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With constexpr, A function can be evaluated at compile time or runtime depending upon the arguments. But usually, the algorithm has to be different between compile time and runtime. Eg. Consider the constexpr version of factorial.

constexpr int fact(int n)
return (n)?n*fact(n-1):1;

If n happens be at runtime wont the function be inefficient than one forloop? Is there some template magic to determine if the function is being executed at compile time or run time and use different algorithm?

factorial was just an example. Is all constexpr functions be as efficient as they would be if coded without constexpr restrictions? Eg:

constexpr int combinations(int n, int k)
//Assume all error conditions and edge conditions are taken care with ternary operator ?:
return fact(n)/(fact(k)*fact(n-k);

If the function is written in runtime, it can benefit from Memoization. Even this was possible, I guess it will be difficult to express the function such that it is both constexpr and also as efficient as possible in runtime.

share|improve this question
It doesn't answer you question, but the function will not be inefficient if your compiler optimizes for tail recursion. – Eduardo Jan 18 '13 at 8:11
@Eduardo The compiler needs to do more here since the function is not tail recursive. Modern compilers can optimise this in simple enough cases though (OP’s example would be optimised). – Konrad Rudolph Jan 18 '13 at 8:21
No, there is no way in the current language to check when a constexpr function is being executed - the compiler may decide on a rand() % 2 == 0 whim whether or not to evaluate the function at compile- or runtime (assuming that the preconditions for it actually being evaluated at compile-time are present). – Xeo Jan 18 '13 at 8:34
@Xeo: well, if the result need be a compile-time constant (template parameter, static <built-in> const, ...) then you can ensure the computation is done at compile-time; obviously this does not answer the question though. – Matthieu M. Jan 18 '13 at 10:00
@KonradRudolph: you are right; it has to multiply the result by n after the call. Thanks for the correction. – Eduardo Jan 18 '13 at 10:35

No, as far as I know you can't detect how the compiler is using the function in a given call, or direct the compiler to use different implementations depending on constness.

But first of all, a constexpr function is restricted to a single return statement, which means that the compiler can (most often) easily apply tail recursion optimization, turning a recursive call into a loop. Thus, this question is about how to do premature optimization, which is not a good idea. Low level optimization is the compiler's job: let it.

Secondly, if you really really want to do the compiler's job then you can just name the functions, instead of trying to senselessly cram two different function implementations into a single one. For what purpose would that serve? Only obscurity.

For the particular example given,

constexpr int fact(int n)
    return (n)?n*fact(n-1):1;

the compiler has to recognize that it can be rewritten as tail-recursive. As I recall from my testing for an earlier SO question about it, even the Visual C++ compiler does that. Although for some inexplicable reason (possibly having to do with the original x86 processor design) it was stumped by use of floating point type: same high level logic, different low level result.

As a slightly less drastic help-the-compiler work effort, after having measured and found that this function is the one that makes your app unacceptably slow, and after having inspected the machine code and found that the compiler fails to recognize the function's tail-recursiveness, you can rewrite it as follows:

constexpr int fact( int multiplier, int n )
    return (n != 0? fact( multiplier*n, n-1 ) : multiplier);

constexpr int fact( int n )
    return fact( 1, n );

Disclaimer: code not touched by compiler's dirty hands.

share|improve this answer
Unless you have a really relaxed floating-point mode, the floating-point version can't be rewritten automatically, because it changes the semantics of floating-point traps. The original one can produce an overflow trap after recursion, the almost-equivalent may only trigger it before recursion. Also, floating-point multiplication isn't commutative/distributive, and the almost-equivalent multiplies n*(n-1)*(n-2)*...*2 whereas the original multiplies 2*3*4*...n. – Ben Voigt Jan 18 '13 at 13:48
@BenVoigt: for the ordinary SO reader I think it's best to also mention that for a result that's within the range of integers that can be represented exactly by the floating point type, which is about 51 bits for ordinary 64-bit IEEE 754, the floating point multiplication is exact and commutative (and distributive). anyway, thanks! i didn't think of either possibility that you mention, only about machine code level synchronization of the floating point processing. – Cheers and hth. - Alf Jan 18 '13 at 14:07
@Alf: Yes, the differences are likely to only affect the last couple bits of the computed precision, which is 80-bits or more on x86 CPUs. So there should be no change after rounding to double precision. (In the general case fixed-precision floating-point math is not commutative/distributive at any precision, but a factorial product behaves much better than the general case. Whether the compiler can deduce that this is a well-behaved case is doubtful.) – Ben Voigt Jan 18 '13 at 14:23
Also, I think the part of this answer that claims that it's senseless to overload a function name is quite ridiculous. – Ben Voigt Jan 18 '13 at 14:56
@BenVoigt: sorry, your statement that I've "claims that it's senseless to overload a function name" is incorrect, just completely fabricated, and you know it. and you're trying to make readers believe it. hence, you're lying. also, your "also" is implying that your claim is an observation about incorrectness/absurdity that comes in addition to some earlier such observation. well it ain't an observation (it's just a misleading claim on your part) and it doesn't come in addition to any earlier observation. and you know also that. hence, also that a lie. sorry about nailing those two lies. – Cheers and hth. - Alf Jan 18 '13 at 15:15

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