hash all elements in `A`

[iterate the array and insert the elements into a hash-set], then iterate B, and check for each element if it is in `B`

or not. you can get average run time of `O(|A|+|B|)`

.

You cannot get sub-linear complexity, so this solution is **optimal for average case analyzis**, however, since hashing is **not** `O(1)`

*worst case*, you might get bad worst-case performance.

**EDIT:**

If you don't have enough space to store a hash set of elements in B, you might want to concider a probabilistic solution using bloom filters. The problem: there might be some false positives [but never false negative]. Accuracy of being correct increases as you allocate more space for the bloom filter.

The other solution is as you said, sort, which will be `O(nlogn)`

time, and then use binary search for all elements in B on the sorted array.

For 3rd stage, you get same complexity: `O(nlogn)`

with the same solution, it will take approximately double time then stage 2, but still `O(nlogn)`

**EDIT2:**

Note that instead of using a regular hash, sometimes you can use a trie [depands on your elements type], for example: for ints, store the number as it was a string, each digit will be like a character. with this solution, you get `O(|B|*num_digits+|A|*num_digits)`

solution, where `num_digits`

is the number of digits in your numbers [if they are ints]. Assuming `num_digits`

is bounded with a finite size, you get `O(|A|+|B|)`

**worst case**.