# Computing π to “infinite” binary precision in C#

So far it looks like Fabrice Bellard's base 2 equation is the way to go

Ironically this will require a BigReal type; do we have this for .Net? .Net 4.0 has BigInteger.

Anyone have a Haskell version?

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What is your motive? :) –  zproxy Oct 6 '09 at 7:27
Not sure if this is of any interest to you: pebblesteps.com/post/… –  Benjol Oct 6 '09 at 7:31
"What is your motive? :) – zproxy" - ulterior –  Bent Rasmussen Oct 6 '09 at 7:38
I do not think you understand what "infinite" actually means :-) –  paxdiablo Oct 6 '09 at 7:40
"Infinite" means "without limit". "Infinite precision" is the same as "arbitrary precision" - in neither case is there an inherent limit. –  David Thornley Oct 6 '09 at 19:57

## 4 Answers

Since you're asking for a Haskell version, here is a paper by Jerzy Karczmarczuk, called "The Most Unreliable Technique in the World to compute π":

This paper is an atypical exercice in lazy functional coding, written for fun and instruction. It can be read and understood by anybody who understands the programming language Haskell. We show how to implement the Bailey-Borwein-Ploue formula for π in a co-recursive, incremental way which produces the digits 3, 1, 4, 1, 5, 9. . . until the memory exhaustion. This is not a way to proceed if somebody needs many digits! Our coding strategy is perverse and dangerous, and it provably breaks down. It is based on the arithmetics over the domain of infinite sequences of digits representing proper fractions expanded in an integer base. We show how to manipulate: add, multiply by an integer, etc. such sequences from the left to the right ad infinitum, which obviously cannot work in all cases because of ambiguities. Some deep philosophical consequences are discussed in the conclusions.

It doesn't really solve the problem in an efficient or very practical way, but is entertaining and shows some of the problems with lazy infinite precision arithmetic.

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Thanks a lot! This exactly the kind of stuff I was looking for! –  Bent Rasmussen Oct 7 '09 at 17:05

By far my favorite Haskell spigot for pi comes from Jeremy Gibbons:

pi = g(1,0,1,1,3,3) where
g(q,r,t,k,n,l) =
if 4*q+r-t<n*t
then n : g(10*q,10*(r-n*t),t,k,div(10*(3*q+r))t-10*n,l)
else g(q*k,(2*q+r)*l,t*l,k+1,div(q*(7*k+2)+r*l)(t*l),l+2)

The mathematical background that justifies that implementation can be found in:

A Spigot Algorithm for the Digits of Pi

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Awesome! Thanks for the reference! –  Bent Rasmussen Oct 13 '09 at 19:54

There exists such possibility to process big rational numbers in DLR-based dynamic languages (e.g. IronPython). Or you can use any portable C/C++ implementation of big real numbers through P/Invoke.

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Wikipedia details a lot of ways to get numerical approximations of pi here. They also give some sample pseudo-code

Edit : If you're interested in this kind of mathematical problems without having any related real-world problem to solve (which is definitely a good attitude to have, IMHO), you could visit the Euler Project page

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Sorry, you misread my question. I'm not after anything within the range of native types. I want true "BigNum" π. –  Bent Rasmussen Oct 6 '09 at 17:00
I'm also not after a "baked" solution, just genuine input/ideas about this. I didn't think I was the only person on Stackoverflow to be interested in this kind of thing in my spare time. –  Bent Rasmussen Oct 6 '09 at 17:04
@Bent. This is a classic math problem. It's covered extensively in the wikipedia page I posted, and I honestly doubt you will get some guenuinely new ideas here. What exactly are you after ? –  Brann Oct 6 '09 at 17:35
Don't get hung up over the term "approximation." Any representation, even one that is arbitrarily (not infinitely) precise, is still a numerical approximation. –  Jimmy Oct 6 '09 at 18:21
I agree with that Jimmy but I still think using the term infinite is acceptable given that streams do in fact model infinite series, even if they can never be realized. But it doesn't really matter. I think .Net lacks a "native" BigReal type (one that comes with the BCL). –  Bent Rasmussen Oct 6 '09 at 19:30