In the book "*The Haskell Road to Logic, Maths and Programming*", the authors present two alternative ways of finding the least divisor `k`

of a number `n`

with `k > 1`

, claiming that the second version is much faster than the first one. I have problems understanding why (I am a beginnner).

Here is the first version (page 10):

```
ld :: Integer -> Integer -- finds the smallest divisor of n which is > 1
ld n = ldf 2 n
ldf :: Integer -> Integer -> Integer
ldf k n | n `rem` k == 0 = k
| k ^ 2 > n = n
| otherwise = ldf (k + 1) n
```

If I understand this correctly, the `ld`

function basically ends up iterating through all integers in the interval `[2..sqrt(n)]`

and stops as soon as one of them divides `n`

, returning it as the result.

The second version, which the authors claim to be much faster, goes like this (page 23):

```
ldp :: Integer -> Integer -- finds the smallest divisor of n which is > 1
ldp n = ldpf allPrimes n
ldpf :: [Integer] -> Integer -> Integer
ldpf (p:ps) n | rem n p == 0 = p
| p ^ 2 > n = n
| otherwise = ldpf ps n
allPrimes :: [Integer]
allPrimes = 2 : filter isPrime [3..]
isPrime :: Integer -> Bool
isPrime n | n < 1 = error "Not a positive integer"
| n == 1 = False
| otherwise = ldp n == n
```

The authors claim that this version is faster because it iterates only through the list of *primes* within the interval `2..sqrt(n)`

, instead of iterating through all numbers in that range.

However, this argument doesn't convince me: the recursive function `ldpf`

is eating one by one the numbers from the list of primes `allPrimes`

. This list is generated by doing `filter`

on the list of all integers.

So unless I am missing something, this second version ends up iterating through all numbers within the interval `2..sqrt(n)`

too, but for each number it first checks whether it is prime (a relatively expensive operation), and if so, it checks whether it divides `n`

(a relatively cheap one).

I would say that just checking whether `k`

divides `n`

for each `k`

should be faster. Where is the flaw in my reasoning?

`primes`

is a constant applicative form (CAF) and will be memoised. In fact the`primes`

list isn't the fastest algorithm, but at least it avoids the usual "unfaithful" seive of Eratosthenes multiple-removals problem. Read The Genuine Sieve of Eratosthenes if you want to find primes faster. – AndrewC Feb 23 '14 at 18:04`n*n`

rather than`n^2`

, since I don't trust the compiler to do that for me. – augustss Feb 23 '14 at 22:01