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_init(ix);
    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);
            break;
        }
    }

    mpf_clear(ix);
    mpf_clear(r_i2);
    mpf_clear(r_i3);
    mpf_clear(r_i4);

    return (PyObject*)pi;
}

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

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.
        

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

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.