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Since it is possible that a function declared as constexpr can be called during run-time, under which criteria does the compiler decide whether to compute it at compile-time or during runtime?

template<typename base_t, typename expo_t>
constexpr base_t POW(base_t base, expo_t expo)
    return (expo != 0 )? base * POW(base, expo -1) : 1;

int main(int argc, char** argv)
    int i = 0;
    std::cin >> i;

    std::cout << POW(i, 2) << std::endl;
    return 0;

In this case, i is unknown at compile-time, which is probably the reason why the compiler treats POW() as a regular function which is called at runtime. This dynamic however, as convenient as it may appear to be, has some impractical implications. For instance, could there be a case where I would like the compiler to compute a constexpr function during compile-time, where the compiler decides to treat it as a normal function instead, when it would have worked during compile-time as well? Are there any known common pitfalls?

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AFAIK, when all arguments are constant expressions. – chris Jan 9 '13 at 23:19
@chris And what if I write POW((unsigned __int64)2, 63). Would that still count as a constant expression? – CaffeineAddict Jan 9 '13 at 23:21
@chris: Actually, it's more complex than that I think. I think constexpr is only required to be evaluated when its result is used as a template parameter, array bound, or other integral constant. Any other time is an optimization. In fact, even when given constant expression arguments, it might be required to execute at runtime. constexpr int func(int p) { return !p ? 1 : throw std::exception("HI");} must be evaluated at runtime when given a non-zero input. – Mooing Duck Jan 9 '13 at 23:21
Initializers that are constant expressions form part of the static initialization phase, e.g. constexpr int a = POW(5, 4);. That's essentially computed at compile time. But you can of course still use POW in other places. – Kerrek SB Jan 9 '13 at 23:23
@MooingDuck: Unless the result of the function is being used in your aforementioned constant expression "requirerers", then it will give a compile-time error because of the exception. – GManNickG Jan 9 '13 at 23:34
up vote 56 down vote accepted

constexpr functions will be evaluated at compile time when all its arguments are constant expressions and the result is used in a constant expression as well. A constant expression could be a literal (like 42), a non-type template argument (like N in template<class T, size_t N> class array;), an enum element declaration (like Blue in enum Color { Red, Blue, Green };, another variable declared constexpr, and so on.

They might be evaluated when all its arguments are constant expressions and the result is not used in a constant expression, but that is up to the implementation.

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@mcmcc try using the result as an non-type template parameter. this should cover integral constexpr. for float you need something else. – TemplateRex Jan 11 '13 at 19:39
@rhalbersma: It's the "something else" that I'm puzzled by... – mcmcc Jan 11 '13 at 19:42
Where in the Standard is there a guarantee that constexpr functions are evaluated at compile time if all arguments are constant expressions? I believe the only thing the Standard says is that constexpr functions can be used in contexts that must be evaluated at compile time, e.g. template arguments. Anything else is up to the compiler to decide. At least that is what I've believed so far. – jogojapan Jan 16 '13 at 4:36
@jogojapan: According to both Bjarne and Herb back at the ISO C++ post, "The correct answer - as stated by Herb - is that according to the standard a constexpr function may be evaluated at compiler time or run time unless it is used as a constant expression, in which case it must be evaluated at compile-time.". That would mean that a in your example must be evaluated at compile-time, and doesn't make the note downright wrong. I'm not sure this is actually guaranteed by the standard at this point... – K-ballo Jan 16 '13 at 6:37
@mcmcc: For your "something else", why not write a constexpr function that accepts a floating-point value (or in fact any type you like) and returns an integer, then use that inside a template non-type parameter. constexpr size_t check_nonintegral_constexpr(float v) { return sizeof v; } std::array<check_nonintegral_constexpr(pow(2.0, 4))> assertion; – Ben Voigt Apr 1 '13 at 21:59

The function has to be evaluated at compile-time when a constant expression is needed.

The simplest method to guarantee this is to use a constexpr value, or std::integral_constant:

constexpr auto result = POW(i, 2); // this should not compile since i is not a constant expression
std::cout << result << std::endl;


std::cout << std::integral_constant<int, POW(i, 2)>::value << std::endl;


#define POW_C(base, power) (std::integral_constant<decltype(POW((base), (power)), POW((base), (power))>::value)

std::cout << POW_C(63, 2) << std::endl;


template<int base, int power>
struct POW_C {
  static constexpr int value = POW(base, power);

std::cout << POW_C<2, 63>::value << std::endl;
share|improve this answer
Does that mean that std::cout << POW(2, 63) << std::endl could end up not being evaluated during compile-time, since cout doesn't require a constant expression value? – CaffeineAddict Jan 9 '13 at 23:30
@cyberpunk_ the example code I posted is what does that. – Pubby Jan 9 '13 at 23:40
@cyberpunk_ The arguments to constexpr functions are not constant expressions and so that wouldn't help. – Pubby Jan 9 '13 at 23:48
@cyberpunk_: You should use references for that. (Not that copying a compile-time value is going to cost anything...) – GManNickG Jan 10 '13 at 1:05
@balki Here is what I came up with, but I am not sure if it's the best possible solution. I am also not sure if returning an rvalue reference actually works this way. #define FORCE_CT_EVAL(func) [](){constexpr auto ___expr = func; return std::move(___expr);}() – CaffeineAddict Jan 12 '13 at 13:46

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