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Solutions are welcome in any language. :-) I'm looking for the fastest way to obtain the value of π, as a personal challenge. More specifically I'm using ways that don't involve using #defined constants like M_PI, or hard-coding the number in.

The program below tests the various ways I know of. The inline assembly version is, in theory, the fastest option, though clearly not portable; I've included it as a baseline to compare the other versions against. In my tests, with built-ins, the 4 * atan(1) version is fastest on GCC 4.2, because it auto-folds the atan(1) into a constant. With -fno-builtin specified, the atan2(0, -1) version is fastest.

Here's the main testing program (pitimes.c):

#include <math.h>
#include <stdio.h>
#include <time.h>

#define ITERS 10000000
#define TESTWITH(x) {                                                       \
    diff = 0.0;                                                             \
    time1 = clock();                                                        \
    for (i = 0; i < ITERS; ++i)                                             \
        diff += (x) - M_PI;                                                 \
    time2 = clock();                                                        \
    printf("%s\t=> %e, time => %f\n", #x, diff, diffclock(time2, time1));   \

static inline double
diffclock(clock_t time1, clock_t time0)
    return (double) (time1 - time0) / CLOCKS_PER_SEC;

    int i;
    clock_t time1, time2;
    double diff;

    /* Warmup. The atan2 case catches GCC's atan folding (which would
     * optimise the ``4 * atan(1) - M_PI'' to a no-op), if -fno-builtin
     * is not used. */
    TESTWITH(4 * atan(1))
    TESTWITH(4 * atan2(1, 1))

#if defined(__GNUC__) && (defined(__i386__) || defined(__amd64__))
    extern double fldpi();

    /* Actual tests start here. */
    TESTWITH(atan2(0, -1))
    TESTWITH(2 * asin(1))
    TESTWITH(4 * atan2(1, 1))
    TESTWITH(4 * atan(1))

    return 0;

And the inline assembly stuff (fldpi.c), noting that it will only work for x86 and x64 systems:

    double pi;
    asm("fldpi" : "=t" (pi));
    return pi;

And a build script that builds all the configurations I'm testing (build.sh):

gcc -O3 -Wall -c           -m32 -o fldpi-32.o fldpi.c
gcc -O3 -Wall -c           -m64 -o fldpi-64.o fldpi.c

gcc -O3 -Wall -ffast-math  -m32 -o pitimes1-32 pitimes.c fldpi-32.o
gcc -O3 -Wall              -m32 -o pitimes2-32 pitimes.c fldpi-32.o -lm
gcc -O3 -Wall -fno-builtin -m32 -o pitimes3-32 pitimes.c fldpi-32.o -lm
gcc -O3 -Wall -ffast-math  -m64 -o pitimes1-64 pitimes.c fldpi-64.o -lm
gcc -O3 -Wall              -m64 -o pitimes2-64 pitimes.c fldpi-64.o -lm
gcc -O3 -Wall -fno-builtin -m64 -o pitimes3-64 pitimes.c fldpi-64.o -lm

Apart from testing between various compiler flags (I've compared 32-bit against 64-bit too, because the optimisations are different), I've also tried switching the order of the tests around. The atan2(0, -1) version still comes out top every time, though.

share|improve this question
boggle If it's a personal challenge, why are you asking us for the solution? =) –  Erik Forbes Oct 2 '08 at 21:36
I asked the question initially because I was one of the very first people in the private beta, and Jeff was asking people to populate the site with questions. This was one I was dealing with at the time, to solve this problem: stackoverflow.com/questions/1053 [continues] –  Chris Jester-Young Oct 2 '08 at 22:01
There's gotta to be a way to do it in C++ metaprogramming. The run time will be really good, but the compile time won't be. –  David Thornley Dec 9 '09 at 16:27
the question is: why would you not want to use a constant? e.g. either defined by a library or by yourself? Computing Pi is a waste of CPU cycles, as this problem has been solved over and over and over again to a number of significant digits much greater than needed for daily computations –  Tilo Oct 28 '11 at 0:58

21 Answers 21

up vote 116 down vote accepted

The Monte Carlo method, as mentioned, applies some great concepts but it is, clearly, not the fastest --not by a long shot, not by any reasonable usefulness. Also, it all depends on what kind of accuracy you are looking for. The fastest pi I know of is the digits hard coded. Looking at Pi and Pi[PDF], there are a lot of formulas.

Here is a method that converges quickly (~14digits per iteration). The current fastest application, PiFast, uses this formula with the FFT. I'll just write the formula, since the code is straight forward. This formula was almost found by Ramanujan and discovered by Chudnovsky. It is actually how he calculated several billion digits of the number --so it isn't a method to disregard. The formula will overflow quickly since we are dividing factorials, it would be advantageous then to delay such calculating to remove terms.

enter image description here

enter image description here


enter image description here

Below is the Brent–Salamin algorithm. Wikipedia mentions that when a and b are 'close enough' then (a+b)^2/4t will be an approximation of pi. I'm not sure what 'close enough' means, but from my tests, one iteration got 2digits, two got 7, and three had 15, of course this is with doubles, so it might have error based on it's representation and the 'true' calculation could be more accurate.

let pi_2 iters =
    let rec loop_ a b t p i =
        if i = 0 then a,b,t,p
            let a_n = (a +. b) /. 2.0 
            and b_n = sqrt (a*.b)
            and p_n = 2.0 *. p in
            let t_n = t -. (p *. (a -. a_n) *. (a -. a_n)) in
            loop_ a_n b_n t_n p_n (i - 1)
    let a,b,t,p = loop_ (1.0) (1.0 /. (sqrt 2.0)) (1.0/.4.0) (1.0) iters in
    (a +. b) *. (a +. b) /. (4.0 *. t)

Lastly, how about some pi golf (800 digits)? 160 characters!

int a=10000,b,c=2800,d,e,f[2801],g;main(){for(;b-c;)f[b++]=a/5;for(;d=0,g=c*2;c-=14,printf("%.4d",e+d/a),e=d%a)for(b=c;d+=f[b]*a,f[b]=d%--g,d/=g--,--b;d*=b);}
share|improve this answer
I know! all I wanted was a nice complete answer. I just thought of things late, and I can't spell right! –  nlucaroni Sep 28 '08 at 3:41
Assuming you are trying to implement the first one yourself, wouldn't sqr(k3) be a problem? I'm pretty sure it would end up an irrational number that you will have to estimate (IIRC, all roots that are not whole numbers are irrational). Everything else looks pretty straight-forward if you are using infinite precision arithmetic but that square root is a deal breaker. The second one includes a sqrt as well. –  Bill K Aug 30 '10 at 22:20
@nlucaroni - I don't recall what image you originally linked above, can you find it or something similar to replace it with and update your post? The stack overflow image upload interface would be a good longer term solution... –  Adam Davis Feb 10 '11 at 7:46
The image was Chudnovsky`s Formula; mentioned in the link just north of the image. I replaced those long variables to k1...6. –  nlucaroni Feb 10 '11 at 19:36
in my experience, 'close enough' usually means there's a taylor series approximation involved. –  Stephen Feb 10 '11 at 19:46

I really like this program, which approximates pi by looking at its own area :-)

IOCCC 1988 : westley.c

share|improve this answer
If you replace _ with -F<00||--F-OO-- it should be easier to follow :-) –  Pat Sep 24 '08 at 22:01
I knew the guy who wrote it. Very nice guy, quiet, not the sort of person you'd expect to come up with lots of weird C like that. –  David Thornley Jan 12 '09 at 20:24
it prints 0.25 here -.- –  Johannes Schaub - litb Feb 26 '09 at 19:30
This program was great in 1998, but was broken because modern preprocessors are more liberal with inserting spaces around macro expansions to prevent things like this from working. It is a relic, unfortunately. –  Chris Lutz Dec 23 '09 at 10:12
Pass --traditional-cpp to cpp to get the intended behavior. –  Nietzche-jou Jan 6 '10 at 12:47

Here's a general description of a technique for calculating pi that I learnt in high school.

I only share this because I think it is simple enough that anyone can remember it, indefinitely, plus it teaches you the concept of "Monte-Carlo" methods -- which are statistical methods of arriving at answers that don't immediately appear to be deducible through random processes.

Draw a square, and inscribe a quadrant (one quarter of a semi-circle) inside that square (a quadrant with radius equal to the side of the square, so it fills as much of the square as possible)

Now throw a dart at the square, and record where it lands -- that is, choose a random point anywhere inside the square. Of course, it landed inside the square, but is it inside the semi-circle? Record this fact.

Repeat this process many times -- and you will find there is a ratio of the number of points inside the semi-circle versus the total number thrown, call this ratio x.

Since the area of the square is r times r, you can deduce that the area of the semi circle is x times r times r (that is, x times r squared). Hence x times 4 will give you pi.

This is not a quick method to use. But it's a nice example of a Monte Carlo method. And if you look around, you may find that many problems otherwise outside your computational skills can be solved by such methods.

share|improve this answer
This is the method we used to calculate Pi in a java project in school. Just used a randomizer to come up with the x,y coordinates and the more 'darts' we threw the closer to Pi we came. –  Jeff Keslinke Feb 2 '09 at 21:01

In the interests of completeness, a C++ template version, which in an optimised build will compute PI at compile time and will inline to a single value.

#include <iostream>

template<int I>
struct sign
    enum {value = (I % 2) == 0 ? 1 : -1};

template<int I, int J>
struct pi_calc
    inline static double value ()
        return (pi_calc<I-1, J>::value () + pi_calc<I-1, J+1>::value ()) / 2.0;

template<int J>
struct pi_calc<0, J>
    inline static double value ()
        return (sign<J>::value * 4.0) / (2.0 * J + 1.0) + pi_calc<0, J-1>::value ();

struct pi_calc<0, 0>
    inline static double value ()
        return 4.0;

template<int I>
struct pi
    inline static double value ()
        return pi_calc<I, I>::value ();

int main ()
    std::cout.precision (12);

    const double pi_value = pi<10>::value ();

    std::cout << "pi ~ " << pi_value << std::endl;

    return 0;

Note for I > 10, optimised builds can be slow, as can non-optimised runs. I think for 12 iterations there are around 80k calls to value() (without memoization).

share|improve this answer
I run this and get "pi ~ 3.14159265383" –  maxwellb Jun 29 '10 at 20:56
Well, that's accurate to 9dp's. Are you objecting to something or just making an observation? –  jon-hanson Jun 30 '10 at 5:17

There's actually a whole book dedicated (amongst other things) to fast methods for the computation of \pi: 'Pi and the AGM', by Jonathan and Peter Borwein (available on Amazon).

I studied the AGM and related algorithms quite a bit: it's quite interesting (though sometimes non-trivial).

Note that to implement most modern algorithms to compute \pi, you will need a multiprecision arithmetic library (GMP is quite a good choice, though it's been a while since I last used it).

The time-complexity of the best algorithms is in O(M(n)log(n)), where M(n) is the time-complexity for the multiplication of two n-bit integers (M(n)=O(n log(n) log(log(n))) using FFT-based algorithms, which are usually needed when computing digits of \pi, and such an algorithm is implemented in GMP).

Note that even though the mathematics behind the algorithms might not be trivial, the algorithms themselves are usually a few lines of pseudo-code, and their implementation is usually very straightforward (if you chose not to write your own multiprecision arithmetic :-) ).

share|improve this answer

The following answers precisely how to do this in the fastest possible way -- with the least computing effort. Even if you don't like the answer, you have to admit that it is indeed the fastest way to get the value of PI.

The FASTEST way to get the value of Pi is:

  1. chose your favorite programming language
  2. load it's Math library
  3. and find that Pi is already defined there!! ready to use it..

in case you don't have a Math library at hand..

the SECOND FASTEST way (more universal solution) is:

look up Pi on the Internet, e.g. here:

http://www.eveandersson.com/pi/digits/1000000 (1 million digits .. what's your floating point precision? )

or here:


or here:


It's really fast to find the digits you need for whatever precision arithmetic you would like to use, and by defining a constant, you can make sure that you don't waste precious CPU time.

Not only is this a partly humorous answer, but in reality, if anybody would go ahead and compute the value of Pi in a real application .. that would be a pretty big waste of CPU time, wouldn't it? At least I don't see a real application for trying to re-compute this.

Dear Moderator: please note that the OP asked: "Fastest Way to get the value of PI"

share|improve this answer

The BBP formula allows you to compute the nth digit - in base 2 (or 16) - without having to even bother with the previous n-1 digits first :)

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Just came across this one that should be here for completeness:

calculate PI in Piet

It has the rather nice property that the precision can be improved making the program bigger.

Here's some insight into the language itself

share|improve this answer
I always loved this Piet program. Shows how Piet is clearly more practical than BF ;-) –  user166390 Jul 13 '11 at 20:10

Instead of defining pi as a constant, I always use acos(-1).

share|improve this answer
cos(-1), or acos(-1)? :-P That (the latter) is one of the test cases in my original code. It's among my preferred (along with atan2(0, -1), which really is the same as acos(-1), except that acos is usually implemented in terms of atan2), but some compilers optimise for 4 * atan(1)! –  Chris Jester-Young Apr 2 '09 at 20:27

If this article is true, then the algorithm that Bellard has created could be one of the speediest available. He has created pi to 2.7 TRILLION digits using a DESKTOP PC!

...and he has published his work here

Good work Bellard, You are a pioneer!


share|improve this answer
Bellard pioneered in many, many ways...first there was LZEXE, quite possibly the first executable compressor (think what UPX does, then flip back in time to the '80s), and of course now, both QEMU and FFMPEG are widely used. Oh, and his IOCCC entry.... :-P –  Chris Jester-Young Jan 6 '10 at 15:06

This is a "classic" method, very easy to implement. This implementation, in python (not so fast language) does it:

from math import pi
from time import time

precision = 10**6 # higher value -> higher precision
                  # lower  value -> higher speed

t = time()

calc = 0
for k in xrange(0, precision):
    calc += ((-1)**k) / (2*k+1.)
calc *= 4. # this is just a little optimization

t = time()-t

print "Calculated: %.40f" % calc
print "Costant pi: %.40f" % pi
print "Difference: %.40f" % abs(calc-pi)
print "Time elapsed: %s" % repr(t)

You can find more information here.

Anyway the fastest way to get a precise as-much-as-you-want value of pi in python is:

from gmpy import pi
print pi(3000) # the rule is the same as 
               # the precision on the previous code

here is the piece of source for the gmpy pi method, I don't think the code is as much useful as the comment in this case:

static char doc_pi[]="\
pi(n): returns pi with n bits of precision in an mpf object\n\

/* This function was originally from netlib, package bmp, by
 * Richard P. Brent. Paulo Cesar Pereira de Andrade converted
 * it to C and used it in his LISP interpreter.
 * Original comments:
 *   sets mp pi = 3.14159... to the available precision.
 *   uses the gauss-legendre algorithm.
 *   this method requires time o(ln(t)m(t)), so it is slower
 *   than mppi if m(t) = o(t**2), but would be faster for
 *   large t if a faster multiplication algorithm were used
 *   (see comments in mpmul).
 *   for a description of the method, see - multiple-precision
 *   zero-finding and the complexity of elementary function
 *   evaluation (by r. p. brent), in analytic computational
 *   complexity (edited by j. f. traub), academic press, 1976, 151-176.
 *   rounding options not implemented, no guard digits used.
static PyObject *
Pygmpy_pi(PyObject *self, PyObject *args)
    PympfObject *pi;
    int precision;
    mpf_t r_i2, r_i3, r_i4;
    mpf_t ix;

    ONE_ARG("pi", "i", &precision);
    if(!(pi = Pympf_new(precision))) {
        return NULL;

    mpf_set_si(pi->f, 1);

    mpf_set_ui(ix, 1);

    mpf_init2(r_i2, precision);

    mpf_init2(r_i3, precision);
    mpf_set_d(r_i3, 0.25);

    mpf_init2(r_i4, precision);
    mpf_set_d(r_i4, 0.5);
    mpf_sqrt(r_i4, r_i4);

    for (;;) {
        mpf_set(r_i2, pi->f);
        mpf_add(pi->f, pi->f, r_i4);
        mpf_div_ui(pi->f, pi->f, 2);
        mpf_mul(r_i4, r_i2, r_i4);
        mpf_sub(r_i2, pi->f, r_i2);
        mpf_mul(r_i2, r_i2, r_i2);
        mpf_mul(r_i2, r_i2, ix);
        mpf_sub(r_i3, r_i3, r_i2);
        mpf_sqrt(r_i4, r_i4);
        mpf_mul_ui(ix, ix, 2);
        /* Check for convergence */
        if (!(mpf_cmp_si(r_i2, 0) && 
              mpf_get_prec(r_i2) >= (unsigned)precision)) {
            mpf_mul(pi->f, pi->f, r_i4);
            mpf_div(pi->f, pi->f, r_i3);


    return (PyObject*)pi;

EDIT: I had some problem with cut and paste and identation, anyway you can find the source here.

share|improve this answer

This version (in Delphi) is nothing special, but it is at least faster than the version Nick Hodge posted on his blog :). On my machine, it takes about 16 seconds to do a billion iterations, giving a value of 3.1415926525879 (the accurate part is in bold).

program calcpi;



  start, finish: TDateTime;

function CalculatePi(iterations: integer): double;
  numerator, denominator, i: integer;
  sum: double;
  PI may be approximated with this formula:
  4 * (1 - 1/3 + 1/5 - 1/7 + 1/9 - 1/11 .......)
  numerator := 1;
  denominator := 1;
  sum := 0;
  for i := 1 to iterations do begin
    sum := sum + (numerator/denominator);
    denominator := denominator + 2;
    numerator := -numerator;
  Result := 4 * sum;

    start := Now;
    finish := Now;
    WriteLn('Seconds:' + FormatDateTime('hh:mm:ss.zz',finish-start));
    on E:Exception do
      Writeln(E.Classname, ': ', E.Message);
share|improve this answer

Pi is exactly 3! [Prof. Frink (Simpsons)]

Joke, but here's one in C# (.NET-Framework required).

using System;
using System.Text;

class Program {
    static void Main(string[] args) {
        int Digits = 100;

        BigNumber x = new BigNumber(Digits);
        BigNumber y = new BigNumber(Digits);
        x.ArcTan(16, 5);
        y.ArcTan(4, 239);
        string pi = x.ToString();

public class BigNumber {
    private UInt32[] number;
    private int size;
    private int maxDigits;

    public BigNumber(int maxDigits) {
        this.maxDigits = maxDigits;
        this.size = (int)Math.Ceiling((float)maxDigits * 0.104) + 2;
        number = new UInt32[size];
    public BigNumber(int maxDigits, UInt32 intPart)
        : this(maxDigits) {
        number[0] = intPart;
        for (int i = 1; i < size; i++) {
            number[i] = 0;
    private void VerifySameSize(BigNumber value) {
        if (Object.ReferenceEquals(this, value))
            throw new Exception("BigNumbers cannot operate on themselves");
        if (value.size != this.size)
            throw new Exception("BigNumbers must have the same size");

    public void Add(BigNumber value) {

        int index = size - 1;
        while (index >= 0 && value.number[index] == 0)

        UInt32 carry = 0;
        while (index >= 0) {
            UInt64 result = (UInt64)number[index] +
                            value.number[index] + carry;
            number[index] = (UInt32)result;
            if (result >= 0x100000000U)
                carry = 1;
                carry = 0;
    public void Subtract(BigNumber value) {

        int index = size - 1;
        while (index >= 0 && value.number[index] == 0)

        UInt32 borrow = 0;
        while (index >= 0) {
            UInt64 result = 0x100000000U + (UInt64)number[index] -
                            value.number[index] - borrow;
            number[index] = (UInt32)result;
            if (result >= 0x100000000U)
                borrow = 0;
                borrow = 1;
    public void Multiply(UInt32 value) {
        int index = size - 1;
        while (index >= 0 && number[index] == 0)

        UInt32 carry = 0;
        while (index >= 0) {
            UInt64 result = (UInt64)number[index] * value + carry;
            number[index] = (UInt32)result;
            carry = (UInt32)(result >> 32);
    public void Divide(UInt32 value) {
        int index = 0;
        while (index < size && number[index] == 0)

        UInt32 carry = 0;
        while (index < size) {
            UInt64 result = number[index] + ((UInt64)carry << 32);
            number[index] = (UInt32)(result / (UInt64)value);
            carry = (UInt32)(result % (UInt64)value);
    public void Assign(BigNumber value) {
        for (int i = 0; i < size; i++) {
            number[i] = value.number[i];

    public override string ToString() {
        BigNumber temp = new BigNumber(maxDigits);

        StringBuilder sb = new StringBuilder();

        int digitCount = 0;
        while (digitCount < maxDigits) {
            temp.number[0] = 0;
            sb.AppendFormat("{0:D5}", temp.number[0]);
            digitCount += 5;

        return sb.ToString();
    public bool IsZero() {
        foreach (UInt32 item in number) {
            if (item != 0)
                return false;
        return true;

    public void ArcTan(UInt32 multiplicand, UInt32 reciprocal) {
        BigNumber X = new BigNumber(maxDigits, multiplicand);
        reciprocal *= reciprocal;


        BigNumber term = new BigNumber(maxDigits);
        UInt32 divisor = 1;
        bool subtractTerm = true;
        while (true) {
            divisor += 2;
            if (term.IsZero())

            if (subtractTerm)
            subtractTerm = !subtractTerm;
share|improve this answer

Use the Machin-like formula

176 * arctan (1/57) + 28 * arctan (1/239) - 48 * arctan (1/682) + 96 * arctan(1/12943) 

[; \left( 176 \arctan \frac{1}{57} + 28 \arctan \frac{1}{239} - 48 \arctan \frac{1}{682} + 96 \arctan \frac{1}{12943}\right) ;], for you TeX the World people.

Implemented in Scheme, for instance:

(+ (- (+ (* 176 (atan (/ 1 57))) (* 28 (atan (/ 1 239)))) (* 48 (atan (/ 1 682)))) (* 96 (atan (/ 1 12943))))

share|improve this answer

With doubles:

4.0 * (4.0 * Math.Atan(0.2) - Math.Atan(1.0 / 239.0))

This will be accurate up to 14 decimal places, enough to fill a double (the inaccuracy is probably because the rest of the decimals in the arc tangents are truncated).

Also Seth, it's 3.141592653589793238463, not 64.

share|improve this answer

If by fastest you mean fastest to type in the code, here's the golfscript solution:

share|improve this answer

Back in the old days, with small word sizes and slow or non-existent floating-point operations, we used to do stuff like this:

/* Return approximation of n * PI; n is integer */
#define pi_times(n) (((n) * 22) / 7)

For applications that don't require a lot of precision (video games, for example), this is very fast and is accurate enough.

share|improve this answer
For more accuracy use 355 / 113. Very accurate for the size of numbers involved. –  David Thornley Dec 9 '09 at 16:25

If you are willing to use an approximation, 355 / 113 is good for 6 decimal digits, and has the added advantage of being usable with integer expressions. That's not as important these days, as "floating point math co-processor" ceased to have any meaning, but it was quite important once.

share|improve this answer

Calculate PI at compile-time with D.

( Copied from DSource.org )

/** Calculate pi at compile time
 * Compile with dmd -c pi.d
module calcpi;

import meta.math;
import meta.conv;

/** real evaluateSeries!(real x, real metafunction!(real y, int n) term)
 * Evaluate a power series at compile time.
 * Given a metafunction of the form
 *  real term!(real y, int n),
 * which gives the nth term of a convergent series at the point y
 * (where the first term is n==1), and a real number x,
 * this metafunction calculates the infinite sum at the point x
 * by adding terms until the sum doesn't change any more.
template evaluateSeries(real x, alias term, int n=1, real sumsofar=0.0)
  static if (n>1 && sumsofar == sumsofar + term!(x, n+1)) {
     const real evaluateSeries = sumsofar;
  } else {
     const real evaluateSeries = evaluateSeries!(x, term, n+1, sumsofar + term!(x, n));

/*** Calculate atan(x) at compile time.
 * Uses the Maclaurin formula
 *  atan(z) = z - z^3/3 + Z^5/5 - Z^7/7 + ...
template atan(real z)
    const real atan = evaluateSeries!(z, atanTerm);

template atanTerm(real x, int n)
    const real atanTerm =  (n & 1 ? 1 : -1) * pow!(x, 2*n-1)/(2*n-1);

/// Machin's formula for pi
/// pi/4 = 4 atan(1/5) - atan(1/239).
pragma(msg, "PI = " ~ fcvt!(4.0 * (4*atan!(1/5.0) - atan!(1/239.0))) );
share|improve this answer
Unfortunately, tangents are arctangents are based on pi, somewhat invalidating this calculation. –  Grant Johnson Sep 26 '08 at 14:42

Brent's method posted above by Chris is very good; Brent generally is a giant in the field of arbitrary-precision arithmetic.

If all you want is the Nth digit, the famous BBP formula is useful in hex

share|improve this answer
The Brent method wasn't posted by me; it was posted by Andrea, and I just happened to be the last person who edited the post. :-) But I agree, that post deserves an upvote. –  Chris Jester-Young Aug 7 '09 at 11:44

If you want to compute an approximation of the value of π (for some reason), you should try a binary extraction algorithm. Bellard's improvement of BBP gives does PI in O(N^2).

If you want to obtain an approximation of the value of π to do calculations, then:

PI = 3.141592654

Granted, that's only an approximation, and not entirely accurate. It's off by a little more than 0.00000000004102. (four ten-trillionths, about 4/10,000,000,000).

If you want to do math with π, then get yourself a pencil and paper or a computer algebra package, and use π's exact value, π.

If you really want a formula, this one is fun:

π = -i ln(-1)

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Your formula depends on how you define ln in the complex plane. It has to be non-contiguous along one line in the complex plane, and it's quite common for that line to be the negative real axis. –  erikkallen Dec 23 '09 at 12:14

protected by Robert Harvey Feb 10 '11 at 20:20

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