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In my code, I need to test if a type given to a template is a pointer -- be it smart or not. According to boost, there is no reliable and generic way to do that (see here) -- or is there?

So far, I check for the following:

  • A: Can T be converted to void*?
  • B: Does T have a get() method?
  • C: Does T have a type called element_type?
  • D: Does get() return an element_type*?

If (A || B && C && D), then I conclude that my type must be some kind of pointer.

Here's the template:

template <typename T>
class is_pointer_type
    typedef struct { char array[1]; } yes;
    typedef struct { char array[2]; } no;

    template <typename C> static yes test_g(decltype(&C::get));
    template <typename C> static no  test_g(...);

    template <typename C> static yes test_e(typename C::element_type*);
    template <typename C> static no  test_e(...);

    enum {
        has_get          = sizeof(test_g<T>(0)) == sizeof(yes),
        has_element_type = sizeof(test_e<T>(0)) == sizeof(yes)

    template <typename Q, bool OK = false>
    struct get { struct type {}; };

    template <typename Q>
    struct get<Q, true>
        typedef decltype(((Q*)nullptr)->get()) type;

    template <typename Q, bool OK = false>
    struct ptr { struct type {}; };

    template <typename Q>
    struct ptr<Q, true>
        typedef typename Q::element_type* type;

    enum {
        types_ok = std::is_same<
                           typename get<T, has_get>::type,
                           typename ptr<T, has_element_type>::type
        value    = std::is_convertible<T, void*>::value || types_ok

So far, it seems to work out ok. But is there something wrong with this reasoning? Should I be prepared for unpleasant surprises? What about const / volatile?

Update (Motivation):

In the comments you ask for my motivation and they are right, I owe you one. The use case is a Lua - C++ binding library: when exposing a class instance to Lua with template <typename T> push_value(T value), I need to deduce the underlying type U in any combination of T = U const/volatile/*/& and T = some_pointer<U>. I need to know if the underlying class U has been registered already with the binder.

share|improve this question
You are doing something boost says cannot be done. I'd be very ready for surprises... – Michael Dorgan May 10 '12 at 17:37
This isn't a generic solution, it is a solution targeted at a particular conceptual notation. What if you run into a smart pointer that doesn't have an element_type but instead has a ptr_type or requires the use of a trait? – Crazy Eddie May 10 '12 at 17:41
There are things that can be converted to void* but are not smart pointers. Specifically: early attempts at a safe bool idiom, including std::ios. – Steve Jessop May 10 '12 at 17:45
Why do you think you need this? I believe the solution to this "problem" is worthless. However, the solution to the problem you think can be solved like this, but didn't tell us, can be useful. – R. Martinho Fernandes May 10 '12 at 18:14
Unless you do this for a library, how about declaring template is_pointer_like<T> and then just specialize it for plain and smart pointer types you actually use? – doublep May 10 '12 at 18:35
up vote 1 down vote accepted

It's easy to check if a type is a pointer, either using boost or defining a custom template with a specialization like

template <typename C> static no test_pointer(C);
template <typename C> static yes test_pointer(C*);

But you can stick with the void* solution if you like it more.

To check smart pointers, I suggest checking for appropriate operators instead. I think a type can be considered to be a smart pointer only if it has both operator* and operator-> defined. So you should check for

template <typename C> static yes test_deref(decltype(&C::operator*));
template <typename C> static no test_deref(...);
template <typename C> static yes test_arrow(decltype(&C::operator->));
template <typename C> static no test_arrow(...);

and require both results to be 'yes'. So, the final formula can be calculated as "normal pointer || (has operator* && has operator->)".

However, it's a solution only for smart pointers. If you also want to pass types other than smart pointers (other wrappers, collections, etc) to Lua than it's a whole different story and I don't dare to propose a solution for that.

share|improve this answer
std::unique_ptr<T[]> is a full-fledged smart pointer that doesn't provide operator-> but operator[] instead. – Xeo May 20 '12 at 6:30
I get your point, and you're right from your point of view. However, that's exactly why unique_ptr<T[]> should be considered as a smart array instead of a smart pointer despite its name. If you pass such pointers to Lua, you have to add another test directly for such exceptions, and that's a drawback. Are there any similar exceptions we can think of? – Zólyomi István May 20 '12 at 16:09
Agreed. Also, element_type is not needed with C++11 any more, as it should be the same as decltype(&C::operator*)) – marton78 May 28 '12 at 12:09

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