Today at school the teacher asked us to implement a duplicate-deletion algorithm. It's not that difficult, and everyone came up with the following solution (pseudocode):

```
for i from 1 to n - 1
for j from i + 1 to n
if v[i] == v[j] then remove(v, v[j]) // remove(from, what)
next j
next i
```

The computational complexity for this algo is `n(n-1)/2`

. (We're in high school, and we haven't talked about big-O, but it seems to be `O(n^2)`

). This solution appears ugly and, of course, slow, so I tried to code something faster:

```
procedure binarySearch(vector, element, *position)
// this procedure searches for element in vector, returning
// true if found, false otherwise. *position will contain the
// element's place (where it is or where it should be)
end procedure
----
// same type as v
vS = new array[n]
for i from 1 to n - 1
if binarySearch(vS, v[i], &p) = true then
remove(v, v[i])
else
add(vS, v[i], p) // adds v[i] in position p of array vS
end if
next i
```

This way `vS`

will contain all the elements we've already passed. If element `v[i]`

is in this array, then it is a duplicate and is removed. The computational complexity for the binary search is `log(n)`

and for the main loop (second snippet) is `n`

. Therefore the whole CC is `n*log(n)`

if I'm not mistaken.

Then I had another idea about using a binary tree, but I can't put it down.

Basically my questions are:

- Is my CC calculation right? (and, if not, why?)
- Is there a faster method for this?

Thanks

`vS`

, and what does`add`

do exactly? – Robin Green May 20 '11 at 12:42