Simple deterministic primality testing for small numbers

I am aware that there are a number of primality testing algorithms used in practice (Sieve of Eratosthenes, Fermat's test, Miller-Rabin, AKS, etc). However, they are either slow (e.g. sieve), probabalistic (Fermat and Miller-Rabin), or relatively difficult to implement (AKS).

What is the best deterministic solution to determine whether or not a number is prime?

Note that I am primarily (pun intended) interested in testing against numbers on the order of 32 (and maybe 64) bits. So a robust solution (applicable to larger numbers) is not necessary.

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What language are you using? there might be an AKS implementation that already exist for it.. – amit Sep 29 '11 at 8:27
I can't use existing implementations. This is for use in competitions and such where I cannot use external code. I don't want to use AKS because it takes a long time to code/debug. I'm looking for something relatively simple to implement yet efficient. – tskuzzy Sep 29 '11 at 8:29
If you are calling primality test often and don't care much about space+all you need is speed, I suggest you precompute all the prime from 0 - 2^64 put it in a big lookup table. Or if you care about speed and space, either do memoization and/or precompute like the first million prime or so. For 32 bit there aren't that many of them primes.utm.edu/howmany.shtml – Piti Ongmongkolkul Sep 29 '11 at 8:39
@Piti: you can't precompute all primes to `2^64`. 32, yes. – Steve Jessop Sep 29 '11 at 8:53
yah i meant 32 sorry – Piti Ongmongkolkul Sep 29 '11 at 8:57

4 Answers

Up to `~2^30` you could brute force with trial-division.

Up to `3.4*10^14`, Rabin-Miller with the first 7 primes has been proven to be deterministic.

Above that, you're on your own. There's no known sub-cubic deterministic algorithm.

EDIT : I remembered this, but I didn't find the reference until now:

http://reference.wolfram.com/legacy/v5_2/book/section-A.9.4

PrimeQ first tests for divisibility using small primes, then uses the Miller-Rabin strong pseudoprime test base 2 and base 3, and then uses a Lucas test.

As of 1997, this procedure is known to be correct only for `n < 10^16`, and it is conceivable that for larger `n` it could claim a composite number to be prime.

So if you implement Rabin-Miller and Lucas, you're good up to 10^16.

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Trial division is not feasible in my case because the primality test will called many times and needs to be as efficient as possible. – tskuzzy Sep 29 '11 at 8:22
AKS is deterministic and works fine for all numbers – amit Sep 29 '11 at 8:22
@amit: But as the OP said, it's a nightmare to implement. And it is still slower than Rabin-Miller. – Mysticial Sep 29 '11 at 8:27
@amit: I never defined "efficient". If "efficient" means polynomial. Then yes AKS is efficient. But if "efficient" is sub-cubic, then no AKS isn't. – Mysticial Sep 29 '11 at 8:35
@amit: Agreed, lemme fix my answer. – Mysticial Sep 29 '11 at 8:43

If I didn't care about space, I would try precomputing all the primes below 2^32 (~4e9/ln(4e9)*4 bytes, which is less than 1GB), store them in the memory and use a binary search. You can also play with memory mapping of the file containing these precomputed primes (pros: faster program start, cons: will be slow until all the needed data is actually in the memory).

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And the list umopit.ru/CompLab/primes32eng.htm – Piti Ongmongkolkul Sep 29 '11 at 9:06

If you can factor n-1 it is easy to prove that n is prime, using a method developed by Edouard Lucas in the 19th century. You can read about the algorithm at Wikipedia, or look at my implementation of the algorithm at my blog. There are variants of the algorithm that require only a partial factorization.

If the factorization of n-1 is difficult, the best method is the elliptic curve primality proving algorithm, but that requires more math, and more code, than you may be willing to write. That would be much faster than AKS, in any case.

Are you sure that you need an absolute proof of primality? The Baillie-Wagstaff algorithm is faster than any deterministic primality prover, and there are no known counter-examples.

If you know that n will never exceed 2^64 then strong pseudo-prime tests using the first twelve primes as bases are sufficient to prove n prime. For 32-bit integers, strong pseudo-prime tests to the three bases 2, 7 and 61 are sufficient to prove primality.

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1. Use the Sieve of Eratosthenes to pre-calculate as many primes as you have space for. You can fit in a lot at one bit per number and halve the space by only sieving odd numbers (treating 2 as a special case).

2. For numbers from `Sieve.MAX_NUM` up to the square of `Sieve.MAX_NUM` you can use trial division because you already have the required primes listed. Judicious use of Miller-Rabin on larger unfactored residues can speed up the process a lot.

3. For numbers larger than that I would use one of the probabilistic tests, Miller-Rabin is good and if repeated a few times can give results that are less likely to be wrong than a hardware failure in the computer you are running.

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