I have been trying out const expressions which are evaluated at compile time. But I played with an example that seems incredibly fast when executed at compile time.


constexpr long int fib(int n) { 
    return (n <= 1)? n : fib(n-1) + fib(n-2); 

int main () {  
    long int res = fib(45); 
    std::cout << res; 
    return 0; 

When I run this code it takes about 7 seconds to run. So far so good. But when I change long int res = fib(45) to const long int res = fib(45) it takes not even a second. To my understanding it is evaluated at compile time. But the compilation takes about 0.3 seconds

How can the compiler evaluate this so quickly, but at runtime it takes so much more time? I'm using gcc 5.4.0.

  • 7
    I conjecture that the compiler caches the the function calls to fib. The implementation of the fibonacci numbers you have above is preeeeeetty slow. Try caching the function values in runtime code and it will much faster.
    – n314159
    Jan 23, 2020 at 7:23
  • 4
    This recursive fibonacci is terribly inefficient (it has an exponential runtime), so my guess is that the compile time evaluation is more clever than this and optimizes the calculation.
    – Blaze
    Jan 23, 2020 at 7:23
  • 1
    @AlanBirtles Yes I compiled it with -O3.
    – Peter234
    Jan 23, 2020 at 7:24
  • 1
    I we assume that the compiler caches function calls the function needs to be eveluated only 46 times (once for each possible argument 0-45) instead of 2^45 times. However I don't know if gcc works like that.
    – Lukas-T
    Jan 23, 2020 at 7:33
  • 3
    @Someprogrammerdude I know. But how can the compilation be so quick when the evaluation takes so much time at runtime?
    – Peter234
    Jan 23, 2020 at 7:44

2 Answers 2


The compiler caches smaller values and does not need to recompute as much as the runtime version does.
(The optimiser is very good and generates lots of code including trickery with special cases that are incomprehensible to me; the naive 2^45 recursions would take hours.)

If you also store previous values:

int cache[100] = {1, 1};

long int fib(int n) {
    int res = cache[n];
    return res ? res : (cache[n] = fib(n-1) + fib(n-2));

the runtime version is much faster than the compiler.

  • There is no way to avoid recursing twice, unless you do some caching. Do you think the optimizer implements some caching? Are you able to show this in the compiler output, as that would be really interesting?
    – Suma
    Jan 23, 2020 at 8:29
  • ... it is also possible compiler instead of caching compiler is able to prove some relationship between fib(n-2) and fib(n-1) and instead of calling fib(n-1) it uses to fib(n-2) value to compute that. I think that matches what I see in the output of 5.4 whne removing constexpr and using -O2.
    – Suma
    Jan 23, 2020 at 8:32
  • 1
    Do you have a link or other source that explains what optimizations can be done at compile time?
    – Peter234
    Jan 23, 2020 at 8:33
  • As long as the observable behaviour is unchanged, the optimizer is free to do almost anything. Given fib function has no side effects (references no external variables, output depends on inputs only), with a clever optimizer a lot can be done.
    – Suma
    Jan 23, 2020 at 8:35
  • @Suma It's no problem to recurse only once. Since there is an iterative version, there is of course also a recursive version, that uses for example tail recursion.
    – Ctx
    Jan 27, 2020 at 9:21

You may find interesting with 5.4 the function is not completely eliminated, you need at least 6.1 for that.

I do not think there is any caching happening. I am convinced the optimizer is smart enough to prove relationship between fib(n - 2) and fib(n-1) and avoids the second call completely. This is GCC 5.4 output (obtained from godbolt) with no constexpr and -O2:

        cmp     rdi, 1
        push    r12
        mov     r12, rdi
        push    rbp
        push    rbx
        jle     .L4
        mov     rbx, rdi
        xor     ebp, ebp
        lea     rdi, [rbx-1]
        sub     rbx, 2
        call    fib(long)
        add     rbp, rax
        cmp     rbx, 1
        jg      .L3
        and     r12d, 1
        lea     rax, [r12+rbp]
        pop     rbx
        pop     rbp
        pop     r12
        xor     ebp, ebp
        jmp     .L2

I have to admit I do not understand the output with -O3 - the code generated is surprisingly complex, with lots of memory accesses and pointer arithmetics and it is quite possible there is some caching (memoization) done with those settings.

  • I think I am wrong. There is a loop at .L3, and the fib is looping over all lower fibs. With -O2 it is still exponential.
    – Suma
    Jan 23, 2020 at 8:51

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