# How are bignums represented internally?

Python provides a "bignum" type called "long" which can represent arbitrarily large numbers. What is the internal representation of this type?

I ask in part because I am curious what operations might be particularly fast or slow on these numbers. For example, is bit shifting particularly fast compared to multiplication or division (as it is for "regular" ints)?

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This is interesting. You should test it: perform a hundred thousand operations of each kind on both `int` and `long`, and see which are faster! – uʍop ǝpısdn Apr 23 '14 at 20:03
This is just a guess, but this should depend on the implementation and against which arbitrary precision library it links. – Hyperboreus Apr 23 '14 at 20:05
– Fredrik Pihl Apr 23 '14 at 20:08
@Hyperboreus You're not wrong, but FYI: At least CPython and PyPy roll their own implementation (they don't link to a third party library), and the two implementations are very similar aside from being written in rather different languages. – delnan Apr 23 '14 at 20:08
legacy.python.org/dev/peps/pep-0237 – M4rtini Apr 23 '14 at 20:13

CPython's arbitrary precision integers are stored an array of binary `digits`. Each `digit` consists of either 15 or 30 bits. Addition, subtraction, and bit shifts are all O(n). Multiplication (for large enough values) uses Karatsuba multiplication which is O(n**1.585). Division still uses the classical O(n**2) algorithm.

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Well, I wrote this. I'm not sure how good this is, but you can use it as a starting point for a more refined and complete benchmark.

``````import timeit

def timef(f, *args):
return timeit.timeit(lambda: f(*args), number = 1000000) # repetitions

tests = {
'addition'      : lambda x: x + 17,
'substraction'  : lambda x: x - 17,
'multiplication': lambda x: x * 17,
'division'      : lambda x: x / 17,
'float division': lambda x: x / 17.0
}

for name, f in tests.items():
print  'int {0}'.format(name).ljust(20), timef(f, 0)
print 'long {0}'.format(name).ljust(20), timef(f, 10 ** 50)
print
``````

What I'm seeing is that `int()` operations are indeed faster, but not a lot faster.

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