The following code compiles without problems in g++:

#include <iostream>
#include <string>
#include <tuple>

template<typename T>
void test(const T& value)
    std::tuple<int, double> x;
    std::cout << std::get<value>(x);

int main() {

I used this command:

g++ test.cpp -o test -std=c++14 -pedantic -Wall -Wextra

But when I switch g++ to clang++ (with g++ 5.1.0 and clang++ 3.6.0), I get the following errors:

test.cpp:9:18: error: no matching function for call to 'get'
    std::cout << std::get<value>(x);
test.cpp:13:5: note: in instantiation of function template specialization 'test<std::integral_constant<unsigned long, 1> >' requested here

/usr/bin/../lib/gcc/x86_64-linux-gnu/5.1.0/../../../../include/c++/5.1.0/tuple:867:5: note: candidate template ignored: invalid explicitly-specified argument for template parameter '_Tp'
    get(tuple<_Types...>& __t) noexcept

And similar note: entries for other overloads of std::get.

But I'm passing std::integral_constant to test(), which is a constant-expression, why would it be an "invalid explicitly-specified argument" for the template parameter? Is it a clang bug or am I doing something wrong here?

I've noticed that if I change parameter for test() from const T& to const T, then clang compiles successfully. Do I somehow lose constexpr quality of integral_constant by passing it by reference?

  • Can std::get accept std::integral_constant as a template parameter at all? For example, this is rejected by gcc.
    – Petr
    Nov 23, 2015 at 13:27
  • And why don't you just pass startingIndex to operation instead of wrapping it into std::integral_constant?
    – Petr
    Nov 23, 2015 at 13:29
  • @Petr you forgot to instantiate it. There's a constexpr conversion operator.
    – Ruslan
    Nov 23, 2015 at 13:29
  • @Petr for the second comment, function arguments can't be constexpr. Hmm... I seem to start losing my understanding here... integral_constant is also an argument, why does gcc compile it?..
    – Ruslan
    Nov 23, 2015 at 13:30
  • 1
    @Petr Indeed... but passing integral_constant to a separate template function seems to do: here.
    – Ruslan
    Nov 23, 2015 at 13:37

1 Answer 1


As there is no answer for a week, I will post my vision. I am far from being an expert at language-laywering, actually I would consider myself a complete novice, but still. The following is based on my reading of standard, as well on my recent question.

So, first of all let's rewrite the code the following way:

struct A {
    constexpr operator int() const { return 42; }

template <int>
void foo() {}

void test(const A& value) {

int main() {
    A a{};

It exhibits the same behavior (builds with gcc and fails with similar error with clang), but:

  • is free from template type deduction at test(), to make sure the problem has nothing to do with type deduction,
  • uses 'mocks' instead of std members to make sure this is not a problem with their implementation,
  • and has an explicit variable a, not a temporary, to be explained later.

What does happen here? I will quote N4296.

We have a template foo with a non-type parameter.


A template-argument for a non-type template-parameter shall be a converted constant expression (5.20) of the type of the template-parameter.

So template argument, i.e. value, should be a converted constant expression of type int.


A converted constant expression of type T is an expression, implicitly converted to type T, where the converted expression is a constant expression and the implicit conversion sequence contains only

  • user-defined conversions,
  • ... (irrelevant bullets dropped)

and where the reference binding (if any) binds directly.

Our expression (value) can be implicitly converted to type int, and the conversion sequence contains only user-defined conversions. So the two questions remain: whether "the converted expression is a constant expression" and whether "the reference binding (if any) binds directly".

For the first question, the phrase "the converted expression", I think, means the expression as already converted to int, that is something like static_cast<int>(value), not the original expression (value). For that,


A conditional-expression e is a core constant expression unless the evaluation of e, following the rules of the abstract machine (1.9), would evaluate one of the following expressions:

  • ... (a long list omitted)

Evaluation of our expression, static_cast<int>(value), leads only to evaluation of A::operator int(), which is constexpr, and thus is explicitly allowed. No members of A (if there were any) are evaluated, neither anything else is evaluated.

Therefore, static_cast<int>(value) is a constant expression.

For the second question, about reference binding, it is not clear for me to which process this refers at all. However, anyway we have only one reference in our code (const A& value), and it binds directly to the variable a of main (and this is the reason why I introduced a).

Indeed, direct binding is defined at the end of [8.5.3(dcl.init.ref)]/5:

In all cases except the last (i.e., creating and initializing a temporary from the initializer expression), the reference is said to bind directly to the initializer expression.

This "last" case seem to refer to 5.2, and non-direct binding means initialization from a temporary (like const int& i = 42;), not our case when we have a non-temporary a.

UPD: I asked a separate question to check whether my understanding of the standard, presented above, is correct.

So the bottomline is that the code should be valid, and clang is wrong. I suggest you filing a bug to clang bug tracker, with a reference to this question. Or if for whatever reason you will not file a bug, let me know, I will file it.

UPD: filed a bug report

  • 1
    As you seem to be much better than me at reading the Standard, I think it'd be better if you filed the bug report. (I'd like to have a link to follow it though if you do.)
    – Ruslan
    Dec 1, 2015 at 11:18
  • @Ruslan, ok, but let's first wait for the results of another my question to check whether my reading is correct.
    – Petr
    Dec 1, 2015 at 11:34
  • I just wanted to add that, a year later, as of Dec 2016, this bug is still present in clang. I'm running the bleeding edge of clang (clang version 4.0.0-svn288882-1~exp1 (trunk)), and I just encountered this bug. Dec 13, 2016 at 7:41
  • There is no bug. This code snippet is ill-formed for violating [expr.const]/2.11. Evaluating the equivalent of static_cast<int>(value) necessitates evaluating the id-expression value.
    – T.C.
    Mar 27, 2017 at 19:44
  • 1
    Actually, value doesn't have a "preceding initialization" at all. The definition of test, a non-template function, is either well-formed or ill-formed. That can't depend on how it is called.
    – T.C.
    Mar 28, 2017 at 8:21

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.