Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I've started learning Haskell in the last couple of days and I'm having trouble with this piece of code. I'm trying to make a function that will generate a list of primes given an initial list (contains at least 2), a maximum list length, the index of the current divisor (should start at 1, tests by dividing current number by all primes so far) and the current number to test (an odd number).

I know it's not very elegant or efficient but this code won't compile or run so I'd like to fix it first before optimizing. Although suggestions on that would be cool too.

primes = [2,3,5,7,11,13]

genPrimes primes max curDiv curTest 
  | length primes >= max = primes
  | primes !! curDiv > floor . sqrt curTest = genPrimes (primes ++ [curTest]) max 1 (curTest + 2)
  | curTest `mod` primes !! curDiv == 0 = genPrimes primes max 1 (curTest + 2) 
  | curTest `mod` primes !! curDiv /= 0 = genPrimes primes max (curDiv + 1) curTest

I get the following error when I try to compile the above code:

Couldn't match expected type `a0 -> c0' with actual type `Integer'
Expected type: [a0 -> c0]
  Actual type: [Integer]
In the first argument of `genPrimes', namely `primes'
In the expression: genPrimes primes 50 1 15
share|improve this question
It's generally a good idea to post the exact error message in addition to the code that gives you the error. This makes it easier for us to help you. –  dave4420 Dec 25 '11 at 9:02
add comment

3 Answers

up vote 1 down vote accepted

ja. gave already the correct answer, but your solution isn't very idiomatic. Here is an easy way to generate an infinite list of primes:

primes = 2 : filter isPrime [3,5..]

isPrime n = all ((/=0).(n `mod`)) $ takeWhile (\p -> p*p <= n) primes

primes is easy to understand, it defines 2 as prime, and inspects all following odd numbers if they are prime. isPrime is a little bit more complicated: First we take all primes smaller or equal to the square root of n. Then we check if we divide n by all of these primes that we have no reminder equal to 0. isPrime refers back to primes, but this is no problem as Haskell is lazy, and we never need "too much" primes for our check.

The list primes is infinite, but you can just write something like take 10 primes.

Note that this code has its own problems, see http://www.cs.hmc.edu/~oneill/papers/Sieve-JFP.pdf

share|improve this answer
It makes sense, even though lambda expressions are still a little scary for me. But what I don't understand is why this runs somewhat faster than my code, since it is essentially doing the same thing. Am I correct in understanding that (n mod) is just a function with one input? How can you do that without explicitly defining an input? –  alkjiughh17652 Dec 25 '11 at 9:41
Never mind I figured it out ;p –  alkjiughh17652 Dec 25 '11 at 9:48
@hydroxide better start with [en.wikipedia.org/wiki/Sieve_of_Eratosthenes]. –  Will Ness Dec 25 '11 at 10:04
add comment

At the very least your code should be

primes = [2,3,5,7,11,13]

genPrimes primes max = go primes (length primes) 1 (last primes + 2)
  go prs len d t 
   | len >= max               = prs
   | (prs !! d) > (floor . sqrt . fromIntegral) t
                              = go (prs++[t]) (len+1) 1 (t + 2)
   | t `rem` (prs !! d) == 0  = go  prs        len    1 (t + 2) 
   | t `rem` (prs !! d) /= 0  = go  prs        len  (d + 1)  t

test n = print $ genPrimes primes n
main = test 20

Then you reorganize it thus (abstracting away the tests performed for each candidate number, as the noDivs function):

genPrimes primes max = go primes (length primes) (last primes + 2)
  go prs len t 
   | len >= max      = prs
   | noDivs (floor . sqrt . fromIntegral $ t) t prs
                     = go (prs++[t]) (len+1) (t + 2)
   | otherwise       = go  prs        len    (t + 2)

noDivs lim t (p:rs)
   | p > lim         = True
   | t `rem` p == 0  = False
   | otherwise       = noDivs lim t rs 

then you rewrite noDivs as

noDivs lim t = foldr (\p r -> p > lim || rem t p /= 0 && r) False

then you notice that go just filters numbers through such that pass the noDivs test:

genPrimes primes max = take max (primes ++ filter theTest [t, t+2..])
  t = last primes + 2
  theTest t = noDivs (floor . sqrt . fromIntegral $ t) t

but this doesn't work yet, because theTest needs to pass primes (whole new primes as they are being found) to noDivs, but we are building this whole_primes list (as take max (primes ++ ...)), so is there a vicious circle? No, because we only test up to the square root of a number:

genPrimes primes max = take max wholePrimes 
  wholePrimes = primes ++ filter theTest [t, t+2..]
  t           = last primes + 2
  theTest t   = noDivs (floor . sqrt . fromIntegral $ t) t wholePrimes

This is working now. But finally, there's nothing special in genPrimes now, it's just a glorified call to take, and initial primes list can actually be shrunk, so we get (changing the arguments arrangement for noDivs a little, to make its interface more general):

primes = 2 : 3 : filter (noDivs $ tail primes)  [5, 7..]

noDivs factors t = -- return True if the supplied list of factors is too short
  let lim = (floor . sqrt . fromIntegral $ t) 
  in foldr (\p r-> p > lim || rem t p /= 0 && r) True factors
     -- all ((/=0).rem t) $ takeWhile (<= lim) factors
     -- all ((/=0).rem t) $ takeWhile ((<= t).(^2)) factors
     -- and [rem t f /= 0 | f <- takeWhile ((<= t).(^2)) factors]

The global primes list is indefinitely defined now (i.e. "infinite"). Next step is to realize that between the consecutive squares of primes the length of the list of factors to test by will be the same, incrementing by 1 for each new segment. Then, that having all the factors upfront as the prefix (of known length) of the global primes list, we can directly generate their multiples (thus each being generated just from its prime factors), instead of testing each number whether it is a multiple of any one of the prime factors below its square root, in sequence.

share|improve this answer
Yes it's much nicer, thanks!! I was looking for a way to hide those "helper" variables with recursion -- I've had this problem several times. –  alkjiughh17652 Dec 25 '11 at 9:36
@hydroxide check out the additional code here. :) –  Will Ness Dec 25 '11 at 10:12
add comment

You've got the arguments to ':' reversed: the scalar goes to the left, or you can make a singleton list and concatenate:

| primes !! curDiv > floor . sqrt curTest = genPrimes (primes++[curTest]) max 1 curTest + 2
share|improve this answer
Okay thanks, didn't know that. Changed it to concatenate the lists, but now I get a runtime error.. edited my original post. –  alkjiughh17652 Dec 25 '11 at 9:08
add comment

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.