the program is ill-formed.