# AKS Primes algorithm in Python

A few years ago, it was proven that PRIMES is in P. Are there any algorithms implementing their primality test in Python? I wanted to run some benchmarks with a naive generator and see for myself how fast it is. I'd implement it myself, but I don't understand the paper enough yet to do that.

-
AKS is of great theoretical importance but its performance is terrible (Miller-Rabin is much better). There are many primality tests implemented in Python. – J.F. Sebastian Dec 7 '08 at 18:07
Just so you know: the answer you've accepted is an exponential-time algorithm, not the AKS algorithm. (See section on Wikipedia, or even the "Note" at the top of the Rosettacode page.) – ShreevatsaR May 2 '15 at 18:30

Yes, go look at AKS test for primes page on rosettacode.org

``````def expand_x_1(p):
ex = [1]
for i in range(p):
ex.append(ex[-1] * -(p-i) / (i+1))
return ex[::-1]

def aks_test(p):
if p < 2: return False
ex = expand_x_1(p)
ex[0] += 1
return not any(mult % p for mult in ex[0:-1])
print('# p: (x-1)^p for small p')
for p in range(12):
print('%3i: %s' % (p, ' '.join('%+i%s' % (e, ('x^%i' % n) if n else '')
for n,e in enumerate(expand_x_1(p)))))

print('\n# small primes using the aks test')
print([p for p in range(101) if aks_test(p)])
``````

and the output is:

``````# p: (x-1)^p for small p
0: +1
1: -1 +1x^1
2: +1 -2x^1 +1x^2
3: -1 +3x^1 -3x^2 +1x^3
4: +1 -4x^1 +6x^2 -4x^3 +1x^4
5: -1 +5x^1 -10x^2 +10x^3 -5x^4 +1x^5
6: +1 -6x^1 +15x^2 -20x^3 +15x^4 -6x^5 +1x^6
7: -1 +7x^1 -21x^2 +35x^3 -35x^4 +21x^5 -7x^6 +1x^7
8: +1 -8x^1 +28x^2 -56x^3 +70x^4 -56x^5 +28x^6 -8x^7 +1x^8
9: -1 +9x^1 -36x^2 +84x^3 -126x^4 +126x^5 -84x^6 +36x^7 -9x^8 +1x^9
10: +1 -10x^1 +45x^2 -120x^3 +210x^4 -252x^5 +210x^6 -120x^7 +45x^8 -10x^9 +1x^10
11: -1 +11x^1 -55x^2 +165x^3 -330x^4 +462x^5 -462x^6 +330x^7 -165x^8 +55x^9 -11x^10 +1x^11

# small primes using the aks test
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97]
``````
-
This is not the AKS algorithm; this is an exponential-time algorithm that implements the elementary idea behind the AKS algorithm with none of the ideas that makes it polynomial-time. – ShreevatsaR Apr 24 '15 at 14:27

Quick answer: no, the AKS test is not the fastest way to test primality. There are much much faster primality tests that either assume the (generalized) Riemann hypothesis and/or are randomized. (E.g. Miller-Rabin is fast and simple to implement.) The real breakthrough of the paper was theoretical, proving that a deterministic polynomial-time algorithm exists for testing primality, without assuming the GRH or other unproved conjectures.

That said, if you want to understand and implement it, Scott Aaronson's short article might help. It doesn't go into all the details, but you can start at page 10 of 12, and it gives enough. :-) There is also a list of implementations (mostly in C++) here.

Also, for optimization and improvements (by several orders of magnitude), you might want to look at this report, or (older) Crandall and Papadopoulos's report, or (older still) Daniel J Bernstein's report. All of them have fairly detailed pseudo-code that lends itself well to implementation.

-
Update: Another good exposition of the mathematics,by Terence Tao, here: terrytao.wordpress.com/2009/08/11/the-aks-primality-test – ShreevatsaR Feb 12 '10 at 17:28
The AKS-Test isn't the fastest way, but it is a the first fool-proof test for primes. – Progo Mar 29 '14 at 12:15
@Progo: More precisely, it's the first test which we can prove is fool-proof and polynomial-time. There are other tests which we strongly believe are actually perfectly fool-proof (e.g. because it is possible to prove them assuming strongly-believed conjectures like the Riemann Hypothesis), and there are also other tests which we can prove are perfectly fool-proof, and which almost invariably run fast, but which we can't prove are polynomial-time. The breakthrough of the AKS was doing both. – ShreevatsaR Mar 29 '14 at 12:18
@Progo, clearly you watched the numberphile video, which is very misleading. It is not the fastest way, isn't the first fool-proof test, isn't the fastest fool-proof test, etc. It is deterministic polynomial time, which we didn't have before without assuming the ERH. We had (and still use today) APR-CL which is effectively polynomial time for any input we will be computing. We had, and still use, ECPP which is expected polynomial time (but could run slowly due to randomness). Both are "fool-proof" methods and are much faster. – DanaJ Jun 4 '15 at 1:42