How can I write a function which will return pi (π) to a given number of decimal places?
Edit: Speed is not a concern. I've been looking at http://bellard.org/pi/, but I still don't understand how to get the nth digit of pi.
How can I write a function which will return pi (π) to a given number of decimal places? Edit: Speed is not a concern. I've been looking at http://bellard.org/pi/, but I still don't understand how to get the nth digit of pi. 


In calculus there is a thing called Taylor Series which provides an easy way to calculate many irrational values to arbitrary precision. Pi/4 = 1  1/3 + 1/5  1/7 + ... Keep adding those terms until the number of digits of precision you want stabilize. Taylor's theorem is a powerful tool, but the derivation of this series using the theorem is beyond the scope of the question. It's standard firstyear university calculus and is easily googlable if you're interested in more detail. Edit: I didn't mean to imply that this is the most practical method to calculate pi. That would depend on why you really need to do it. For practical purposes, you should just copy as many digits as you need from one of the many published versions. I was suggesting this as a simple introduction of how irrational values can be equated to infinite series. 


There are many algorithms for numeric approximation of π. 


Latest formula: http://en.wikipedia.org/wiki/Bellard%27s_formula 


As an alternative to JeffH's method of storing every variation, you can just store the maximum number of digits and cut off what you don't need:



Try this algorithm. It's probably the fastest known algorithm that doesn't require arbitrary (read huge) precision floats, and can give you the result directly in base 10 (or any other). 


I believe the algorithm you're looking for is what's known as a "Spigot Algorithm." One particular kind is the BBP (BaileyBorweinPlouffe) formula. I believe that's what you're looking for. 


Are you willing to look up values instead of computing them?Since you didn't explicitly specify that your function has to calculate values, here's a possible solution if you are willing to have an upper limit on the number of digits it can "calculate":
Writing CalcPi() this way (if it meets your needs) has a side benefit of being equally screaming fast for any value of X within your upper limit. 


You can tell the precision based on the last term you added (or subtracted). Since the amplitude of each term in Alan's sequence is always decreasing and each term alternates in sign, the sum won't change more than the last term. Translating that babble: After adding 1/5, the sum won't change more than 1/5, so you are precise to within 1/5. Of course, you'll have to multiply this by 4, so you're really only precise to 4/5. Unfortunately, math doesn't always translate easily into decimal digits. 


Here's a paper (PDF) which explores the curious relationship between a sequence of points on the complex plane and how computing their "Mandelbrot number" (for lack a better term ... the number of iterations required to determine that the points in the sequence are not members of the Mandelbrot set) relates to PI. Practical? Probably not. Unexpected and interesting? I think so. 


I'd start with the formula
Google will easily find a proof for this formula that normal human beings can understand, and a formula to calculate the arc tangent function. This will allow you to calculate a few thousand decimal digits of pi quite easily and quickly. 


Consider this a rough sketch, but it is a straightforward approach that a beginner could implement.


