# Using basic arithmetics for calculating Pi with arbitary precision

I am looking for a formula/algorithm to calculate PI~3.14 in a given precision.

The formula/algorithm must have only very basic arithmetic as

• -: Subtraction
• *: Multiplication
• /: Divison

because I want to implement these operations in C++ and want to keep the implementation as simple as possible (no bignum library is allowed).

I have found that this formula for calculating Pi is pretty simple:

``````Pi/4 = 1 - 1/3 + 1/5 - 1/7 + ...  = sum( (-1)^(k+1)/(2*k-1) , k=1..inf )
``````

(note that (-1)^(k+1) can be implemented easily by above operators).

But the problem about this formula is the inability to specify the number of digits to calculate. In other words, there is no direct way to determine when to stop the calculation.

Maybe a workaround to this problem is calculating the difference between `n-1`th and `n`th calculated term and considering it as the current error.

Anyway, I am looking for a formula/algorithm that have these properties and also converges faster to Pi

• there are dozens of formulas which you can try here, and most of them converge pretty fast en.wikipedia.org/wiki/Pi – Gabi Purcaru Dec 19 '10 at 18:43
• @Gabi: but most of them contain non-basic operations like `square root`. i am looking for a formula based on the `+`,`-`,`*`, and `/`. Please, please read all of the question. – Isaac Dec 19 '10 at 18:45
• Here's another wikipedia source that should help: en.wikipedia.org/wiki/Numerical_approximations_of_%CF%80. (And many are sum formulas using basic operators) – Seth Dec 19 '10 at 18:48
• possible duplicate of Fastest way to get value of pi – Jason S Dec 19 '10 at 22:05
• I don't see the connection between wanting only 'simple' arithmetic ops and avoiding a bignum library: the standard C library contains a lot more than those operations, and you're going to have trouble calculating arbitrary digits without a bignum library regardless of what you use. – Nick Johnson Dec 19 '10 at 22:45

In your original (slowly converging) example, the error term can be computed because this is an alternating series; see http://en.wikipedia.org/wiki/Alternating_series#Approximating_Sums

Essentially, the next uncomputed term is a bound on the error.

``````#include <iostream>
#include <cmath>
int main()
{
double p16 = 1, pi = 0, precision = 10;

for(int k=0; k<=precision; k++)
{
pi += 1.0/p16 * (4.0/(8*k + 1) - 2.0/(8*k + 4) - 1.0/(8*k + 5) - 1.0/(8*k+6));
p16 *= 16;
}
std::cout<<std::setprecision(80)<<pi<<'\n'<<M_PI;
}
``````

Output:

``````3.141592653589793115997963468544185161590576171875
3.141592653589793115997963468544185161590576171875
``````

This is actually the Bailey-Borwein-Plouffe formula, also taken from the link from wikipedia.

• This formula is well-known as one of the formulas that gives `n`th digit of Pi, without the need of calculating `n-1` digits before it. Then, is this formula relatively efficient (in respect to the other formulas) to calculate all n digits? – Isaac Dec 19 '10 at 19:06
• @Isaac I didn't test all of them, but if after 11 steps it finds the first 15 digits, do you still need better performance? (all the 15 digits are correct) – Gabi Purcaru Dec 19 '10 at 19:12
• 11 step for 15 digits seems really, really good! compared to the given summation in the question which needs 300 terms to calculate 2 decimal points! Anyway, I wonder the ability of `BBP` formula to immediately calculate `n`th digit of `Pi` may have impact on the performance of calculating all digits of `Pi` to `n`. – Isaac Dec 19 '10 at 19:33
• @Isaac I'm not the man to say whether or not it could have an impact, but it seems it works very well, so IMO it's ok. Also, I updated the answer with C code and comparison with `M_PI` – Gabi Purcaru Dec 19 '10 at 19:43
• nice answer by the way. (although it cannot calculate Pi for big `n` s). – Isaac Dec 19 '10 at 20:33

You can just do the Taylor envelope of the arctan(1) and then you will get pi/4 just summing all the rest part. The taylor envelope of arctan(1)

http://en.wikipedia.org/wiki/Taylor_series

also you can use the euler formula with z=1 and then multiply the result by 4.