# Why is divide and conquer so fast? [closed]

So I recently decided to look into factorial computing functions, and I have found one that is so totally fast, it blows my mind:

``````def multiply_range(n, m):
print n, m
if n == m:
return n
if m < n:
return 1
else:
return multiply_range(n, (n+m)/2) * multiply_range((n+m)/2+1, m)

def factorial(n):
return multiply_range(1, n)
``````

This is insanely fast. Why? I understand how it works, i just don't understand how doing it this way can make things so much faster.

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## closed as not constructive by Konstantin Dinev, Rohan, Brian Clozel, Emil Vikström, Pavel StrakhovDec 1 '12 at 16:35

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I don't think it's any faster than a factorial with a traditional for loop. Have you measured it? –  kennytm Dec 1 '12 at 7:11

Contrary to @NPE's answer, your method is faster, only for very large numbers. For me, I began to see the divide and conquer method become faster for inputs ~10^4. At 10^6 and above there is no comparison a traditional loop fails miserably.

I'm no expert on hardware multipliers and I hope someone can expand on this, but my understanding is that multiplication is done digit for digit same way we are taught in grade school.

A traditional factorial loop will start with small numbers and the result keeps growing. In the end you are muliplying a ginormous number with a comparatively small number, an expensive calculation due to the mismatch in digits.

ex. compare

``````reduce(operator.mul, range(1,10**5))
reduce(operator.mul, range(10**5,1,-1))
``````

the second is slower because the result grows fast, leading to more expensive calculations sooner.

Your method is faster than either of these by orders of magnitude for large numbers because it divides the factorial into similarly sized parts. The sub-results have similar numbers of digits and multiply faster.

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This observation is true. However, it's worth pointing out that it is predicated on some highly unrealistic assumptions, namely that anyone would want to to compute factorial: (1) iteratively (rather than analytically); (2) exactly; and (3) using integer maths, and do this on inputs of the order of 10**5. –  NPE Dec 1 '12 at 17:12
I think the OP makes these assumptions, and secondly it's usually around 10^(10^x) that you switch to stirling's approximation –  kalhartt Dec 1 '12 at 17:48

The short answer is that you're mistaken. It is not very fast:

``````In [34]: %timeit factorial(100)
10000 loops, best of 3: 57.6 us per loop

In [35]: %timeit reduce(operator.mul, range(1, 101))
100000 loops, best of 3: 19.9 us per loop
``````

In other words, it is about three times slower than a straightforward one-liner.

For smaller values of `n` the difference is even more dramatic.

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Strictly speaking your comparison isn't entirely fair, as the second example is only computing 99 factorial. However, I can't imagine that multiplying by 100 would add much more than about 1% to the running time. –  Luke Woodward Dec 1 '12 at 13:23
@LukeWoodward: Nice catch, thanks! –  NPE Dec 1 '12 at 13:25
try bigger inputs, divide and conquer is meant for large factorials –  kalhartt Dec 1 '12 at 16:04