Question

I recently posted one of my favourite interview whiteboard coding questions in "What's your more controversial programming opinion", which is to write a function that computes Pi using the Leibniz formula.

It can be approached in a number of different ways, and the exit condition takes a bit of thought, so I thought it might make an interesting code golf question. Shortest code wins!

Given that Pi can be estimated using the function 4 * (1 - 1/3 + 1/5 - 1/7 + ...) with more terms giving greater accuracy, write a function that calculates Pi to within 0.00001.

Edit: 3 Jan 2008

As suggested in the comments I changed the exit condition to be within 0.00001 as that's what I really meant (an accuracy 5 decimal places is much harder due to rounding and so I wouldn't want to ask that in an interview, whereas within 0.00001 is an easier to understand and implement exit condition).

Also, to answer the comments, I guess my intention was that the solution should compute the number of iterations, or check when it had done enough, but there's nothing to prevent you from pre-computing the number of iterations and using that number. I really asked the question out of interest to see what people would come up with.

Answer 1

J, 14 chars

4*-/%>:+:i.1e6

Explanation:

"1e6" is number 1 followed by 6 zeroes (1000000).
"i."y generates the first y non negative numbers.
"+:" is a function that doubles each element in the list argument.
">:" is a function that increments by one each element in the list argument.

So, the expression ">:+:i.1e6" generates the first 1000000 odd numbers:

1 3 5 7 ...

"%" is the reciprocal operator (numerator "1" can be omitted).
"-/" does an alternate sum of each element in the list argument.

So, the expression "-/%>:+:i.1e6" generates the alternate sum of the reciprocals of the first 1000000 odd numbers:

1 - 1/3 + 1/5 - 1/7 + ...

"4*" is multiplication by four. If you multiply by four the previous sum, you have pi.

That's it!
J is a powerful language for mathematics.

Edit: since generating 9! (362880) terms for the alternate sum is sufficient to have 5 decimal digit accuracy, and since the Leibniz formula can be written also this way:

4 - 4/3 + 4/5 -4/7 + ...

you can write a shorter, 12 chars version of the program:

-/4%>:+:i.9!

Answer 2

Language: Brainfuck, Char count: 51/59

Does this count? =]

Because there are no floating-point numbers in Brainfuck, it was pretty difficult to get the divisions working properly. Grr.

Without newline (51):

+++++++[>+++++++<-]>++.-----.+++.+++.---.++++.++++.

With newline (59):

+++++++[>+++++++>+<<-]>++.-----.+++.+++.---.++++.++++.>+++.

Answer 3

Perl

26 chars

26 just the function, 27 to compute, 31 to print. From the comments to this answer.

sub _{$-++<1e6&&4/$-++-&_}       # just the sub
sub _{$-++<1e6&&4/$-++-&_}_      # compute
sub _{$-++<1e6&&4/$-++-&_}say _  # print

28 chars

28 just computing, 34 to print. From the comments. Note that this version cannot use 'say'.

$.=.5;$\=2/$.++-$\for 1..1e6        # no print
$.=.5;$\=2/$.++-$\for$...1e6;print  # do print, with bonus obfuscation

36 chars

36 just computing, 42 to print. Hudson's take at dreeves's rearrangement, from the comments.

$/++;$\+=8/$//($/+2),$/+=4for$/..1e6
$/++;$\+=8/$//($/+2),$/+=4for$/..1e6;print

About the iteration count: as far as my math memories go, 400000 is provably enough to be accurate to 0.00001. But a million (or as low as 8e5) actually makes the decimal expansion actually match 5 fractional places, and it's the same character count so I kept that.

Answer 4

Ruby, 33 characters

(0..1e6).inject{|a,b|2/(0.5-b)-a}

Answer 5

Another C# version:

(60 characters)

4*Enumerable.Range(0, 500000).Sum(x => Math.Pow(-1, x)/(2*x + 1));  // = 3,14159

Answer 6

52 chars in Python:

print 4*sum(((-1.)**i/(2*i+1)for i in xrange(5**8)))

(51 dropping the 'x' from xrange.)

36 chars in Octave (or Matlab):

l=0:5^8;disp((-1).^l*(4./(2.*l+1))')

(execute "format long;" to show all the significant digits.) Omitting 'disp' we reach 30 chars:

octave:5> l=0:5^8;(-1).^l*(4./(2.*l+1))'
ans = 3.14159009359631

Answer 7

Haskell

I got it down to 34 characters:

foldl subtract 4$map(4/)[3,5..9^6]

This expression yields 3.141596416935556 when evaluated.

Edit: here's a somewhat shorter version (at 33 characters) that uses foldl1 instead of foldl:

foldl1 subtract$map(4/)[1,3..9^6]

Edit 2: 9^6 instead of 10^6. One has to be economical ;)

Edit 3: Replaced with foldl' and foldl1' with foldl and foldl1 respectively—as a result of Edit 2, it no longer overflows. Thanks to ShreevatsaR for noticing this.

Answer 8

Oracle SQL 73 chars

select -4*sum(power(-1,level)/(level*2-1)) from dual connect by level<1e6

Answer 9

Mathematica, 27 chars (arguably as low as 26, or as high as 33)

NSum[8/i/(i+2),{i,1,9^9,4}]

If you remove the initial "N" then it returns the answer as a (huge) fraction.

If it's cheating that Mathematica doesn't need a print statement to output its result then prepend "Print@" for a total of 33 chars.

NB:

If it's cheating to hardcode the number of terms, then I don't think any answer has yet gotten this right. Checking when the current term is below some threshold is no better than hardcoding the number of terms. Just because the current term is only changing the 6th or 7th digit doesn't mean that the sum of enough subsequent terms won't change the 5th digit.

Answer 10

Language: C, Char count: 71

float p;main(i){for(i=1;1E6/i>5;i+=2)p-=(i%4-2)*4./i;printf("%g\n",p);}

Language: C99, Char count: 97 (including required newline)

#include <stdio.h>
float p;int main(){for(int i=1;1E6/i>5;i+=2)p-=(i%4-2)*4./i;printf("%g\n",p);}

I should note that the above versions (which are the same) keep track of whether an extra iteration would affect the result at all. Thus, it performs a minimum number of operations. To add more digits, replace 1E6 with 1E(num_digits+1) or 4E5 with 4E(num_digits) (depending on the version). For the full programs, %g may need to be replaced. float may need to be changed to double as well.

Language: C, Char count: 67 (see notes)

double p,i=1;main(){for(;i<1E6;i+=4)p+=8/i/(i+2);printf("%g\n",p);}

This version uses a modified version of posted algorithm, as used by some other answers. Also, it is not as clean/efficient as the first two solutions, as it forces 100 000 iterations instead of detecting when iterations become meaningless.

Language: C, Char count: 24 (cheating)

main(){puts("3.14159");}

Doesn't work with digit counts > 6, though.

Answer 11

23 chars in MATLAB:

a=1e6;sum(4./(1-a:4:a))

Answer 12

F#:

Attempt #1:

let pi = 3.14159

Cheating? No, its winning with style!

Attempt #2:

let pi =
    seq { 0 .. 100 }
    |> Seq.map (fun x -> float x)
    |> Seq.fold (fun x y -> x + (Math.Pow(-1.0, y)/(2.0 * y + 1.0))) 0.0
    |> (fun x -> x * 4.0)

Its not as compact as it could possibly get, but pretty idiomatic F#.

Answer 13

Perl :

$i+=($_&1?4:-4)/($_*2-1)for 1..1e6;print$i

for a total of 42 chars.

Answer 14

Ruby, 41 chars (using irb):

s=0;(3..3e6).step(4){|i|s+=8.0/i/(i-2)};s

Or this slightly longer, non-irb version:

s=0;(3..3e6).step(4){|i|s+=8.0/i/(i-2)};p s

This is a modified Leibniz:

1. Combine pairs of terms. This gives you 2/3 + 2/35 + 2/99 + ...
2. Pi becomes 8 * (1/(1 * 3) + 1/(5 * 7) + 1/(9 * 11) + ...)

Answer 15

Using the formula for the error term in an alternating series (and thus the necessary number of iterations to achieve the desired accuracy is not hard coded into the program):

public static void Main(string[] args) {
    double tolerance = 0.000001;
    double piApproximation = LeibnizPi(tolerance);
    Console.WriteLine(piApproximation);
}

private static double LeibnizPi(double tolerance) {
    double quarterPiApproximation = 0;

    int index = 1;
    double term;
    int sign = 1;
    do {
        term = 1.0 / (2 * index - 1);
        quarterPiApproximation += ((double)sign) * term;
        index++;
        sign = -sign;
    } while (term > tolerance);

    return 4 * quarterPiApproximation;
}

Answer 16

{0.0..1E6}|>Seq.fold(fun a x->a+ -1.**x/(2.*x+1.))0.|>(*)4.

F# (Interactive Mode) (59 Chars)

(Yields a warning but omits the casts)

Answer 17

C# using iterator block:

static IEnumerable<double> Pi()
{
    double i = 4, j = 1, k = 4;
    for (;;)
    {
        yield return k;
        k += (i *= -1) / (j += 2);
    }
}

Answer 18

common lisp, 55 chars.

(loop for i from 1 upto 4e5 by 4 sum (/ 8d0 i (+ i 2)))

Answer 19

Here's a solution in MUMPS.

pi(N)
 N X,I
 S X=1 F I=3:4:N-2 S X=X-(1/I)+(1/(I+2))
 Q 4*X

Parameter N indicates how many repeated fractions to use. That is, if you pass in 5 it will evaluate 4 * (1 - 1/3 + 1/5 - 1/7 + 1/9 - 1/11)

Some empirical testing showed that N=272241 is the lowest value that gives a correct value of 3.14159 when truncated to 5 decimal points. You have to go to N=852365 to get a value that rounds to 3.14159.

Answer 20

Language: C99 (implicit return 0), Char count: 99 (95 + 4 required spaces)

exit condition depends on current value, not on a fixed count

#include <stdio.h>

float p, s=4, d=1;
int main(void) {
  for (; 4/d > 1E-5; d += 2)
        p -= (s = -s) / d;
  printf("%g\n", p);
}

compacted version

#include<stdio.h>
float
p,s=4,d=1;int
main(void){for(;4/d>1E-5;d+=2)p-=(s=-s)/d;printf("%g\n",p);}

Answer 21

a=0,b=-1,d=-4,c=1e6;while(c--)a+=(d=-d)/(b+=2)

In javascript. 51 characters. Obviously not going to win but eh. :P

Edit -- updated to be 46 characters now, thanks to Strager. :)

Answer 22

For the record, this Scheme implementation has 95 characters ignoring unnecessary whitespace.

(define (f)
  (define (p a b)
    (if (> a b)
      0
      (+ (/ 1.0 (* a (+ a 2))) (p (+ a 4) b))))
  (* 8 (p 1 1e6)))

Answer 23

Language: dc, Char count: 35

dc -e '9k0 1[d4r/r2+sar-lad274899>b]dsbxrp'

Answer 24

Ruby:

irb(main):031:0> 4*(1..10000).inject {|s,x| s+(-1)**(x+1)*1.0/(2*x-1)}
=> 3.14149265359003

Answer 25

C#:

public static double Pi()
{
    double pi = 0;
    double sign = 1;
    for (int i = 1; i < 500002; i += 2)
    {
        pi += sign / i;
        sign = -sign;
    }
    return 4 * pi;
}

Answer 26

Most of the current answers assume that they'll get 5 digits accuracy within some number of iterations and this number is hardcoded into the program. My understanding of the question was that the program itself is supposed to figure out when it's got an answer accurate to 5 digits and stop there. On that assumption here's my C# solution. I haven't bothered to minimise the number of characters since there's no way it can compete with some of the answers already out there, so I thought I'd make it readable instead. :)

    private static double GetPi()
    {
        double acc = 1, sign = -1, lastCheck = 0;

        for (double div = 3; ; div += 2, sign *= -1)
        {
            acc += sign / div;

            double currPi = acc * 4;
            double currCheck = Math.Round(currPi, 5);

            if (currCheck == lastCheck)
                return currPi;

            lastCheck = currCheck;
        }
    }

Answer 27

64 chars in AWK:

~# awk 'BEGIN {p=1;for(i=3;i<10^6;i+=4){p=p-1/i+1/(i+2)}print p*4}'
3.14159

Answer 28

#!/usr/bin/env python
from math import *
denom = 1.0
imm = 0.0
sgn = 1
it = 0
for i in xrange(0, int(1e6)):
    imm += (sgn*1/denom)
    denom += 2
    sgn *= -1    
print str(4*imm)

Answer 29

C++

double LeibnizPi( double tolerance )
{
    double sum = 1.0;
    for( int plus_div = 5, minus_div = -3, limit = 10 / tolerance; plus_div < limit ; plus_div += 4, minus_div -= 4 )
        sum += 1./plus_div + 1./minus_div;
    return 4 * sum;
}

Answer 30

After noting that

(= (- (/ 4 n)
      (/ 4 (+ n 2)))
   (/ 8 n (+ n 2)))

or, in a more familiar notation:

4    4      8
- - --- = ------
n   n+2   n(n+2)

Common Lisp, with a do* loop (62 essential characters):

(do* ((n 1 (+ n 4))
      (p 8/3 (+ p (/ 8 n (+ n 2)))))
     ((< (- pi p) 1e-6)
      p)

with a tail recursive function (70 essential characters):

(defun l (n p)
  (if (< (- pi p) 1e-6)
      p
      (l (+ n 4)
          (+ p (/ 8 n (+ n 2))))))
(l 1 0)

and with the extended loop (86 essential characters):

(loop for n from 1 by 4
      sum (/ 8 n (+ n 2)) into p
      until (< (- pi p) 1e-6)
      finally (return p))

all under the presumption that preliminary checks how far we have to go to get the desired accuracy are cheating.