Your current solution is `O(n^2)`

, because `filter`

traverses the list once *for each* of the elements in the original list. It's possible to write an `O(n)`

solution using a helper data structure with constant time insertion and membership operations to keep track of the elements that have been found already.

In Racket, we have an out-of-the-box `set`

data structure which, for *constant time operations*, "actually requires O(log N) time for a set of size N" (see the documentation), therefore the `set-member?`

and `set-add`

procedures will be `O(log n)`

. So this implementation using Racket's `set`

is not optimal, but we achieve the `O(n log n)`

target:

```
(define (re-dup lst)
(let loop ((seen (set))
(lst lst)
(acc '()))
(cond ((null? lst)
(reverse acc))
((set-member? seen (car lst))
(loop seen (cdr lst) acc))
(else
(loop (set-add seen (car lst))
(cdr lst)
(cons (car lst) acc))))))
```

It works as expected, preserving the original order in the list (which is a constraint for this problem, as stated in the comments) at the cost of one additional `O(n)`

`reverse`

operation:

```
(re-dup '(4 6 1 1 2 3 3 5 6))
=> '(4 6 1 2 3 5)
```

`filter`

procedure). It works correctly, but it's an`O(n^2)`

solution – Óscar López Jul 2 '13 at 18:55`O(n)`

solution – Óscar López Jul 2 '13 at 19:08