Boost: computing the factorial of a small integer at compile time

I just implemented (once again) a recursive template for computing the factorial of an integer at compile time (who would had thought that some day I'll actually need it!). Still, instead of rolling my own, I went to boost looking for an answer. However, the factorial function in special math specifically forbids its use with integer types, so I just wrote my own.

Still, is there another function in boost that I should use? Should I cast my integer to double and use the boost::factorial function? Is the computation performed at compile time?

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There's a limited depth at which a template can recurse to, so IRL the speedup from computing the factorial at compile-time isn't that great (esp. if you use dynamic programming). – Luchian Grigore Jul 31 '12 at 17:59
See "R.."'s response under this question: stackoverflow.com/questions/3786207/…. Overflow is very likely why Boost doesn't want you to use an int for this. – mwigdahl Jul 31 '12 at 18:02
I can't believe someone actually needs to calculate factorials at compile-time... – Mehrdad Jul 31 '12 at 18:23
@mwigdahl I can fit up to 20! into an unsigned long int which is more than what I need (however, checking for overflow would be one of the reasons that push me to prefer using a library function, my implementation does not check for it). – gnzlbg Jul 31 '12 at 18:23
are you using gcc? – pyCthon Jul 31 '12 at 18:28

You don't need Boost, this is just 1-liner if you have C++11:

``````constexpr uint64_t factorial(uint64_t n) {
return n == 0 ? 1  :  n * factorial(n-1);
}
``````

And it will work even if your arg is not compile time constant too. uint64_t will work with n < 21.

If you are doing it in compile time and multiply with floating point value - there will be no conversion overhead (conversion will be at compile time too).

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+1 for constexpr! – pyCthon Jul 31 '12 at 18:23
Yeah that's the cheap way of doing it. :) – Mehrdad Jul 31 '12 at 18:24
Nice! Way better than templates :) I was using static_cast<double>(n!), not really necessary tho. I'll just do a static_assert for n < 21 and that should do :D – gnzlbg Jul 31 '12 at 18:29
@gnzlbg: Note that you cannot use static_assert here. See stackoverflow.com/questions/8626055/… – Leonid Volnitsky Jul 31 '12 at 18:43
@LeonidVolnitsky I know :D I only need to call the function three times so I assert their size at the beginning but if I need to use it more often I might just fall back to the recursive template in order to integrate the assertion :) – gnzlbg Jul 31 '12 at 21:02

Since there are a limited number of factorials that can fit inside an integer, you can simply pre-compute the first 20 values by hand and store them in a global or static array. Then use a global or static function to lookup the factorial in the array:

``````#include <iostream>

const int factorials[] =
{
1,
1,
2,
6,
24,
// etc...
};

inline const int factorial(int n) {return factorials[n];}

int main()
{
static const int fourFactorial = factorial(4);
std::cout << "4! = " << fourFactorial << "\n";
}
``````

If you use a literal as an argument to `factorial`, then the compiler should simply substitute the function call with the result (when optimization is enabled). I have tried the above example in XCode 4.4 (on a Mac) and I see in the assembly that it initializes `fourFactorial` with the constant 24:

``````.loc    1 20 38  ## /Users/emile/Dev/sandbox/sandbox/main.cpp:20:38
movl    \$24, __ZZ4mainE13fourFactorial(%rip)
``````

This method may result in faster compilation than by using recursive compile-time tricks.

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