If you want the fastest* answer:

- Sort one array--time is N log N.
- For each element in the second array, search the first. If you find it, add 1 to a companion array; otherwise add 0--time is N log N, using N space.
- For each non-zero count, copy the corresponding entry into the temporary array, compacting it so it's still sorted--time is N.
- For each element in the third array, search the temporary array; when you find a hit, stop. Time is less than N log N.

Here's code in Scala that illustrates this:

```
import java.util.Arrays
val a = Array(1,5,2,3,14,1,7)
val b = Array(3,9,14,4,2,2,4)
val c = Array(1,9,11,6,8,3,1)
Arrays.sort(a)
val count = new Array[Int](a.length)
for (i <- 0 until b.length) {
val j =Arrays.binarySearch(a,b(i))
if (j >= 0) count(j) += 1
}
var n = 0
for (i <- 0 until count.length) if (count(i)>0) { count(n) = a(i); n+= 1 }
for (i <- 0 until c.length) {
if (Arrays.binarySearch(count,0,n,c(i))>=0) println(c(i))
}
```

With slightly more complexity, you can either use no extra space at the cost of being even more destructive of your original arrays, or you can avoid touching your original arrays at all at the cost of another N space.

Edit: * as the comments have pointed out, hash tables are faster for non-perverse inputs. This is "fastest worst case". The worst case may not be so unlikely unless you use a really good hashing algorithm, which may well eat up more time than your sort. For example, if you multiply all your values by 2^16, the trivial hashing (i.e. just use the bitmasked integer as an index) will collide every time on lists shorter than 64k....

`A = {1, 1, 1, 1, 1}; B = {2, 3, 4, 5, 1}; C = {2, 2, 2, 2, 1};`

? – IVlad Mar 10 '10 at 16:08IN ALL 3. It doesn't say anything about an element not being able to appear in just two of the three arrays or about an element not being able to appear 199 times in a single array. But anyway, my solution ignores that and just takes your "NO" answer into consideration. Good luck in the interview. – IVlad Mar 10 '10 at 16:45