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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
see e.g. – 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
1 – M4rtini Apr 23 '14 at 20:13

2 Answers 2

up vote 2 down vote accepted

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)

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

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