**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
[71,839,1471,6857,59569,104441,486847Interrupted.
```

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..]
[[71,839,1471,6857],[2,2,2,3,3,1259Interrupted.
```

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
[71,839,1471,6857,59569,104441,486847,600851475143]
```

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)
[600851475149]
```

Since `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
[(71,8462696833),(839,10086647),(1471,6857),(6857,1),(1,1),(1,1),(1,1),(1,1),(1,
1),(1,1),(1,1),(1,1),(1,1),(1,1),(1,1),(1,1),(1,1),(1,1)Interrupted
```

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..]
[[71,839,1471,6857],[2,2,2,3,3,1259,6628403],[5,120170295029],[2,13,37,227,27514
79],[3,7,7,11,163,2279657],[2,2,41,3663728507],*[600851475149]*,[2,3,5,5,19,31,680
0809],*[600851475151]*,[2,2,2,2,37553217197],[3,3,3,211,105468049],[2,7,11161,3845
351],[5,67,881,2035853],[2,2,3Interrupted.