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.

  • 15
    I think this cannot work in principle (except when you always apply it to a type that always stays incomplete, or is always complete). Because whether U is complete or not, is_complete<U> always specifies the same type. If you now go and use is_complete<U> in two different translation units, the value member would possibly have a different value each time and the compiler is free in what value it uses. This is not valid i think, but i can't find a statement of the Standard about this :( Would be glad if you could find out. Oct 26, 2009 at 15:09
  • The bigger question is why. Without reflection why do you need this as the compiler knows at compiler time. Oct 26, 2009 at 15:43
  • There is also no way in C++03 this can be done. Atmost with C++0x with "sfinae for expressions" but even then if you pass vector<int> for example and vector is only declared but not defined, then the check for completeness will yield to an implicit instantiation, and if the definition is not available will issue an hard error that's not covered by sfinae (the error is not in the "immediate context"). Oct 26, 2009 at 15:47
  • 1
    @litb: I would say this is handled with a combination of 14.4/1 (Type equivalence for template-id's) and then 3.2/5 bullet 2 which requires that names refer to the same entity. If the same template-id results in a name referring to different entities then that's an ODR violation. Oct 26, 2009 at 16:43
  • 1
    The compiler knows that a type is here incomplete, and then complete perhaps a few lines later; say after a new declaration or specialisation. Surely that information could, in principle, be made available. Jun 21, 2016 at 23:16

9 Answers 9


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

    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.

  • __COUNTER__ is supported by MSVC and with gcc starting from 4.3. However, with gcc, the problem isn't really in forging different is_complete types with the help of __COUNTER__ but having the compiler do SFINAE and select the pass(...) overload. Dec 25, 2009 at 10:33
  • 1
    This doesn't seem to be compatible with complete abstract types. On MSVC 2008 IS_COMPLETE(MyAbstractClass) fails to compile. And even if the compiler did allow this and was able to do the SFINAE with the abstract type, it seems that it would give the incorrect answer (i.e. it would report that a complete abstract type was in fact incomplete).
    – bshields
    Jul 5, 2011 at 9:22
  • 8
    This violates the ODR rule. The counter gets you multiple different specializations in one translation unit, but if you use it in a second file, the same specialization will get an incompatible definition. The solution is to put it in an unnamed namespace. Jul 16, 2013 at 8:32
  • 2
    __LINE__ can be used instead of __COUNTER__. __LINE__ is standard.
    – anton_rh
    Jul 26, 2021 at 5:26
  • My answer works without a macro.
    – user541686
    Sep 18, 2021 at 12:45

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?

  • 3
    Worked perfectly for me on all compilers I tested, and follows a more familiar style for custom type traits, without relying on the implementation specific __COUNTER__ value. I believe this is a better solution than the accepted answer. Aug 14, 2018 at 23:20
  • 3
    This doesn't seem to work if I forward declare a type, use this trait, then define it and use it again. It yields false for on both. Tried on gcc.godbolt.org with trunk GCC/Clang. gcc.godbolt.org/z/pegeNa
    – SLC
    Apr 29, 2019 at 12:15
  • 2
    @SanduLiviuCatalin Works fine like this: gcc.godbolt.org/z/HFGdZA. So I guess you've found a bug you can workaround by reordering your definitions. I think this is related to the fact the template is evaluated once in this compilation unit.
    – mister why
    Sep 11, 2019 at 12:03
  • Note that this does not return the correct value for function types because sizeof cannot be applied to function types.
    – Fido
    Feb 20, 2022 at 19:51
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;
  • 5
    Nice, but as @litb says in his comment, it doesn't work properly if is_complete<type> appears in 2 contradicting locations in the same file, when the definition of class type appears between them (I tried :) ).
    – Asaf
    Oct 26, 2009 at 15:11
  • fails here with error: initializing argument 1 of ‘static char (& is_complete<T>::pass(T))[2] [with T = Foo]’ Dec 22, 2009 at 23:32
  • It does not work with modern GCC or Clang: gcc.godbolt.org/z/z5cYWjeaE
    – Fedor
    Jul 29, 2021 at 15:06

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.


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.

  • Question regarding this point: "A template instantiated on an incomplete type must not do anything differently from if it were instantiated on a complete type." If we ensure that a template is not simultaneously instantiated on both the incomplete and the complete versions of the same type, is that still an ODR violation, or is that fine?
    – user541686
    Sep 18, 2021 at 13:15
  • The requirement is applied at each place the instantiation is used and then again at the end of each translation unit. So no. The principle is that types don’t have changing versions. Sep 18, 2021 at 14:05

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.

  • "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" indeed, a user defined type is not inherently complete or incomplete, it is only incomplete until it is completed (void is inherently incomplete). So the whole idea is extremely problematic.
    – curiousguy
    May 24, 2014 at 3:25
  • 1
    sizeof is ill-formed for incomplete types and cannot yield zero, since C++98: "The sizeof operator shall not be applied to an expression that has … incomplete type, … or to the parenthesized name of such types." GCC's treatment is nonconforming, but it's a good idea to support it anyway if writing such a facility. Jul 24, 2015 at 1:33
  • "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." -- Apparently no compiler works this way even in the simplest situations (live on godbolt: example 1, example 2).
    – Dr. Gut
    Apr 6, 2020 at 0:18

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.


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.


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>))>> :

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

struct 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()`

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.