If you are given an arbitrary binary tree, in the worst case you have to inspect all the nodes to determine whether they have the same value. There's a simple adversarial argument you can use here - if your algorithm doesn't look at all values, since there's no relation between any distinct values in the tree, an adversary could feed you a tree where n - 1 values are all the same. If you didn't then look at the last value, the adversary could force your algorithm to be wrong by setting that value to the opposite of what your algorithm says.

On the other hand, if you're talking about a binary *search* tree, then you can solve this in time O(h), where h is the height of the tree. Specifically, just look at the first and last values and see if they're the same. If so, all intermediary values in the tree must be the same. If they aren't, then you've witnessed two distinct values. This will run in time O(log n) on a perfectly balanced tree and O(n) on a degenerate linked list. I suspect this might have been what the original question was asking, since it's a more interesting question than the general binary tree case (at least, in my opinion).

Hope this helps!