So, this is a common interview question. There's already a topic up, which I have read, but it's dead, and no answer was ever accepted. On top of that, my interests lie in a slightly more constrained form of the question, with a couple practical applications.

Given a two dimensional array such that:

- Elements are unique.
- Elements are sorted along the x-axis and the y-axis.
- Neither sort predominates, so neither sort is a secondary sorting parameter.
- As a result, the diagonal is also sorted.
- All of the sorts can be thought of as moving in the same direction. That is to say that they are all ascending, or that they are all descending.
- Technically, I think as long as you have a >/=/< comparator, any total ordering should work.
- Elements are numeric types, with a single-cycle comparator.
- Thus, memory operations are the dominating factor in a big-O analysis.

How do you find an element? Only worst case analysis matters.

Solutions I am aware of:

A variety of approaches that are:

O(nlog(n)), where you approach each row separately.

O(nlog(n)) with strong best and average performance.

One that is O(n+m):

Start in a non-extreme corner, which we will assume is the bottom right.

Let the target be J. Cur Pos is M.

If M is greater than J, move left.

If M is less than J, move up.

If you can do neither, you are done, and J is not present.

If M is equal to J, you are done.

Originally found elsewhere, most recently stolen from here.

And I believe I've seen one with a worst-case O(n+m) but a optimal case of nearly O(log(n)).

What I am curious about:

Right now, I have proved to my satisfaction that naive partitioning attack always devolves to nlog(n). Partitioning attacks in general appear to have a optimal worst-case of O(n+m), and most do not terminate early in cases of absence. I was also wondering, as a result, if an interpolation probe might not be better than a binary probe, and thus it occurred to me that one might think of this as a set intersection problem with a weak interaction between sets. My mind cast immediately towards Baeza-Yates intersection, but I haven't had time to draft an adaptation of that approach. However, given my suspicions that optimality of a O(N+M) worst case is provable, I thought I'd just go ahead and ask here, to see if anyone could bash together a counter-argument, or pull together a recurrence relation for interpolation search.

greaterthan the max, the target is not present", and compare just K, T in the max? Also, I may be missing something, but isn't`[ 100 200 ; 50 199 ]`

a counter example, if the target is on the left of 100? – lijie Dec 20 '10 at 23:56