I have some variant using V = std::variant<A, B, C> and some function foo with the prototype void foo(const T&).

And want my function foo to be std::enable_ifed if one of V's types are passed (without indicating them explicitly).

My V will get more and more types in time, because of that, solution like

template<class T,
         typename std::enable_if<
            std::is_same_v<T, A> || std::is_same_v<T, B> || std::is_same_v<T, C>,
            int>::type = 0>
void foo(const T&);

is not acceptable.

Here is a boost solution.

Is it possible to implement the logic for std::variant?

Ideally, the type trait should look like is_one_of_variants_types<V, T>.

  • A variant can be any of the types; what does foo do if the variant isn't actually a valid alternative? – Yakk - Adam Nevraumont Aug 24 '19 at 21:01
  • @Yakk-AdamNevraumont, foo takes some of variant's types, not the variant itself. (Those types of the variant may be variants themselves, yet that shouldn't affect the solution.) – Nestor Aug 24 '19 at 22:08
template <typename, typename>
constexpr bool is_one_of_variants_types = false;

template <typename... Ts, typename T>
constexpr bool is_one_of_variants_types<std::variant<Ts...>, T>
    = (std::is_same_v<T, Ts> || ...);

template <typename T>
auto foo(const T&)
    -> std::enable_if_t<is_one_of_variants_types<V, T>>;


| improve this answer | |

And want my function foo to be std::enable_if ed if one of V's types are passed (without indicating them explicitly).

I suppose you can simply try, inside a decltype(), to emplace() a T value inside a V value.

I mean... something as follows

#include <variant>
#include <type_traits>

struct A {};
struct B {};
struct C {};

using V = std::variant<A, B, C>;

template <typename T>
auto foo (T const & t)
   -> std::void_t<decltype( std::declval<V>().emplace<T>(t) )>
 { }

int main ()
   foo(A{});  // compile
   // foo(0); // compilation error

Obviously this works only if all variant types are different and with a copy constructor (implicit or explicit).

| improve this answer | |
  • thank you for the smart solution! May you please explain why Obviously this works only if all variant types are different.? – Nestor Aug 24 '19 at 22:26
  • Because the emplace<T, Args...>() method is available only if T occurs exactly one times in Tipes... (given a std::variant<Tipes...>). Not the only problem: T must be constructible from a T value, so you needs a copy constructor (implicit, as in my example, or explicit) for every type in Tipes.... So, yes: it's a smart solution; but with a couple of great limits. – max66 Aug 25 '19 at 11:59
  • Thank you! Didn’t know that. I’ve tested your solution. Some more limitations: the types cannot be incomplete (i.e. forward declared types won’t compile if foo is used before their definitions) and, of course, limitations on constructors are painful. – Nestor Aug 25 '19 at 12:44
  • @Nestor - yes... the incompleteness is another problem. – max66 Aug 25 '19 at 17:47

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