# Trying to calculate Pi to N number of decimals with C#

Note: I've already read this topic, but I don't understand it and it doesn't provide a solution I could use. I'm terrible with number problems.

What's a simple way to generate Pi to what number of decimals a user wants? This isn't for homework, just trying to complete some of the projects listed here:

-
this is a duplicate of many questions. –  Chris H Feb 9 '10 at 1:50
I only found the one I linked up top. Is there another one that shows a porper solution? –  delete Feb 9 '10 at 1:51
That link doesn't really show a simple C# solution. :S I'm learning so something convoluted is not what I need right now. –  delete Feb 9 '10 at 1:58
@Ram, I think this is so he could practice his C# skills. I recommend Jason's answer, where it is your perogative to write C# code. –  Russell Feb 9 '10 at 4:18
show 1 more comment

A classic algorithm for calculating digits of `pi` is the Gauss-Legendre algorithm. While it is not as fast as some of the more modern algorithms it does have the advantage of being understandable.

Let

``````a_0 = 1
b_0 = 1/Sqrt(2)
t_0 = 1/4
p_0 = 1
``````

Then

``````a_(n+1) = (a_n + b_n) / 2
b_(n+1) = Sqrt(a_n * b_n)
t_(n+1) = t_n - p_n * (a_n - a_(n+1))^2
p_(n+1) = 2 * p_n
``````

Then

``````pi =. (a_n + b_n)^2 / (4 * t_n)
``````

Here (`=.` means "approximately equal to") This algorithm exhibits quadratic convergence (the number of correct decimal places doubles with each iteration).

I'll leave it to you to translate this to C# including discovering an arbitrary-precision arithmetic library.

-

The topic your talking about calculate the value of PI using the taylor series. Using the function "double F (int i)" wrote on that topic will give you the value of PI after "i" terms.

This way of calculating PI is kind of slow, i suggest you to look at the PI fast algorithm.

You can also find one implementation here that get the calculate PI to the n th digit.

Good luck!

-

If you take a close look into this really good guide:

Patterns for Parallel Programming: Understanding and Applying Parallel Patterns with the .NET Framework 4

You'll find at Page 70 this cute implementation (with minor changes from my side):

``````static decimal ParallelPartitionerPi(int steps)
{
decimal sum = 0.0;
decimal step = 1.0 / (decimal)steps;
object obj = new object();
Parallel.ForEach(Partitioner.Create(0, steps),
() => 0.0,
(range, state, partial) =>
{
for (int i = range.Item1; i < range.Item2; i++)
{
decimal x = (i + 0.5) * step;
partial += 4.0 / (1.0 + x * x);
}
return partial;
},
partial => { lock (obj) sum += partial; });
return step * sum;
}
``````
-