# Million decimal places in python

We recently delve into infinite series in calculus and that being said, I'm having so much fun with it. I derived my own inverse tan infinte series in python and set to 1 to get pi/4*4 to get pi. I know it's not the fastest algorithm, so please let's not discuss about my algorithm. What I would like to discuss is how do I represent very very small numbers in python. What I notice is as my programs iterate the series, it stops somewhere at the 20 decimal places (give or take). I tried using decimal module and that only pushed to about 509. I want an infinite (almost) representation.

Is there a way to do such thing? I reckon no data type will be able to handle such immensity, but if you can show me a way around that, I would appreciate that very much.

Good day to y'all

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possible duplicate of Python floating point arbitrary precision available? –  Ken Wayne VanderLinde May 18 '13 at 19:54
If it stopped after 509 decimal places then that indicates a flaw in the algorithm, not the datatype. –  Ignacio Vazquez-Abrams May 18 '13 at 19:57
@KenWayneVanderLinde nope, they just recommended to use the decimal module on that one either. –  Joey Arnold Andres May 18 '13 at 19:59
@JoeyArnoldAndres: How are you sing the `decimal` module? Are you sure your algorithm isn't just slowing down to a point where it looks like it stopped? –  Blender May 18 '13 at 20:02
That's because you're converting from a `float`, and those only go to about 1e-308 or so. `>>> Decimal('1e-400')` `Decimal('1E-400')` –  Ignacio Vazquez-Abrams May 18 '13 at 20:07

Python's decimal module requires that you specify the "context," which affects how precise the representation will be.

I might recommend gmpy2 for this type of thing - you can do the calculation on rational numbers (arbitrary precision) and convert to decimal at the last step.

Here's an example - substitute your own algorithm as needed:

``````import gmpy2
gmpy2.get_context().precision = 10000
pi = 0
for n in range(1000000):
# Formula from http://en.wikipedia.org/wiki/Calculating_pi#Arctangent
numer = pow(2, n + 1)
denom = gmpy2.bincoef(n + n, n) * (n + n + 1)
frac = gmpy2.mpq(numer, denom)
pi += frac
# Print every 1000 iterations
if n % 1000 == 0:
print(gmpy2.mpfr(pi))
``````
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