Daniel Wagner's answer explains the general strategy of deriving bounds for the runtime complexity rather well. However, as is usually the case for general strategies, it yields too conservative bounds.

So, just for the heck of it, let's investigate this example in some more detail.

```
main = print (head (filter isPrime (filter ((==0) . (n `mod`)) [n-1,n-2..])))
where n = 600851475143
```

(Aside: if `n`

were prime, this would cause a runtime error when checking `n `mod` 0 == 0`

, thus I change the list to `[n, n-1 .. 2]`

so that the algorithm works for all `n > 1`

.)

Let's split up the expression into its parts, so we can see and analyse each part more easily

```
main = print answer
where
n = 600851475143
candidates = [n, n-1 .. 2]
divisorsOfN = filter ((== 0) . (n `mod`)) candidates
primeDivisors = filter isPrime divisorsOfN
answer = head primeDivisors
```

Like Daniel, I work with the assumption that arithmetic operations, comparisons etc. are O(1) - although not true, that's a good enough approximation for all remotely reasonable inputs.

So, of the list `candidates`

, the elements from `n`

down to `answer`

have to be generated, `n - answer + 1`

elements, for a total cost of `O(n - answer + 1)`

. For composite `n`

, we have `answer <= n/2`

, then that's Θ(n).

Generating the list of divisors as far as needed is then `Θ(n - answer + 1)`

too.

For the number `d(n)`

of divisors of `n`

, we can use the coarse estimate `d(n) <= 2√n`

.

All divisors `>= answer`

of `n`

have to be checked for primality, that's at least half of all divisors.
Since the list of divisors is lazily generated, the complexity of

```
isPrime :: Integer -> Bool
isPrime p = (divisors p) == [1, p]
```

is O(smallest prime factor of p), because as soon as the first divisor `> 1`

is found, the equality test is determined. For composite `p`

, the smallest prime factor is `<= √p`

.

We have `< 2√n`

primality checks of complexity at worst O(√n), and one check of complexity `Θ(answer)`

, so the combined work of all prime tests carried out is O(n).

Summing up, the total work needed is `O(n)`

, since the cost of each step is `O(n)`

at worst.

In fact, the total work done in this algorithm is `Θ(n)`

. If `n`

is prime, generating the list of divisors as far as needed is done in O(1), but the prime test is `Θ(n)`

. If `n`

is composite, `answer <= n/2`

, and generating the list of divisors as far as needed is `Θ(n)`

.

If we don't consider the arithmetic operations to be O(1), we have to multiply with the complexity of an arithmetic operation on numbers the size of `n`

, that is `O(log n)`

bits, which, depending on the algorithms used, usually gives a factor slightly above `log n`

and below `(log n)^2`

.