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so the function would be something like primesearch::Int -> [Int]. For example, primesearch 4 = [2,3,5,7]. Would you need to use the sieve function somehow? or is there another way of doing it?

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4 Answers 4

To generate the first k prime numbers, or the prime numbers <= n, I recommend a sieve. Which kind of sieve depends on how many primes you want. For small numbers of primes, a monolithic Eratosthenes bit sieve is simple and fast. But if you want large numbers of primes, a monolithic sieve would need too much memory, so a segmented sieve is then the better option. For very small numbers of primes (the primes <= 100000, say), a trial division is even easier, but still sufficiently fast.

If you want to earnestly use primes, there are already packages on hackage which provide prime generators, for example arithmoi and NumberSieves. There are others, but as far as I know, all the others are significantly slower.

If it's for homework or similar, which method is the most appropriate depends on what the exercise shall teach.

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Check out this link. It shows several approaches, ranging from simple to understand to efficient.

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Another fun article is http://www.cs.hmc.edu/~oneill/papers/Sieve-JFP.pdf. It is referenced by qrl's link, but is worth checking out on its own. It provides better explanations than qrl's link, but does not provide nearly as many implementations.

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I've personally found the article's explanations very confusing, and could finally make sense of it all only from its math analysis (contradicted in part by those very explanations - re the question of starting (in which algorithm?) from squares of primes). –  Will Ness Mar 9 '12 at 9:23

Here's the fastest of the simplest, in the low ranges of up to a million primes or so:

{-# OPTIONS_GHC -O2 #-}
import Data.Array.Unboxed

primesToA m = sieve 3 (array (3,m) [(i,odd i) | i<-[3..m]]
                       :: UArray Int Bool)
    sieve p a 
      | p*p > m   = 2 : [i | (i,True) <- assocs a]
      | a!p       = sieve (p+2) $ a//[(i,False) | i <- [p*p, p*p+2*p..m]]
      | otherwise = sieve (p+2) a

(thanks to Daniel Fischer for adding this little thing called explicit type signature here, thus making it work on unboxed arrays). The kicker is, there's a destructive update going on here behind the scenes. (apparently not).

As for the JFP article, it misses the key reason for the Turner's code abysmal inefficiency, - in fact dismisses it as irrelevant, - presents the sieve's definition in imprecise and confusing manner, and offers very confused and incoherent verbal explanations, together with sound and enlightening math analysis. As for the main dish, after all the build-up it doesn't even make any claims as to its priority queue-based code's run-time complexity. And in fact, its empirical complexity is worse than the optimal, theoretical value (plus the final code in article has major flaw, corrected later in the distributed code file).

edit: this was in response to your title, but in the text it seems you want to generate a set number of primes, not primes up to a given value. The upper limit value is easy to over-estimate, so that

nPrimes n | n > 3 =
    x = fromIntegral n
    m = ceiling $ x*(log x + log (log x))
    take n $ primesToA m
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Which part of the code exactly does the destructive update? –  is7s Mar 7 '12 at 16:30
@is7s the array-update (//) in tail-recursive call. I deduce this from its low-ish empirical run-time cpxty of ~k^1.3 (log of ratio of run times in base of ratio of sizes), and from the fact that with the explicit signature removed, it runs at O(k^1.8) and above (in k primes produced), and orders of magnitude slower. (trial division runs at k^1.45 and good PQ or tree-folding code at k^1.2) –  Will Ness Mar 7 '12 at 16:44
I think you are mistaken. Such an optimisation is not possible since a UArray is immutable. The fact that it's relatively fast doesn't mean that it uses destructive updates. –  is7s Mar 7 '12 at 16:52
@is7s run-time cpxty is my evidence. for a sieve up to m producing k primes, we have pi(sqrt m) steps for each prime p_i below it, each generating and removing n_i = O(m/p_i) multiples. Generating n_i multiples obviously takes n_i time. If each is removed at O(1) time we get theoretical cpxty of O(k*log k*log(log k)), which is empirically below O(k^1.2). –  Will Ness Mar 7 '12 at 16:58
@is7s or maybe not fully destructive (for it does run above what it should if that were the case) but at least it seems to update the whole list of multiples at once. I interpret the increased cpxty of boxed arrays as each removal step for each prime taking much longer, cpxty-wise as well. I don't remember exactly but memory consumption should be drastically smaller as well for the unboxed, which again I'd interpret as evidence towards destructive update. –  Will Ness Mar 7 '12 at 17:03

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