Alright here we go...apologies to anyone expecting a faster solution. It turns out my teacher was having a little fun with me and I completely missed the point of what he was saying.

I should begin by clarifying what I meant by:

he hinted that there was an even *faster* way of doing it

The gist of our conversation was this: he said that my XOR approach was interesting, and we talked for a while about how I arrived at my solution. He asked me whether I thought my solution was optimal. I said I did (for the reasons I mentioned in my question). Then he asked me, "Are you *sure*?" with a look on his face I can only describe as "smug". I was hesitant but said yeah. He asked me if I could think of a better way to do it. I was pretty much like, "You mean there's a faster way?" but instead of giving me a straight answer he told me to think about it. I said I would.

So I thought about it, sure that my teacher knew something I didn't. And after not coming up with anything for a day, I came here.

What my teacher actually wanted me to do was **defend** my solution as being optimal, *not* try to find a better solution. As he put it: creating a nice algorithm is the easy part, the hard part is proving it works (and that it's the best). He thought it was quite funny that I spent so much time in Find-A-Better-Way Land instead of working out a simple proof of O(n) that would have taken considerably less time (we ended up doing so, see below if you're interested).

So I guess, big lesson learned here. I'll be accepting Shashank Gupta's answer because I think that it *does* manage to answer the original question, even though the question was flawed.

I'll leave you guys with a neat little Python one-liner I found while typing the proof. It's not any more efficient but I like it:

```
def getUniqueElement(a, b):
return reduce(lambda x, y: x^y, a + b)
```

## A Very Informal "Proof"

Let's start with the original two arrays from the question, `a`

and `b`

:

```
int[] a = {6, 5, 6, 3, 4, 2};
int[] b = {5, 7, 6, 6, 2, 3, 4};
```

We'll say here that the shorter array has length `n`

, then the longer array must have length `n + 1`

. The first step to proving linear complexity is to append the arrays together into a third array (we'll call it `c`

):

```
int[] c = {6, 5, 6, 3, 4, 2, 5, 7, 6, 6, 2, 3, 4};
```

which has length `2n + 1`

. Why do this? Well, now we have another problem entirely: finding the element that occurs an odd number of times in `c`

(from here on "odd number of times" and "unique" are taken to mean the same thing). This is actually a pretty popular interview question and is apparently where my teacher got the idea for his problem, so now my question has some practical significance. Hooray!

Let's assume there *is* an algorithm faster than O(n), such as O(log n). What this means is that it will only access *some* of the elements of `c`

. For example, an O(log n) algorithm might only have to check log(13) ~ 4 of the elements in our example array to determine the unique element. Our question is, is this possible?

First let's see if we can get away with removing *any* of the elements (by "removing" I mean not having to access it). How about if we remove 2 elements, so that our algorithm only checks a subarray of `c`

with length `2n - 1`

? This is still linear complexity, but if we can do that then maybe we can improve upon it even further.

So, let's choose two elements of `c`

completely at random to remove. There are actually several things that could happen here, which I'll summarize into cases:

```
// Case 1: Remove two identical elements
{6, 5, 6, 3, 4, 2, 5, 7, 2, 3, 4};
// Case 2: Remove the unique element and one other element
{6, 6, 3, 4, 2, 5, 6, 6, 2, 3, 4};
// Case 3: Remove two different elements, neither of which are unique
{6, 5, 6, 4, 2, 5, 7, 6, 6, 3, 4};
```

What does our array now look like? In the first case, 7 is still the unique element. In the second case there is a *new* unique element, 5. And in the third case there are now 3 unique elements...yeah it's a total mess there.

Now our question becomes: can we determine the unique element of `c`

just by looking at this subarray? In the first case we see that 7 is the unique element of the subarray, but we can't be sure it is also the unique element of `c`

; the two removed elements could have just as well been 7 and 1. A similar argument applies for the second case. In case 3, with 3 unique elements we have no way of telling which two are non-unique in `c`

.

It becomes clear that even with `2n - 1`

accesses, there is just not enough information to solve the problem. And so the optimal solution is a linear one.

Of course, a real proof would use induction and not use proof-by-example, but I'll leave that to someone else :)

`m = n + 1`

then`O(n+m) --> O(2n+1) --> O(n)`

. Since`n`

is the input length in Big-O notation, algorithms cannot have a complexity less than`O(n)`

unless they have some pre-conditioned input or data structure to work with. On the other hand, it may well be possible to optimize or improve on thecode-efficiency, though I think that your approach is probably near-optimal. – RBarryYoung Oct 6 '13 at 16:48