It is possible to create such a trait, with two restrictions:

- For the compiler, a free function is something fundamentally different from a class functor that overloads
`operator()`

. Thus we have to treat both cases seperately when implementing. This is not a problem for usage though, we can hide this implementation detail from the user.
- We need to know the signature of the function you want to call. This is usually not a problem, and it does have the nice side effect that our trait is able to handle overloads pretty natively.

**Step one: Free functions**

Let's start with free functions, because they are little easier to detect. Our task is, when given a function pointer, to determine whether the signature of that function pointer matches the signature passed as the second template argument. To be able to compare those, we either need to get a grasp of the underlying function signature, or create a function pointer of our signature. I arbitrarily chose the latter:

```
// build R (*)(Args...) from R (Args...)
// compile error if signature is not a valid function signature
template <typename, typename>
struct build_free_function;
template <typename F, typename R, typename ... Args>
struct build_free_function<F, R (Args...)>
{ using type = R (*)(Args...); };
```

Now all that's left to do is to compare and we are done with the free function part:

```
// determine whether a free function pointer F has signature S
template <typename F, typename S>
struct is_function_with_signature
{
// check whether F and the function pointer of S are of the same
// type
static bool constexpr value = std::is_same<
F, typename build_free_function<F, S>::type
>::value;
};
```

**Step two: Class functors**

This one is a little more involved. We could easily detect with SFINAE whether a class defines an `operator()`

:

```
template <typename T>
struct defines_functor_operator
{
typedef char (& yes)[1];
typedef char (& no)[2];
// we need a template here to enable SFINAE
template <typename U>
static yes deduce(char (*)[sizeof(&U::operator())]);
// fallback
template <typename> static no deduce(...);
static bool constexpr value = sizeof(deduce<T>(0)) == sizeof(yes);
};
```

but that does not tell us whether one exists for our desired function signature! Luckily, we can use a trick here: pointers are valid template parameters. Thus we can first use the member function pointer of our desired signature, and check whether `&T::operator()`

is of that type:

```
template <typename T, T> struct check;
```

Now `check<void (C::*)() const, &C::operator()>`

will only be a valid template instantiation if `C`

does indeed have a `void C::operator()() const`

. But to do this we first have to combine `C`

and the signature to a member function pointer. As we already have seen, we need to worry about two extra cases we did not have to care about for free functions: `const`

and `volatile`

functions. Besides that it's pretty much the same:

```
// build R (C::*)(Args...) from R (Args...)
// R (C::*)(Args...) const from R (Args...) const
// R (C::*)(Args...) volatile from R (Args...) volatile
// compile error if signature is not a valid member function signature
template <typename, typename>
struct build_class_function;
template <typename C, typename R, typename ... Args>
struct build_class_function<C, R (Args...)>
{ using type = R (C::*)(Args...); };
template <typename C, typename R, typename ... Args>
struct build_class_function<C, R (Args...) const>
{ using type = R (C::*)(Args...) const; };
template <typename C, typename R, typename ... Args>
struct build_class_function<C, R (Args...) volatile>
{ using type = R (C::*)(Args...) volatile; };
```

Putting that and our findings concerning the `check`

helper struct together, we get our check metafunction for functor objects:

```
// determine whether a class C has an operator() with signature S
template <typename C, typename S>
struct is_functor_with_signature
{
typedef char (& yes)[1];
typedef char (& no)[2];
// helper struct to determine that C::operator() does indeed have
// the desired signature; &C::operator() is only of type
// R (C::*)(Args...) if this is true
template <typename T, T> struct check;
// T is needed to enable SFINAE
template <typename T> static yes deduce(check<
typename build_class_function<C, S>::type, &T::operator()> *);
// fallback if check helper could not be built
template <typename> static no deduce(...);
static bool constexpr value = sizeof(deduce<C>(0)) == sizeof(yes);
};
```

**Step three: Putting the pieces together**

We are almost done. Now we only need to decide when to use our free function, and when the class functor metafunctions. Luckily, C++11 provides us with a `std::is_class`

trait that we can use for this. So all we have to do is specialize on a boolean parameter:

```
// C is a class, delegate to is_functor_with_signature
template <typename C, typename S, bool>
struct is_callable_impl
: std::integral_constant<
bool, is_functor_with_signature<C, S>::value
>
{};
// F is not a class, delegate to is_function_with_signature
template <typename F, typename S>
struct is_callable_impl<F, S, false>
: std::integral_constant<
bool, is_function_with_signature<F, S>::value
>
{};
```

So we can finally add the last piece of the puzzle, being our actual `is_callable`

trait:

```
// Determine whether type Callable is callable with signature Signature.
// Compliant with functors, i.e. classes that declare operator(); and free
// function pointers: R (*)(Args...), but not R (Args...)!
template <typename Callable, typename Signature>
struct is_callable
: is_callable_impl<
Callable, Signature,
std::is_class<Callable>::value
>
{};
```

Now we clean up our code, put implementation details into anonymous namespaces so they are not acessible outside of our file, and have a nice `is_callable.hpp`

to use in our project.

**Full code**

```
namespace // implementation detail
{
// build R (*)(Args...) from R (Args...)
// compile error if signature is not a valid function signature
template <typename, typename>
struct build_free_function;
template <typename F, typename R, typename ... Args>
struct build_free_function<F, R (Args...)>
{ using type = R (*)(Args...); };
// build R (C::*)(Args...) from R (Args...)
// R (C::*)(Args...) const from R (Args...) const
// R (C::*)(Args...) volatile from R (Args...) volatile
// compile error if signature is not a valid member function signature
template <typename, typename>
struct build_class_function;
template <typename C, typename R, typename ... Args>
struct build_class_function<C, R (Args...)>
{ using type = R (C::*)(Args...); };
template <typename C, typename R, typename ... Args>
struct build_class_function<C, R (Args...) const>
{ using type = R (C::*)(Args...) const; };
template <typename C, typename R, typename ... Args>
struct build_class_function<C, R (Args...) volatile>
{ using type = R (C::*)(Args...) volatile; };
// determine whether a class C has an operator() with signature S
template <typename C, typename S>
struct is_functor_with_signature
{
typedef char (& yes)[1];
typedef char (& no)[2];
// helper struct to determine that C::operator() does indeed have
// the desired signature; &C::operator() is only of type
// R (C::*)(Args...) if this is true
template <typename T, T> struct check;
// T is needed to enable SFINAE
template <typename T> static yes deduce(check<
typename build_class_function<C, S>::type, &T::operator()> *);
// fallback if check helper could not be built
template <typename> static no deduce(...);
static bool constexpr value = sizeof(deduce<C>(0)) == sizeof(yes);
};
// determine whether a free function pointer F has signature S
template <typename F, typename S>
struct is_function_with_signature
{
// check whether F and the function pointer of S are of the same
// type
static bool constexpr value = std::is_same<
F, typename build_free_function<F, S>::type
>::value;
};
// C is a class, delegate to is_functor_with_signature
template <typename C, typename S, bool>
struct is_callable_impl
: std::integral_constant<
bool, is_functor_with_signature<C, S>::value
>
{};
// F is not a class, delegate to is_function_with_signature
template <typename F, typename S>
struct is_callable_impl<F, S, false>
: std::integral_constant<
bool, is_function_with_signature<F, S>::value
>
{};
}
// Determine whether type Callable is callable with signature Signature.
// Compliant with functors, i.e. classes that declare operator(); and free
// function pointers: R (*)(Args...), but not R (Args...)!
template <typename Callable, typename Signature>
struct is_callable
: is_callable_impl<
Callable, Signature,
std::is_class<Callable>::value
>
{};
```

**Ideone example with some tests**

http://ideone.com/7PWdiv

`is_function<F::operator()>::value`

? – Fiktik Jan 31 '12 at 17:03`result_of`

trait would work to identify any callable type. I'm a bit surprised that there doesn't seem to be any`std::is_callable`

trait already. – bames53 Jan 31 '12 at 19:40`result_of`

in this way all day. It seems like there are many situations where GCC will produce an error, in one overload, though another valid overload exists. – user2023370 Jan 31 '12 at 23:05`is_function<typename F::operator()>::value`

is also rejected:`invalid template argument`

. – user2023370 Feb 1 '12 at 10:21