# C implentation of Simon Plouffe's 1996 algorithm for computing pi fails

You can see the pi formula in the "approximations of pi" Wikipedia article. I was attracted to the formula because it is compact and promises efficient computation, plus it is specialized for base 10. The formula is

`````` pi = -3 + SUM(n=0,oo): n*(2^n)*(n!)^2/(2*n)!
``````

My C code is below. It seems very straight forward. It computes all of the intermediate steps, but it completely fails to converge. What is the bug?

``````#include <stdio.h>
#include <math.h>
#define sq(x)  ((x)*(x))
int nfac(int);
int main()
{
double term, denom, sum;
double w, x, y, z, pi;
int n;

/* Plouffe's 1996 algorithm
(see http://en.wikipedia.org/wiki/Approximations_of_π:  */
sum = -3.;
for(n=1; n <= 11; n++)
{
printf("n= %d\n", n);
printf("n! = %.0f\n", w = nfac(n));
printf("(n!)^2 = %.0f\n", x = sq(w));
printf("2^n = %.0f\n", y = pow(2,n));
printf("(2*n)! = %.0f\n", z = nfac(2*n));
printf("n*2^n)*((n!)^2)/(2*n)! = %f\n", term = n*y*x/z);
printf("sum = %f\n\n", sum += term);
}
printf("pi = %.10f\n\n", pi = sum);
}

int nfac(int n)
{
int i, nn;

if(n==0) return 1;

nn = 1;
for(i=1; i<=n; i++)
nn= i*nn;
return nn;
}
``````
-

Simple! Your `nfac`-method returns an `int`...

During computation you will also call it with arguments like `22` (line: `printf("(2*n)! = %.0f\n", z = nfac(2*n));` with `n = 11`).

The result of that does not fit inside of an `int` ;)

I would suggest using another type for `nfac`, but as others already suggested, I have no idea how precise your result will get even when using `double`.

-

A `double` and `int` can only hold a limited number, and if you get into the high ranges of `double` its precision deteriorates. You should really read What Every Computer Scientist Should Know About Floating-Point Arithmetic.

You need a large number library to do this kind of calculation.

As an example, let's say you use a 64-bit unsigned integer. What is the maximum factorial that fits in this? The answer is a mere 20!

``````factorial(21)  = 51090942171709440000
pow(2, 64) - 1 = 18446744073709551615
``````
-
absolutely... especially looking at the fact that with the current 11 iterations it should have a `sum` of just `~3.10046` (assuming no precision problems) while already having huge intermediate values... even if `double` were precise, I'm sure you will even exceed `double`'s maximum value before getting anywhere near 3,14159... ;) –  olydis Sep 14 '13 at 17:51