I'm trying to implement std::is_enum. Here is my code so far:

template<typename T>
struct is_enum {
    static bool value;

template<typename T>
bool is_enum<T>::value = false;

template<enum E>
struct is_enum {
    static bool value;

template<enum E>
bool is_enum<E>::value = true;

This code causes error. More precisely:

g++ -std=c++0x -Wall -o "enum2" "enum2.cpp" (in directory: /home/aristophanes/Desktop/C++)
Compilation failed.
enum2.cpp:11:15: error: use of enum ‘E’ without previous declaration
enum2.cpp:3:10: error: template parameter ‘class T’
enum2.cpp:12:8: error: redeclared here as ‘int E’
enum2.cpp:16:15: error: use of enum ‘E’ without previous declaration
enum2.cpp:17:14: error: ‘E’ was not declared in this scope
enum2.cpp:17:15: error: template argument 1 is invalid
enum2.cpp:17:18: error: template declaration of ‘bool value’

Can anyone explain to me where I make a mistake? It is mine or the compiler's fault? Thanks in advance.

Edit: if it is completely wrong, then how can I correct it?

Note: I'm using g++ -o <file> <file>.cpp

  • 13
    I'm fairly certain that is_enum, like many other type traits, cannot be implemented without compiler intrinsics.
    – ildjarn
    Jul 3 '12 at 18:30
  • [OT] In this case, a better alternative to static variables can be enums (like: enum { value = false };)
    – Gigi
    Jul 3 '12 at 18:31
  • 7
    @Gigi : This is tagged c++11 -- the best alternative is to inherit from std::true_type, std::false_type, or std::integral_constant<>. :-]
    – ildjarn
    Jul 3 '12 at 18:32
  • 2
    @ildjarn that is incorrect (at least for C++03 and I'm pretty sure the same is true about C++11). An implementation is given in "C++ Templates, the complete guide", and I provided an alternative definition in one of my answers (which is far less elegant, but passed all my tests), see stackoverflow.com/questions/4705316/… Jul 6 '12 at 21:03
  • @JohannesSchaub-litb: In C++11 [meta.rqmts]/p1 requires std::is_enum to derive publicly and unambiguously from std::true_type or std::false_type. Jul 6 '12 at 23:23

The best way to implement this is to use compiler magic, and I believe most implementations do this.

For example, here's libc++'s implementation for gcc >= 4.3 and any compiler that __has_feature(is_enum)1

template <class _Tp> struct _LIBCPP_VISIBLE is_enum
    : public integral_constant<bool, __is_enum(_Tp)> {};

For all other compilers libc++ does:

template <class _Tp> struct _LIBCPP_VISIBLE is_enum
    : public integral_constant<bool, !is_void<_Tp>::value             &&
                                     !is_integral<_Tp>::value         &&
                                     !is_floating_point<_Tp>::value   &&
                                     !is_array<_Tp>::value            &&
                                     !is_pointer<_Tp>::value          &&
                                     !is_reference<_Tp>::value        &&
                                     !is_member_pointer<_Tp>::value   &&
                                     !is_union<_Tp>::value            &&
                                     !is_class<_Tp>::value            &&
                                     !is_function<_Tp>::value         > {};

Some of those other type traits still require compiler magic.2 E.g. is_union. However, that condition can be rewritten such that it doesn't need compiler magic. This can be done by replacing the seperate checks for unions and classes with a single check for both, as Johannes Schaub points out.

1. So far as I know only clang implements __has_feature, unfortunately.
2. It's interesting that libc++ does have a version of is_union<T> and is_class<T> that do not use compiler intrinsics, but as a result they provide erroneous results for union types. But their erroneous results are complementary so libc++'s fallback implementation of is_enum<T> provides accurate results.

  • 3
    Your answer is incorrect. In the alternative definition, you can replace !is_union<_Tp> && !is_class<_Tp> by !is_union_or_class<_Tp>, which is pretty straightforward to implement without compiler-intrinsics by trying to form a member pointer and relying on SFINAE. All the other type traints mentioned there can be written without intrinsics support too. Jul 6 '12 at 21:06
  • @Johannes : Ah, is_union_or_class didn't occur to me. Good stuff.
    – ildjarn
    Jul 6 '12 at 21:42
  • @bames53: Your description of when libc++ uses this definition is inverted. libc++ uses this definition for gcc < 4.3 or does not have __has_feature(is_enum). Jul 6 '12 at 23:21
  • 1
    @HowardHinnant I'm mentioning both implementations, but the first one is so short and simple that it's easy to skip over. I believe my answer already reflects that libc++ uses a fallback only for gcc<4.3 and other compilers for which __has_feature(is_enum) is not true.
    – bames53
    Jul 7 '12 at 0:01
  • 1
    The clang libcxx non-magic implementation is incorrect, if the compiler has built-in nullptr(in this case likely the 'magic' version is selected). one way to fix it is to add && !is_null_pointer<T>::value (c++14). I know this trait is in C++14, but, in the latest libcxx source code, it is still not fixed.
    – YumeYao
    Sep 17 '20 at 16:30


template<enum E>

promises that the template argument is a value of type enum E. The argument is NOT a type (Type template arguments are introduced by typename, or for backward compatibility, class. Even struct isn't allowed). It's just like saying

template<int i>

except no name is given for the variable.

Things go wrong from there.

  • @RondogiannisAristophanes: No, you need a compiler builtin operator, like ildjarn said in the comments.
    – Ben Voigt
    Jul 3 '12 at 18:36

You problem is that

template<enum E>

Is interpreted as unnamed parameter with type forward declared enum named E.
Semantically same to


Just substituting int with enum E.

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