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I recently stumbled upon a paper on a parallelization of the Pollard-rho algorithm, and given my specific application, in addition to the fact that I haven't attained the required level of math, I'm wondering if this particular parallelization method helps my specific case.

I'm trying to find two factors--semiprimes--of a very large number. My assumption, based on what little I can understand of the paper, is that this parallelization works well on a number with lots of smaller factors, rather than two very large factors.

Is this true? Should I use this parallelization or use something else? Should I even use Pollard-rho, or is there a better parallelization of a different factorization algorithm?

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How large is your very-large number? How many decimal digits? –  user448810 Sep 26 '11 at 0:59
    
Anywhere from 2^16 (5 decimal digits) to 2^8192 (2467 decimal digits). I'm guessing I'd probably use a number of different algorithms, depending on the magnitude of the number, though I'm not sure. I know that Pollard-rho is a specialized algorithm, but I haven't found many parallelizations of other algorithms, so I'm struggling a little bit. –  skeggse Sep 26 '11 at 2:52
    
Note that, although 2^8192 is the theoretical upper bound, I do not expect to be able to factor anything that large. –  skeggse Sep 26 '11 at 3:02

2 Answers 2

up vote 3 down vote accepted

The basic idea in factoring large integers is to use a variety of methods, each with its own pluses and minuses. The usual plan is to start with trial division by primes to 1000 or 10000, followed by a few million Pollard rho steps; that ought to get you factors up to about twelve digits. At that point a few tests are in order: is the number a prime power or a perfect power (there are simple tests for those properties). If you still haven't factored the number, you know that it will be hard, so you will need heavy-duty tools. A useful next step is Pollard's p-1 method, followed by its close cousin the elliptic curve method. After a while, if that doesn't work, the only methods left are quadratic sieve or number field sieve, which are inherently parallel.

The parallel rho method that you asked about isn't widely used today. As you suggested, Pollard rho is better suited to finding small factors rather than large ones. For a semi-prime, it's better to spend parallel cycles on one of the sieves than on Pollard rho.

I recommend the factoring forum at mersenneforum.org for more information.

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One small problem. The methods you recommended are fairly complex, and I can't seem to find any algorithm specification or pseudocode. Given that my mathematics background is somewhat limiting, I can't just go to the source and try to come up with the code on my own. –  skeggse Sep 26 '11 at 13:57
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You don't need to do it yourself. Go to the factoring forum at mersenneforum.org. They have pointers to programs like gmp-ecm, msieve and others that are both freely available and also the best available factoring programs. If you have to do it yourself, my blog at programmingpraxis.com has descriptions and source code for most of those factoring algorithms, though not yet the two sieves. –  user448810 Sep 26 '11 at 19:59

The wikipedia article states two concrete examples:

Number                Original code      Brent's modification
18446744073709551617  26 ms              5 ms
10023859281455311421  109 ms             31 ms

First of all, run these two with your program and take a look at your times. If they are similar to this ("hard" numbers calculating 4-6 times longer), ask yourself if you can live with that. Or even better, use other algorithms like simple classic "brute force" factorization and look at the times they give. I guess they might have a hard-easy factor closer to 1, but worse absolute times, so it's a simple trade-off.

Side note: Of course, parallelization is the way to go here, I guess you know that but I think it's important to emphasize. Also, it would help for the case that another approach lies between the Pollard-rho timings (e.g. Pollard-Rho 5-31 ms, different approach 15-17 ms) - in this case, consider running the 2 algorithms in seperate threads to do a "factorization race".

In case you don't have an actual implementation of the algorithm yet, here are Python implementations.

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Many thanks, I had been unable to access the original document, so this implementation has proved most useful. –  skeggse Sep 26 '11 at 13:55

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