Is it possible to check if a template type has been instantiated at compile time so that I can use this information in an enable_if specialization?

Let's say I have

template <typename T> struct known_type { };

Can I somehow define some is_known_type whose value is true if known_type is instantiated at compile time?

  • Could you please show an example using this kind of information in an enable_if? – erenon Jan 27 '15 at 20:59
  • The accepted answer does not appear to work on newer compilers. It seems that the answer depends on some GCC compiler bugs and the solution does not work on standard conforming compilers. – Ralph Tandetzky Jan 2 '16 at 0:47
up vote 16 down vote accepted

It's possible to do this if you leverage the fact that specific expressions may or may not be used in places where constexprs are expected, and that you can query to see what the state is for each candidate you have. Specifically in our case, the fact that constexprs with no definition cannot pass as constant expressions and noexcept is a guarantee of constant expressions. Hence, noexcept(...) returning true signals the presence of a properly defined constexpr.

Essentially, this treats constexprs as Yes/No switches, and introduces state at compile-time.

Note that this is pretty much a hack, you will need workarounds for specific compilers (see the articles ahead) and this specific friend-based implementation might be considered ill-formed by future revisions of the standard.

With that out of the way...

User Filip Roséen presents this concept in his article dedicated specifically to it.

His example implementation is, with quoted explanations:

constexpr int flag (int);

A constexpr function can be in either one of two states; either it is usable in a constant-expression, or it isn't - if it lacks a definition it automatically falls in the latter category - there is no other state (unless we consider undefined behavior).

Normally, constexpr functions should be treated exactly as what they are; functions, but we can also think of them as individual handles to "variables" having a type similar to bool, where each "variable" can have one of two values; usable or not-usable.

In our program it helps if you consider flag to be just that; a handle (not a function). The reason is that we will never actually call flag in an evaluated context, we are only interested in its current state.

template<class Tag>
struct writer {
  friend constexpr int flag (Tag) {
    return 0;
  }
};

writer is a class template which, upon instantiation, will create a definition for a function in its surrounding namespace (having the signature int flag (Tag), where Tag is a template-parameter).

If we, once again, think of constexpr functions as handles to some variable, we can treat an instantiation of writer as an unconditional write of the value usable to the variable behind the function in the friend-declaration.

template<bool B, class Tag = int>
struct dependent_writer : writer<Tag> { };

I would not be surprised if you think dependent_writer looks like a rather pointless indirection; why not directly instantiate writer where we want to use it, instead of going through dependent_writer?

  1. Instantiation of writer must depend on something to prevent immediate instantiation, and;
  2. dependent_writer is used in a context where a value of type bool can be used as dependency.
template<
  bool B = noexcept (flag (0)),
  int    =   sizeof (dependent_writer<B>)
>
constexpr int f () {
  return B;
}

The above might look a little weird, but it's really quite simple;

  1. will set B = true if flag(0) is a constant-expression, otherwise B = false, and;
  2. implicitly instantiates dependent_writer (sizeof requires a completely-defined type).

The behavior can be expressed with the following pseudo-code:

IF [ `int flag (int)` has not yet been defined ]:
  SET `B` =   `false`
  INSTANTIATE `dependent_writer<false>`
  RETURN      `false`
ELSE:
  SET `B` =   `true`
  INSTANTIATE `dependent_writer<true>`
  RETURN      `true`

Finally, the proof of concept:

int main () {
  constexpr int a = f ();
  constexpr int b = f ();
  static_assert (a != b, "fail");
}

I applied this to your particular problem. The idea is to use the constexpr Yes/No switches to indicate whether a type has been instantiated. So, you'll need a separate switch for every type you have.

template<typename T>
struct inst_check_wrapper
{
    friend constexpr int inst_flag(inst_check_wrapper<T>);
};

inst_check_wrapper<T> essentially wraps a switch for whatever type you may give it. It's just a generic version of the original example.

template<typename T>
struct writer 
{
    friend constexpr int inst_flag(inst_check_wrapper<T>) 
    {
        return 0;
    }
};

The switch toggler is identical to the one in the original example. It comes up with the definition for the switch of some type that you use. To allow for easy checking, add a helper switch inspector:

template <typename T, bool B = noexcept(inst_flag(inst_check_wrapper<T>()))>
constexpr bool is_instantiated()
{
    return B;
}

Finally, the type "registers" itself as initialized. In my case:

template <typename T>
struct MyStruct
{
    template <typename T1 = T, int = sizeof(writer<MyStruct<T1>>)>
    MyStruct()
    {}
};

The switch is turned on as soon as that particular constructor is asked for. Sample:

int main () 
{
    static_assert(!is_instantiated<MyStruct<int>>(), "failure");
    MyStruct<int> a;
    static_assert(is_instantiated<MyStruct<int>>(), "failure");
}

Live on Coliru.

  • I fear, this will not work with multiple translation units. – Dieter Lücking May 19 '15 at 16:35
  • Is this what "Black magic" supposed to mean? – Guillaume Racicot Dec 8 '15 at 16:17
  • 1
    @GuillaumeRacicot it's Templatemancy. – user932887 Dec 8 '15 at 16:40
  • I checked your "proof of concept" on different compilers. It works for older compilers: gcc 4.7, 4.8 and 4.9 in C++11 mode. However, it does not work for the newer compilers gcc 5.2 and clang 3.6. I checked all modes: C++11, C++14 and C++17. It appears that the default template arguments are not decided upon at the time of instantiation, but at the time default template arguments are written out the first time. And this makes sense, since all else will lead to strange problems regarding the one-definition rule (ODR). – Ralph Tandetzky Jan 2 '16 at 0:44
  • @RalphTandetzky Why is that implementation odr-problematic if all the functions involved are constexpr which implies inline? – Peregring-lk Oct 23 '17 at 21:05

No, a compile time check for not instantiated classes is not possible. However you might establish a (static) map of instantiated classes (in debug build), which you can check at run time.

However, analyzing the linked binary by comparing a list of expected instantiated classes with actually instantiated classes should be possible (but that is past compile time and past my knowledge).

  • my problem is solving overlapping partial specializations of a struct, i have a specialization that should be applied only for known types that are not really known until compile time cause it's a template library i'm writing – tuccio Jan 27 '15 at 22:54

There's is no way to do that. So I would say: No.

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