# OverflowError: long int too large to convert to float in python

I tried to calculate poisson distribution in python as below:

``````p = math.pow(3,idx)
depart = math.exp(-3) * p
depart = depart / math.factorial(idx)
``````

idx ranges from 0

But I got `OverflowError: long int too large to convert to float`

I tried to convert depart to `float` but no results.

-
Factorial gets really large, really fast –  Hunter McMillen Apr 23 '13 at 16:22
What is the value of idx when you hit this error? –  Pyrce Apr 23 '13 at 16:23
When you wish to compute a factorial, compute it's logarithm instead –  zehelvion Jun 13 at 13:10

Factorials get large real fast:

``````>>> math.factorial(170)
7257415615307998967396728211129263114716991681296451376543577798900561843401706157852350749242617459511490991237838520776666022565442753025328900773207510902400430280058295603966612599658257104398558294257568966313439612262571094946806711205568880457193340212661452800000000000000000000000000000000000000000L
``````

Note the `L`; the factorial of 170 is still convertable to a float:

``````>>> float(math.factorial(170))
7.257415615307999e+306
``````

but the next factorial is too large:

``````>>> float(math.factorial(171))
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
OverflowError: long int too large to convert to float
``````

You could use the `decimal` module; calculations will be slower, but the `Decimal()` class can handle factorials this size:

``````>>> from decimal import Decimal
>>> Decimal(math.factorial(171))
Decimal('1241018070217667823424840524103103992616605577501693185388951803611996075221691752992751978120487585576464959501670387052809889858690710767331242032218484364310473577889968548278290754541561964852153468318044293239598173696899657235903947616152278558180061176365108428800000000000000000000000000000000000000000')
``````

You'll have to use `Decimal()` values throughout:

``````from decimal import *

with localcontext() as ctx:
ctx.prec = 32  # desired precision
p = ctx.power(3, idx)
depart = ctx.exp(-3) * p
depart /= math.factorial(idx)
``````
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What is the large number class in Python called? because `170!` is well above the limits of a 64-bit integer. I assume the type is coerced to that? If so, why is the `L` still appended to the end? –  Hunter McMillen Apr 23 '13 at 16:31
@HunterMcMillen: Python long integers are only limited by OS memory allocation. The `L` signifies we moved beyond the maximum C integer size for the platform (64-bit in my case) to show long integers are being used; the transition is automatic. See docs.python.org/2/library/… –  Martijn Pieters Apr 23 '13 at 16:33
Ahh, I see. Most other languages have `BigInteger` or something similar. Thanks. –  Hunter McMillen Apr 23 '13 at 16:36

Try using the decimal library. It claims to support arbitrary precision.
`from decimal import Decimal`

Also, you don't need to use `math.pow`. `pow` is in-built.

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Hi guys I tried to use decimal or scipy but i got ImportError: No module named scipy.stats the same error for decimal –  user2312186 Apr 23 '13 at 17:08
what version are you running? `decimal` library is supposed to be standard for all. perhaps you have deleted it. re-install python and it will fix it. as for scipy, it is a third-party package, so you'll have to download it from scipy.org –  xylon97 Apr 23 '13 at 17:12
I installed scipy and it works well –  user2312186 Apr 23 '13 at 17:44
I am going to use poisson like this: depart = depart + Poisson(3) so that inter-arrival times are selected by Poisson. but it does not work. –  user2312186 Apr 23 '13 at 17:45

When idx gets large either the `math.pow` and/or the `math.factorial` will become insanely large and be unable to convert to a floating value (`idx=1000` triggers the error on my 64 bit machine). You'll want to not use the math.pow function as it overflows earlier than the built in `**` operator because it tries to keep higher precision by float converting earlier. Additionally you can wrap each function call in a `Decimal` object for higher precision.

Another approach when dealing with very large numbers is to work in the log scale. Take the log of every value (or calculate the log version of each value) and perform all required operations before taking the exponentiation of the results. This allows for your values to temporary leave the floating domain space while still accurately computing a final answer that lies within floating domain.

``````3 ** idx  =>  math.log(3) * math.log(idx)
math.exp(-3) * p  =>  -3 + math.log(p)
math.factorial(idx)  =>  sum(math.log(ii) for ii in range(1, idx))
...
math.exp(result)
``````

This stays in the log domain until the very end so your numbers can get very, very large before you'll hit overflow problems.

-

The `scipy` module could help you.

scipy.misc.factorial is a factorial function that can use the gamma function approximation to calculate the factorial, and returns the result using floating points.

``````import numpy
from scipy.misc import factorial

i = numpy.arange(10)
print(numpy.exp(-3) * 3**i / factorial(i))
``````

Gives:

``````[ 0.04978707  0.14936121  0.22404181  0.22404181  0.16803136  0.10081881
0.05040941  0.02160403  0.00810151  0.0027005 ]
``````

There is also a module to calculate Poisson distributions. For example:

``````import numpy
from scipy.stats import poisson

i = numpy.arange(10)
p = poisson(3)
print(p.pmf(i))
``````

Gives:

``````[ 0.04978707  0.14936121  0.22404181  0.22404181  0.16803136  0.10081881
0.05040941  0.02160403  0.00810151  0.0027005 ]
``````
-
+1 for `scipy.stats`, but the factorial function scipy offers will still `inf` out at large argument. –  DSM Apr 23 '13 at 16:46
Thanks. I am going to generate Poisson numbers as generating packet time in the network. How can i use this function for generating a Poisson number each continually? –  user2312186 Apr 23 '13 at 16:52