# How did Python implement the built-in function pow()?

I have to write a program to calculate `a**b % c` where `b` and `c` are both very large numbers. If I just use `a**b % c`, it's really slow. Then I found that the built-in function `pow()` can do this really fast by calling `pow(a, b, c)`.
I'm curious to know how does Python implement this? Or where could I find the source code file that implement this function?

• The cpython source repo is at hg.python.org/cpython – Wooble Mar 9 '11 at 14:07
• ...under Objects/longobject.c:long_pow() (as JimB had already commented). – smci Jul 19 '11 at 20:45

If `a`, `b` and `c` are integers, the implementation can be made more efficient by binary exponentiation and reducing modulo `c` in each step, including the first one (i.e. reducing `a` modulo `c` before you even start). This is what the implementation of `long_pow()` does indeed. The function has over two hundred lines of code, as it has to deal with reference counting, and it handles negative exponents and a whole bunch of special cases.

At its core, the idea of the algorithm is rather simple, though. Let's say we want to compute `a ** b` for positive integers `a` and `b`, and `b` has the binary digits `b_i`. Then we can write `b` as

``````b = b_0 + b1 * 2 + b2 * 2**2 + ... + b_k ** 2**k
``````

ans `a ** b` as

``````a ** b = a**b0 * (a**2)**b1 * (a**2**2)**b2 * ... * (a**2**k)**b_k
``````

Each factor in this product is of the form `(a**2**i)**b_i`. If `b_i` is zero, we can simply omit the factor. If `b_i` is 1, the factor is equal to `a**2**i`, and these powers can be computed for all `i` by repeatedly squaring `a`. Overall, we need to square and multiply `k` times, where `k` is the number of binary digits of `b`.

As mentioned above, for `pow(a, b, c)` we can reduce modulo `c` in each step, both after squaring and after multiplying.

• Why can we reduce by modulo c in each step? – Ben Sandler Aug 30 '15 at 22:26
• @BenSandler: Because aa' (mod c) and bb' (mod c) imply aba'b' (mod c), or in other words, it doesn't matter whether you first reduce a and b modulo c and then multiply them, or multiply them first and then reduce modulo c. See the Wikipedia article on modular arithmetic. – Sven Marnach Aug 31 '15 at 12:53
• Note that `long_pow` is now defined at another line in that file: github.com/python/cpython/blob/master/Objects/… – JohanC Dec 8 '19 at 21:57
• @JohanC I've updated the link to include the commit hash, so it doesn't get out of date anymore. – Sven Marnach Dec 9 '19 at 8:38

You might consider the following two implementations for computing `(x ** y) % z` quickly.

In Python:

``````def pow_mod(x, y, z):
"Calculate (x ** y) % z efficiently."
number = 1
while y:
if y & 1:
number = number * x % z
y >>= 1
x = x * x % z
return number
``````

In C:

``````#include <stdio.h>

unsigned long pow_mod(unsigned short x, unsigned long y, unsigned short z)
{
unsigned long number = 1;
while (y)
{
if (y & 1)
number = number * x % z;
y >>= 1;
x = (unsigned long)x * x % z;
}
return number;
}

int main()
{
printf("%d\n", pow_mod(63437, 3935969939, 20628));
return 0;
}
``````
• @Noctis, I tried running your Python implementation and got this:TypeError: ufunc 'bitwise_and' not supported for the input types, and the inputs could not be safely coerced to any supported types according to the casting rule ''safe'' ---- As I'm learning Python right now, I thought you might have an idea about this error (a search suggests it might be a bug but I'm thinking that there's a quick workaround) – stackuser May 7 '13 at 2:24
• @stackuser: It appears to be working fine in the following demonstration: ideone.com/sYzqZN – Noctis Skytower May 7 '13 at 12:50
• Can anyone explain why this solution works? I am having trouble understanding the logic behind this algorithm. – kilojoules May 24 '15 at 3:59
• @NoctisSkytower, what would be the benefit of this considering the native python `pow()` builtin function supports this as well and seems faster? `>>> st_pow = 'pow(65537L, 767587L, 14971787L) >>> st_pow_mod = 'pow_mod(65537L, 767587L, 14971787L)' >>> timeit.timeit(st_pow) 4.510787010192871 >>> timeit.timeit(st_pow_mod, def_pow_mod) 10.135776996612549` – Fabiano Jun 8 '16 at 3:25
• @Fabiano My function is not supposed to be used. It is simply an explanation of how Python works behinds the scenes without referring to its source in C. I was trying to answer wong2's question about how `pow` was implimented. – Noctis Skytower Jun 8 '16 at 13:18

Line 1426 of this file shows the Python code that implements math.pow, but basically it boils down to it calling the standard C library which probably has a highly optimized version of that function.

Python can be quite slow for intensive number-crunching, but Psyco can give you a quite speed boost, it won't be as good as C code calling the standard library though.

• `math.pow()` does't have the modulo argument, and isn't the same function as the builtin `pow()`. Also FYI, Psyco is getting pretty stale, and no 64-bit support. NumPy is great for serious math. – JimB Mar 9 '11 at 14:30

I don't know about python, but if you need fast powers, you can use exponentiation by squaring:

http://en.wikipedia.org/wiki/Exponentiation_by_squaring

It's a simple recursive method that uses the commutative property of exponents.

Python uses C math libraries for general cases and its own logic for some of its concepts (such as infinity).

Implement pow(x,n) in Python

``````def myPow(x, n):
p = 1
if n<0:
x = 1/x
n = abs(n)

# Exponentiation by Squaring

while n:
if n%2:
p*= x
x*=x
n//=2
return p
``````

Implement pow(x,n,m) in Python

``````def myPow(x,n,m):
p = 1
if n<0:
x = 1/x
n = abs(n)
while n:
if n%2:
p*= x%m
x*=x%m
n//=2
return p
``````