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While investigating the Arecibo message I tried to implement semiprimality tests in Haskell. I've come up with two versions:

isSemiprime1 :: Int -> Bool
isSemiprime1 n = (length factors) == 2 && (product factors) == n ||
                (length factors) == 1 && (head factors) ^ 2 == n
                    where factors = primeFactors n

isSemiprime2 :: Int -> Bool
isSemiprime2 n =
            case (primeFactors n) of
              [f1, f2] -> f1 * f2 == n
              [f] -> f ^ 2 == n
              otherwise -> False

I ran some benchmarks using defaultMain (from the package Criterion.Main) and isSemiprime2 turned out slightly faster. Can you think of some more clever implementations, cause I don't think this is the cream of the crop :). I'm specifically interested in concise, heavily functional implementations.

Also, if anyone is interested, here's my code for benchmarking:

main :: IO ()
main = defaultMain [
        bgroup "isSemiprime1" [ bench "169" $ whnf isSemiprime1 169
                              , bench "1679" $ whnf isSemiprime1 1679
        bgroup "isSemiprime2" [ bench "169" $ whnf isSemiprime2 169
                              , bench "1679" $ whnf isSemiprime2 1679
share|improve this question
isSemiprime2 should be faster - and if you use bigger numbers, the speed difference will become quite drastic. Regardless, I possit that primeFactors is where most of the time is being spent. – MathematicalOrchid Feb 20 '14 at 11:25
I would expect primeFactors to generate repeated primes, i.e. primeFactors 4 is [2, 2], so you don't need the square case. And if primeFactors generates the list lazily, isSemiprime2 is certainly a lot faster since it can take the otherwise branch when the 3rd factor is found. – Sjoerd Visscher Feb 20 '14 at 11:59
By the way, why not f*f instead of f^2 ? – Ingo Feb 20 '14 at 12:01
@Ingo: because it looks uglier and has no relevant advantage? (It's equivalent, being implemented in terms of *, safe for performance considerations, which doesn't matter here though because much more work is already done at that point anyway.) – leftaroundabout Feb 20 '14 at 13:47
Someone with a C background might think so, but they might also wonder why you multiply with a dereferenced pointer in e ** x, or use bitwise OR to build up guards. It's perfectly obvious in this case that we want exponentiation, in particular as the line above has f1 * f2 (which BTW, is quite an argument to write f * f after all – in particular, if you align the * in both lines). – leftaroundabout Feb 20 '14 at 15:07
up vote 1 down vote accepted

The two functions you listed have the same performance since they both use primeFactors where most of the time is spent. If you look at the implementation it's just doing trial division with successive numbers generated from the sieve. This is not the most efficient method.

If you want faster code you should use a better factorization algorithm. For example:

import Math.NumberTheory.Primes.Factorisation

isSemiprime3 :: Integer -> Bool
isSemiprime3 n = (length factors) == 2 && (product factors) == n ||
                (length factors) == 1 && (head factors) ^ 2 == n
                    where factors = map fst $ factorise n

results in:

benchmarking isSemiprime1/557672900621
collecting 100 samples, 1 iterations each, in estimated 13.84439 s
mean: 138.4969 ms, lb 138.3753 ms, ub 138.7278 ms, ci 0.950
std dev: 830.8696 us, lb 505.2076 us, ub 1.301439 ms, ci 0.950

benchmarking isSemiprime3/557672900621
mean: 5.315161 ms, lb 5.292123 ms, ub 5.397730 ms, ci 0.950
std dev: 198.7367 us, lb 59.15932 us, ub 453.7225 us, ci 0.950
found 5 outliers among 100 samples (5.0%)
  3 (3.0%) high mild
  2 (2.0%) high severe
variance introduced by outliers: 33.631%
variance is moderately inflated by outliers

benchmarking isSemiprime2/557672900621
collecting 100 samples, 1 iterations each, in estimated 13.85570 s
mean: 138.9948 ms, lb 138.8015 ms, ub 139.3493 ms, ci 0.950
std dev: 1.302262 ms, lb 844.1709 us, ub 2.330201 ms, ci 0.950

5 ms vs. 138 ms

share|improve this answer
this is an impressive speedup! Thanks for the suggestion. I'll take a look at the implementation. – Wojciech Gac Feb 21 '14 at 10:44
Hmm, I see that this method has the performance difference much more pronounced for large numbers. Tested with smaller numbers (like 1679) the speedup is of the order of 5. I definitely must look more closely into the method. Thanks again for the idea. – Wojciech Gac Feb 21 '14 at 13:23
For small numbers I would expect Math.NumberTheory.Primes.Factorisation to actually be slower. – Daniel Velkov Feb 21 '14 at 18:05

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