std::common_type

Determines the common type among all types T..., that is a type all T... can be explicitly converted to. If such a type exists (as determined according to the rules below), the member type names that type. Otherwise, there is no member type.

• If sizeof...(T) is zero, there is no member type.
• If sizeof...(T) is one (i.e., T... contains only one type T0), the member type names the same type as std::common_type<T0, T0>::type if it exists; otherwise there is no member type.
• If sizeof...(T) is two (i.e., T... contains exactly two types T1 and T2),

• If applying std::decay to at least one of T1 and T2 produces a different type, the member type names the same type as std::common_type<std::decay<T1>::type, std::decay<T2>::type>::type, if it exists; if not, there is no member type;
• Otherwise, if there is a user specialization for std::common_type<T1, T2>, that specialization is used;
• Otherwise, if std::decay<decltype(false?std::declval<T1>():std::declval<T2>())>::type is a valid type, the member type denotes that type, see the conditional operator;

• Otherwise, there is no member type.

• If sizeof...(T) is greater than two (i.e., T... consists of the types T1, T2, R...), then if std::common_type<T1, T2>::type exists, the member type denotes std::common_type<typename std::common_type<T1, T2>::type, R...>::type if such a type exists. In all other cases, there is no member type.

If any type in the parameter pack T is not a complete type, (possibly cv-qualified) void, or an array of unknown bound, the behavior is undefined.

If an instantiation of a template above depends, directly or indirectly, on an incomplete type, and that instantiation could yield a different result if that type were hypothetically completed, the behavior is undefined.

[edit]Nested types

[edit]Helper types

[edit]Specializations

Users may specialize common_type for types T1 and T2 if

• At least one of T1 and T2 depends on a user-defined type, and
• std::decay is an identity transformation for both T1 and T2.

If such a specialization has a member named type, it must be a public and unambiguous member that names a cv-unqualified non-reference type to which both T1 and T2 are explicitly convertible. Additionally, std::common_type<T1, T2>::type and std::common_type<T2, T1>::type must denote the same type.

A program that adds common_type specializations in violation of these rules has undefined behavior.

Note that the behavior of a program that adds a specialization to any other template (except for std::basic_common_reference)(since C++20) from <type_traits> is undefined.

The following specializations are already provided by the standard library:

[edit]Possible implementation

// primary template (used for zero types)template<class...>struct common_type {};   // one typetemplate<class T>struct common_type<T>: common_type<T, T>{};   namespace detail {template<class...>using void_t =void;   template<class T1, class T2>using conditional_result_t = decltype(false?std::declval<T1>():std::declval<T2>());   template<class, class, class=void>struct decay_conditional_result {};template<class T1, class T2>struct decay_conditional_result<T1, T2, void_t<conditional_result_t<T1, T2>>>:std::decay<conditional_result_t<T1, T2>>{};   template<class T1, class T2, class=void>struct common_type_2_impl : decay_conditional_result<const T1&, const T2&>{};   // C++11 implementation:// template<class, class, class = void>// struct common_type_2_impl {};   template<class T1, class T2>struct common_type_2_impl<T1, T2, void_t<conditional_result_t<T1, T2>>>: decay_conditional_result<T1, T2>{};}   // two typestemplate<class T1, class T2>struct common_type<T1, T2>:std::conditional<std::is_same<T1, typenamestd::decay<T1>::type>::value&&std::is_same<T2, typenamestd::decay<T2>::type>::value, detail::common_type_2_impl<T1, T2>, common_type<typenamestd::decay<T1>::type, typenamestd::decay<T2>::type>>::type{};   // 3+ typesnamespace detail {template<class AlwaysVoid, class T1, class T2, class... R>struct common_type_multi_impl {};template<class T1, class T2, class...R>struct common_type_multi_impl<void_t<typename common_type<T1, T2>::type>, T1, T2, R...>: common_type<typename common_type<T1, T2>::type, R...>{};}   template<class T1, class T2, class... R>struct common_type<T1, T2, R...>: detail::common_type_multi_impl<void, T1, T2, R...>{};

[edit]Notes

For arithmetic types not subject to promotion, the common type may be viewed as the type of the (possibly mixed-mode) arithmetic expression such as T0()+ T1()+ ... + Tn().

[edit]Examples

#include <iostream>#include <type_traits>   template<class T>struct Number { T n;};   template<class T, class U>constexpr Number<std::common_type_t<T, U>> operator+(const Number<T>& lhs, const Number<U>& rhs){return{lhs.n+ rhs.n};}   void describe(constchar* expr, const Number<int>& x){std::cout<< expr <<" is Number<int>{"<< x.n<<"}\n";}   void describe(constchar* expr, const Number<double>& x){std::cout<< expr <<" is Number<double>{"<< x.n<<"}\n";}   int main(){ Number<int> i1 ={1}, i2 ={2}; Number<double> d1 ={2.3}, d2 ={3.5}; describe("i1 + i2", i1 + i2); describe("i1 + d2", i1 + d2); describe("d1 + i2", d1 + i2); describe("d1 + d2", d1 + d2);}

i1 + i2 is Number<int>{3} i1 + d2 is Number<double>{4.5} d1 + i2 is Number<double>{4.3} d1 + d2 is Number<double>{5.8}

[edit]Defect reports

The following behavior-changing defect reports were applied retroactively to previously published C++ standards.

[edit]See also