A lot of this is going to depend on what type of data you have. You mention sorting, so I take it the elements are comparable. With sets of size `m`

and `n`

, this will take `O(m lg m + n lg n)`

to sort, and that will dominate. (Asymptotically, it won't matter if you do binary search or walk both lists. Walking both lists should be `O( m + n)`

.) Of course, if you are using data with a better sort algorithm available, such as integers with radix-sort, you should be able to get down to `O( m + n)`

.

Using sets (as others are suggesting) implicitly suggests using hashing, which will definitely make your problem easier. If you hash all the elements in A ( `O(m)`

) and store all the hashes in a hash set in memory, then hash B ( `O(n)`

) and detect where collisions may occur in the hash set. This becomes a matter for optimization: you have to evaluate a classic speed-memory trade-off. The larger your hash set, the quicker the collision-checks will be. This will run in `O( m + n )`

.

It's worth noting that you can prove that any algorithm that does what you ask will run in at least `m + n`

time, since all the inputs need to be looked at.