TL;DR: The two things you were doing non-optimally, are: not stopping at the square root, and not dividing out each smallest factor, as they are found.
Here's a little derivation of the (2nd) factorization code shown in the answer by HaskellElephant. We start with your code:
f1 n = [ x | x <- [2..n], rem n x == 0]
n3 = 600851475143
Prelude> f1 n3
So it doesn't finish in any reasonable amount of time, and some of the numbers it produces are not prime... But instead of adding primality check to the list comprehension, let's notice that 71 is prime. The first number produced by
f1 n is the smallest divisor of
n, and thus it is prime. If it weren't, we'd find its smallest divisor first - a contradiction.
So, we can divide it out, and continue searching for the prime factors of newly reduced number:
f2 n = tail $ iterate (\(_,m)-> (\f->(f, quot m f)) . head $ f1 m) (1,n)
Prelude> f2 n3
[(71,8462696833),(839,10086647),(1471,6857),(6857,1),(*** Exception: Prelude.hea
d: empty list
(the error, because
f1 1 == ). We're done! (6857 is the answer, here...). Let's wrap it up:
takeUntil p xs = foldr (\x r -> if p x then [x] else x:r)  xs
pfactors1 n = map fst . takeUntil ((==1).snd) . f2 $ n -- prime factors of n
Trying out our newly minted solution,
Prelude> map pfactors1 [n3..]
suddenly we hit a new inefficiency wall, on numbers without small divisors. But if
n = a*b and
1 < a <= b, then
a*a <= a*b == n and so it is enough to test only until the square root of a number, to find its smallest divisor.
f12 n = [ x | x <- takeWhile ((<= n).(^2)) [2..n], rem n x == 0] ++ [n]
f22 n = tail $ iterate (\(_,m)-> (\f->(f, quot m f)) . head $ f12 m) (1,n)
pfactors2 n = map fst . takeUntil ((==1).snd) . f22 $ n
What couldn't finish in half an hour now finishes in under one second (on a typical performant box):
Prelude> f12 n3
All the divisors above
sqrt n3 were not needed at all. We unconditionally add
n itself as the last divisor in
f12 so it is able to handle prime numbers:
Prelude> f12 (n3+6)
n3 / sqrt n3 = sqrt n3 ~= 775146, your original attempt at
f1 n3 should have taken about a week to finish. That's how important this optimization is, of stopping at the square root.
Prelude> f22 n3
We've apparently traded the "Prelude.head: empty list" error for a non-terminating - but productive - behavior.
Lastly, we break
f22 up in two parts and fuse them each into the other functions, for a somewhat simplified code. Also, we won't start over anew, as
f12 does, searching for the smallest divisor from 2 all the time, anymore:
-- smallest factor of n, starting from d. directly jump from sqrt n to n.
smf (d,n) = head $ [ (x, quot n x) | x <- takeWhile ((<=n).(^2)) [d..]
, rem n x == 0] ++ [(n,1)]
pfactors n = map fst . takeUntil ((==1).snd) . tail . iterate smf $ (2,n)
This expresses guarded (co)recursion through a higher-order function
iterate, and is functionally equivalent to that code mentioned above. The following now runs smoothly, and we're even able to find a pair of twin primes as a bonus there:
Prelude Saga> map pfactors [n3..]