I've been messing around with an SVN build of clang to experiment with the relaxed rules for constexpr. One of the things I've been unable to determine as of yet is whether it's possible to loop through the elements inside a tuple at compile-time in a constexpr function.

Because I don't have a C++14 compliant standard library to test on, I've prepared the following equivalent test:

template<int N>
constexpr int foo() {
  return N;

constexpr int getSum() {
  auto sum = 0;
  for (auto i = 0; i < 10; ++i) {
    sum += foo<i>();
  return sum;

constexpr auto sum = getSum();

The interesting part here is foo<i>(). In a non-constexpr function I would expect this to fail to compile, because you simply cannot use a runtime int to generate a compile-time instantiation of a template. Because this is a constexpr function, however, I question whether this would be possible. In particular, the value is known at compile-time, even if it is allowed to mutate.

I know that the following code will compile:

constexpr auto nValue = 2;

In SVN clang, my first example does not:

test2.cpp:19:12: error: no matching function for call to 'foo'
    sum += foo();
test2.cpp:11:15: note: candidate template ignored: invalid explicitly-specified
      argument for template parameter 'N'
constexpr int foo() {

For starters, I struggle to interpret the second part of this error message. That aside, is it mandated by the C++14 standard, and if so, does anyone know why this syntax wouldn't be allowed (simple oversight or to protect against something)?

  • 1
    I think that the error is caused by the fact that i and sum are not constexpr. – Shoe Dec 7 '13 at 3:25
  • 2
    @Jefffrey - Yes, I understand that, but that would make them immutable, which does not seem conceptually necessary. Also, auto is not about typing convenience, it's about correctness, performance, and maintainability. The arguments apply equally well to primitives. Reference: herbsutter.com/2013/08/12/… – Mark Dec 7 '13 at 3:37
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    Templates are instantiated at compile time, so template parameters must be constant expressions. It may not be "conceptually necessary," but for now that's how the language is specified. And please, let's not start a holy war over what is essentially a question of style. – Casey Dec 7 '13 at 3:39
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    @Mark You're looking for § 5.19 in the C++11 standard. It's under [expr.const] – Rapptz Dec 7 '13 at 3:48
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    @Jefffrey - I gave the general reasons. Here it is about maintainability, as it is unlikely I'd introduce a conversion. If I decide to go from int to long long, I can. I recently had to go from double to long double in a project where this proved most useful. In general, it is a good habit, the primitives aren't really all that special, let's not treat them like they are. Let's also end this now - read the gotw, if you agree, great, if not, let's go our separate ways. – Mark Dec 7 '13 at 3:54

That aside, is it mandated by the C++14 standard, and if so, does anyone know why this syntax wouldn't be allowed (simple oversight or to protect against something)?

That's because constexpr is not exclusive to compile-time computations or usage. A constexpr function is just that, allowing a function (or variable) to be used in a constant expression. Outside of that, they're regular functions. A constant expression just so happens to be required in certain contexts such as static_assert or array sizes, etc that are compile-time only situations.

You'll notice in your code that you loop through a variable but the variable you're looping through itself isn't constexpr so it isn't a constant expression to be used in that template instantiation of N. As it stands, it's no different than doing this in C++11:

constexpr bool f(int x) {
    static_assert(x > 10, "..."); // invalid
    return true;

Which is obviously invalid because as I mentioned earlier, you don't have to use constexpr functions in exclusive compile-time situations. For example, nothing is stopping you from doing this:

constexpr int times_ten(int x) {
    return x * 10;

int main() {
   int a = times_ten(20); // notice, not constexpr
   static_assert(times_ten(20) == 200, "...");
   static_assert(a == 200, "..."); // doesn't compile
  • This argument makes sense, but I've already found cases where constexpr functions will compile only if input parameters are constexpr. This was also because of code in the body, not the function signature; I don't see why this should be any different. The compiler can (theoretically) selectively allow it if it knows that the function is, in fact, being evaluated at compile-time. – Mark Dec 7 '13 at 3:40
  • @Mark Unfortunately, as far as the language is concerned template parameters must be constant expressions and one way to enable that as far as the language is concerned is constexpr, so the variable you're looping through has to be constexpr. – Rapptz Dec 7 '13 at 3:44

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