# Why is pow(a, d, n) so much faster than a**d % n?

I was trying to implement a Miller-Rabin primality test, and was puzzled why it was taking so long (> 20 seconds) for midsize numbers (~7 digits). I eventually found the following line of code to be the source of the problem:

``````x = a**d % n
``````

(where `a`, `d`, and `n` are all similar, but unequal, midsize numbers, `**` is the exponentiation operator, and `%` is the modulo operator)

I then I tried replacing it with the following:

``````x = pow(a, d, n)
``````

and it by comparison it is almost instantaneous.

For context, here is the original function:

``````from random import randint

def primalityTest(n, k):
if n < 2:
return False
if n % 2 == 0:
return False
s = 0
d = n - 1
while d % 2 == 0:
s += 1
d >>= 1
for i in range(k):
rand = randint(2, n - 2)
x = rand**d % n         # offending line
if x == 1 or x == n - 1:
continue
for r in range(s):
toReturn = True
x = pow(x, 2, n)
if x == 1:
return False
if x == n - 1:
toReturn = False
break
if toReturn:
return False
return True

print(primalityTest(2700643,1))
``````

An example timed calculation:

``````from timeit import timeit

a = 2505626
d = 1520321
n = 2700643

def testA():
print(a**d % n)

def testB():
print(pow(a, d, n))

print("time: %(time)fs" % {"time":timeit("testA()", setup="from __main__ import testA", number=1)})
print("time: %(time)fs" % {"time":timeit("testB()", setup="from __main__ import testB", number=1)})
``````

Output (run with PyPy 1.9.0):

``````2642565
time: 23.785543s
2642565
time: 0.000030s
``````

Output (run with Python 3.3.0, 2.7.2 returns very similar times):

``````2642565
time: 14.426975s
2642565
time: 0.000021s
``````

And a related question, why is this calculation almost twice as fast when run with Python 2 or 3 than with PyPy, when usually PyPy is much faster?

See the Wikipedia article on modular exponentiation. Basically, when you do `a**d % n`, you actually have to calculate `a**d`, which could be quite large. But there are ways of computing `a**d % n` without having to compute `a**d` itself, and that is what `pow` does. The `**` operator can't do this because it can't "see into the future" to know that you are going to immediately take the modulus.

• +1 that's actually what the docstring implies `>>> print pow.__doc__ pow(x, y[, z]) -> number With two arguments, equivalent to x**y. With three arguments, equivalent to (x**y) % z, but may be more efficient (e.g. for longs).` Jan 3, 2013 at 6:06
• Depending on your Python version, this may only be true under certain conditions. IIRC, in 3.x and 2.7, you can only use the three-argument form with integral types (and non-negative power), and you will always get modular exponentiation with the native `int` type, but not necessarily with other integral types. But in older versions there were rules about fitting into a C `long`, the three-argument form was allowed for `float`, etc. (Hopefully you're not using 2.1 or earlier, and aren't using any custom integral types from C modules, so none of this matters to you.) Jan 3, 2013 at 6:12
• From your answer it seems like it is impossible for a compiler to see the expression and optimize it, which isn't true. It just happens that no current Python compilers do it. Jan 3, 2013 at 12:27
• @danielkza: That's true, I didn't mean to imply it's theoretically impossible. Maybe "doesn't look into the future" would be more accurate than "can't see into the future". Note, though, that the optimization could be extremely difficult or even impossible in general. For constant operands it could be optimized, but in `x ** y % n`, `x` could be an object that implements `__pow__` and, based on a random number, returns one of several different objects implementing `__mod__` in ways that also depend on random numbers, etc. Jan 3, 2013 at 19:12
• @danielkza: Also, the functions don't have the same domain: `.3 ** .4 % .5` is perfectly legal, but if the compiler transformed that into `pow(.3, .4, .5)` that would raise a `TypeError`. The compiler would have to be able to know that `a`, `d`, and `n` are guaranteed to be values of an integral type (or maybe just specifically of type `int`, because the transformation doesn't help otherwise), and `d` is guaranteed to be non-negative. That's something a JIT could conceivably do, but a static compiler for a language with dynamic types and no inference just can't. Jan 3, 2013 at 19:48

why is it almost twice as fast when run with Python 2 or 3 than PyPy, when usually PyPy is much faster?

If you read PyPy's performance page, this is exactly the kind of thing PyPy is not good at—in fact, the very first example they give:

Bad examples include doing computations with large longs – which is performed by unoptimizable support code.

Theoretically, turning a huge exponentiation followed by a mod into a modular exponentiation (at least after the first pass) is a transformation a JIT might be able to make… but not PyPy's JIT.

As a side note, if you need to do calculations with huge integers, you may want to look at third-party modules like `gmpy`, which can sometimes be much faster than CPython's native implementation in some cases outside the mainstream uses, and also has a lot of additional functionality that you'd otherwise have to write yourself, at the cost of being less convenient.

• longs got fixed. try pypy 2.0 beta 1 (it won't be faster than CPython, but should not be slower either). gmpy does not have a way to handle MemoryError :( Jan 5, 2013 at 21:26
• @fijal: Yeah, and `gmpy` is also slower instead of faster in a few cases, and makes a lot of simple things less convenient. It's not always the answer—but sometimes it is. So it's worth looking at if you're dealing with huge integers and Python's native type doesn't seem fast enough. Jan 6, 2013 at 12:01
• and if you don't care if your numbers being big makes your program segfault Jan 7, 2013 at 18:58
• It's the factor that made PyPy not use GMP library for it's longs. It might be ok for you, it's not ok for Python VM developers. The malloc can fail without using a lot of RAM, just put a very large number there. Behavior of GMP from that point on is undefined and Python can't allow this. Jan 7, 2013 at 21:42
• @fijal: I completely agree that it shouldn't be used for implementing Python's built-in type. That doesn't mean it shouldn't ever be used for anything ever. Jan 7, 2013 at 23:30

There are shortcuts to doing modular exponentiation: for instance, you can find `a**(2i) mod n` for every `i` from `1` to `log(d)` and multiply together (mod `n`) the intermediate results you need. A dedicated modular-exponentiation function like 3-argument `pow()` can leverage such tricks because it knows you're doing modular arithmetic. The Python parser can't recognize this given the bare expression `a**d % n`, so it will perform the full calculation (which will take much longer).

The way `x = a**d % n` is calculated is to raise `a` to the `d` power, then modulo that with `n`. Firstly, if `a` is large, this creates a huge number which is then truncated. However, `x = pow(a, d, n)` is most likely optimized so that only the last `n` digits are tracked, which are all that are required for calculating multiplication modulo a number.

• "it requires d multiplications to calculate x**d" -- not correct. You can do it in O(log d) (very wide) multiplications. Exponentiation by squaring can be used without a module. The sheer size of the multiplicands is what takes the lead here. Jan 3, 2013 at 6:10
• @JanDvorak True, I'm not sure why I thought python wouldn't utilize the same exponentiation algorithm for `**` as for `pow`. Jan 3, 2013 at 6:14
• Not the last "n" digits.. it just keeps calculations in Z/nZ. Jan 3, 2013 at 8:20