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std::enable_if

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enable_if
(C++11)
(C++17)
Compile-time rational arithmetic
Compile-time integer sequences
 
Defined in header <type_traits>
template<bool B, class T =void>
struct enable_if;
(since C++11)

If B is true, std::enable_if has a public member typedef type, equal to T; otherwise, there is no member typedef.

This metafunction is a convenient way to leverage SFINAE prior to C++20's concepts, in particular for conditionally removing functions from the candidate set based on type traits, allowing separate function overloads or specializations based on those different type traits.

std::enable_if can be used in many forms, including:

  • as an additional function argument (not applicable to most operator overloads),
  • as a return type (not applicable to constructors and destructors),
  • as a class template or function template parameter.

If the program adds specializations for std::enable_if, the behavior is undefined.

Contents

[edit]Member types

Type Definition
type either T or no such member, depending on the value of B

[edit]Helper types

template<bool B, class T =void>
using enable_if_t =typename enable_if<B,T>::type;
(since C++14)

[edit]Possible implementation

template<bool B, class T =void>struct enable_if {};   template<class T>struct enable_if<true, T>{typedef T type;};

[edit]Notes

A common mistake is to declare two function templates that differ only in their default template arguments. This does not work because the declarations are treated as redeclarations of the same function template (default template arguments are not accounted for in function template equivalence).

/* WRONG */   struct T {enum{ int_t, float_t } type;   template<typename Integer, typename= std::enable_if_t<std::is_integral<Integer>::value>> T(Integer): type(int_t){}   template<typename Floating, typename= std::enable_if_t<std::is_floating_point<Floating>::value>> T(Floating): type(float_t){}// error: treated as redefinition};   /* RIGHT */   struct T {enum{ int_t, float_t } type;   template<typename Integer, std::enable_if_t<std::is_integral<Integer>::value, bool>=true> T(Integer): type(int_t){}   template<typename Floating, std::enable_if_t<std::is_floating_point<Floating>::value, bool>=true> T(Floating): type(float_t){}// OK};

Care should be taken when using enable_if in the type of a constant template parameter of a namespace-scope function template. Some ABI specifications like the Itanium ABI do not include the instantiation-dependent portions of constant template parameters in the mangling, meaning that specializations of two distinct function templates might end up with the same mangled name and be erroneously linked together. For example:

// first translation unit   struct X {enum{ value1 =true, value2 =true};};   template<class T, std::enable_if_t<T::value1, int>=0>void func(){}// #1   templatevoid func<X>();// #2   // second translation unit   struct X {enum{ value1 =true, value2 =true};};   template<class T, std::enable_if_t<T::value2, int>=0>void func(){}// #3   templatevoid func<X>();// #4

The function templates #1 and #3 have different signatures and are distinct templates. Nonetheless, #2 and #4, despite being instantiations of different function templates, have the same mangled name in the Itanium C++ ABI (_Z4funcI1XLi0EEvv), meaning that the linker will erroneously consider them to be the same entity.

[edit]Example

#include <iostream>#include <new>#include <string>#include <type_traits>   namespace detail {void* voidify(constvolatilevoid* ptr)noexcept{returnconst_cast<void*>(ptr);}}   // #1, enabled via the return typetemplate<class T>typename std::enable_if<std::is_trivially_default_constructible<T>::value>::type construct(T*){std::cout<<"default constructing trivially default constructible T\n";}   // same as abovetemplate<class T>typename std::enable_if<!std::is_trivially_default_constructible<T>::value>::type construct(T* p){std::cout<<"default constructing non-trivially default constructible T\n";::new(detail::voidify(p)) T;}   // #2template<class T, class... Args> std::enable_if_t<std::is_constructible<T, Args&&...>::value>// Using helper type construct(T* p, Args&&... args){std::cout<<"constructing T with operation\n";::new(detail::voidify(p)) T(static_cast<Args&&>(args)...);}   // #3, enabled via a parametertemplate<class T>void destroy( T*, typename std::enable_if<std::is_trivially_destructible<T>::value>::type*=0){std::cout<<"destroying trivially destructible T\n";}   // #4, enabled via a constant template parametertemplate<class T, typename std::enable_if<!std::is_trivially_destructible<T>{}&&(std::is_class<T>{}||std::is_union<T>{}), bool>::type=true>void destroy(T* t){std::cout<<"destroying non-trivially destructible T\n"; t->~T();}   // #5, enabled via a type template parametertemplate<class T, typename= std::enable_if_t<std::is_array<T>::value>>void destroy(T* t)// note: function signature is unmodified{for(std::size_t i =0; i <std::extent<T>::value;++i) destroy((*t)[i]);}   /* template<class T, typename = std::enable_if_t<std::is_void<T>::value>> void destroy(T* t) {} // error: has the same signature with #5 */   // the partial specialization of A is enabled via a template parametertemplate<class T, class Enable =void>class A {};// primary template   template<class T>class A<T, typename std::enable_if<std::is_floating_point<T>::value>::type>{};// specialization for floating point types   int main(){union{int i;char s[sizeof(std::string)];} u;   construct(reinterpret_cast<int*>(&u)); destroy(reinterpret_cast<int*>(&u));   construct(reinterpret_cast<std::string*>(&u), "Hello"); destroy(reinterpret_cast<std::string*>(&u));   A<int>{};// OK: matches the primary template A<double>{};// OK: matches the partial specialization}

Output:

default constructing trivially default constructible T destroying trivially destructible T constructing T with operation destroying non-trivially destructible T

[edit]See also

(C++17)
void variadic alias template
(alias template)[edit]
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