How to write `is_complete` template?

Question

After answering this question I was trying to find is_complete template in Boost library and I realized that there is no such template in Boost.TypeTraits. Why there is no such template in Boost library? How it should look like?

//! Check whether type complete
template<typename T>
struct is_complete
{   
  static const bool value = ( sizeof(T) > 0 );
};

...

// so I could use it in such a way
BOOST_STATIC_ASSERT( boost::is_complete<T>::value );

The code above is not correct, because it is illegal to apply sizeof to an incomplete type. What will be a good solution? Is it possible to apply SFINAE in this case somehow?

---

Well, this problem couldn't be solved in general without violating the ODR rule, but there is there a platform specific solution which works for me.

Answer 1

The answer given by Alexey Malistov can be used on MSVC with a minor modification:

namespace 
{
    template<class T, int discriminator>
    struct is_complete {  
      static T & getT();   
      static char (& pass(T))[2]; 
      static char pass(...);   
      static const bool value = sizeof(pass(getT()))==2;
    };
}
#define IS_COMPLETE(X) is_complete<X,__COUNTER__>::value

Unfortunately, the __COUNTER__ predefined macro is not part of the standard, so it would not work on every compiler.

Answer 2

It might be a bit late, but so far, no C++ 11 solution worked for both complete and abstract types.

So, here you are.

With VS2015 (v140), g++ >= 4.8.1, clang >= 3.4, this is working:

template <class T, class = void>
struct IsComplete : std::false_type
{};

template <class T>
struct IsComplete< T, decltype(void(sizeof(T))) > : std::true_type
{};

Thanks to Bat-Ulzii Luvsanbat: https://blogs.msdn.microsoft.com/vcblog/2015/12/02/partial-support-for-expression-sfinae-in-vs-2015-update-1/

With VS2013 (V120):

namespace Details
{

    template <class T>
    struct IsComplete
    {
        typedef char no;
        struct yes { char dummy[2]; };

        template <class U, class = decltype(sizeof(std::declval< U >())) >
        static yes check(U*);

        template <class U>
        static no check(...);

        static const bool value = sizeof(check< T >(nullptr)) == sizeof(yes);
    };

} // namespace Details


template <class T>
struct IsComplete : std::integral_constant< bool, Details::IsComplete< T >::value >
{};

This one is inspired from the internets and static assert that template typename T is NOT complete?

Answer 3

template<class T>
struct is_complete {
    static T & getT();
    static char (& pass(T))[2];
    static char pass(...);

    static const bool value = sizeof(pass(getT()))==2;
};

Answer 4

I'm afraid you can't implement such an is_complete type traits. The implementation given by @Alexey fails to compile on G++ 4.4.2 and G++ 4.5.0:

error: initializing argument 1 of ‘static char (& is_complete::pass(T))[2] [with T = Foo]’

On my Mac, with G++ 4.0.1 evaluating is_complete<Foo>::value where struct Foo; is incomplete yields to true which is even worse than a compiler error.

T can be both complete and incomplete in the same program, depending on the translation unit but it's always the same type. As a consequence, as commented above, is_complete<T> is always the same type as well.

So if you respect ODR it is not possible to have is_complete<T> evaluating to different values depending on where it is used; otherwise it would mean you have different definitions for is_complete<T> which ODR forbids.

EDIT: As the accepted answer, I myself hacked around a solution that uses the __COUNTER__ macro to instantiate a different is_complete<T, int> type everytime the IS_COMPLETE macro is used. However, with gcc, I couldn't get SFINAE to work in the first place.

Answer 5

Solving this requires performing the computation in the default argument of the trait template, as attempting to change the definition of a template violates the ODR rule (although a combination of __COUNTER__ and namespace {} can work around ODR).

This is written in C++11 but can be adjusted to work in C++03 mode of a moderately recent C++11-compatible compiler.

template< typename t >
typename std::enable_if< sizeof (t), std::true_type >::type
is_complete_fn( t * );

std::false_type is_complete_fn( ... );

template< typename t, bool value = decltype( is_complete_fn( (t *) nullptr ) )::value >
struct is_complete : std::integral_constant< bool, value > {};

Online demo.

The default argument is evaluated where the template is named, so it can contextually switch between different definitions. There is no need for a different specialization and definition at each use; you only need one for true and one for false.

The rule is given in §8.3.6/9, which applies equally to function default arguments and default template-arguments:

Default arguments are evaluated each time the function is called.

But beware, using this inside a template is almost sure to violate the ODR. A template instantiated on an incomplete type must not do anything differently from if it were instantiated on a complete type. I personally only want this for a static_assert.

Incidentally, this principle may also be helpful if you want to go the other way and implement the functionality of __COUNTER__ using templates and overloading.

Answer 6

I can't find anything in the standard that guarantees that sizeof on an incomplete type will yield 0. It does require, however, that if T is incomplete at some point, but completed later in that translation unit, that all references to T refer to the same type -- so as I read it, even if T is incomplete where your template was invoked, it would be required to say it was complete if T is completed somewhere in that translation unit.

Answer 7

Just chiming in to signal that an answer (not given by me) to an unrelated question gives a solution for the is_complete<T> template.

The answer is here. I'm not pasting it below in order to not mistakenly get credit for it.

Answer 8

It's an old question, but the proposed answers doesn't work correctly for some types such as function reference type or cv-qualified function types.

template<typename T, typename = void>
struct is_complete_object : std::false_type {};

template<typename T>
struct is_complete_object<T, std::enable_if_t<(sizeof(T) > 0)>> : std::true_type {};

template<typename T, bool v = std::is_object<T>::value /* true */>
struct is_complete_impl : is_complete_object<T> {};

template<typename T>
struct is_complete_impl<T, false> : std::integral_constant<bool, !std::is_void<T>::value> {};

template <typename T>
struct is_complete : is_complete_impl<T> {};

template<typename T>
struct is_complete<T[]> : std::false_type {};

template<typename T, size_t N>
struct is_complete<T[N]> : is_complete<T> {};

Now this will work for function-like types.

Answer 9

With C++17 it is possible to use variadic std::void_t with sizeof operator.

Moreover, with sizeof operator it is also possible to check if a not fully specialized class template "is" (that is would be upon instantiation) complete or not.

You just have to define a dummy tag, which is a complete type.

struct any_t
{
};

template<template<typename> class, typename = void>
struct is_complete : std::false_type
{
};

template<template<typename> class GenericClass>
struct is_complete<GenericClass, std::void_t<decltype(sizeof(GenericClass<any_t>))>> :
  std::true_type
{
};

template<typename T>
struct complete
{
    T t;
    void speak() { return t.speak(); }
};

template<typename>
struct incomplete;

static_assert(is_complete<complete>());
static_assert(!is_complete<incomplete>());

Any invocations of t in complete will cause compilation errors only if you try to instantiate an object.

using t = complete<any_t>; // ok
auto c = complete<any_t>(); // error. any_t has no member `speak()`