First, assuming you want some arbitrary number of digits of pi, and we do not want to be confined with the precision of any of the various floating point numbers out there, let us define a Pi function as a string rather than any number type.

One of the coolest algorithms I found while searching for this technique is the Stanley Rabinowitz and Stan Wagon - Spigot Algorithm. It requires no floating point math, and is mostly an iterative method. It does require some memory for storing integer arrays in the intermediate calculations.

Without taking the time to streamline or clean the code here is an implementation of the algorithm (note the result does not add the decimal point).

Please be sure to cite the algorithm and this site if you intend to use this code for anything other than personal use.

## C# Code

```
public static string CalculatePi(int digits)
{
digits++;
uint[] x = new uint[digits*10/3+2];
uint[] r = new uint[digits*10/3+2];
uint[] pi = new uint[digits];
for (int j = 0; j < x.Length; j++)
x[j] = 20;
for (int i = 0; i < digits; i++)
{
uint carry = 0;
for (int j = 0; j < x.Length; j++)
{
uint num = (uint)(x.Length - j - 1);
uint dem = num * 2 + 1;
x[j] += carry;
uint q = x[j] / dem;
r[j] = x[j] % dem;
carry = q * num;
}
pi[i] = (x[x.Length-1] / 10);
r[x.Length - 1] = x[x.Length - 1] % 10; ;
for (int j = 0; j < x.Length; j++)
x[j] = r[j] * 10;
}
var result = "";
uint c = 0;
for(int i = pi.Length - 1; i >=0; i--)
{
pi[i] += c;
c = pi[i] / 10;
result = (pi[i] % 10).ToString() + result;
}
return result;
}
```

## Update

I finally got around to fixing the "carry error" that happens after 35 digits. Page 6 of the linked document, in fact, specifically talks about what is going on here. I have tested the final version good to 1000 digits.