do numbers in an array contain sides of a valid triange

Check if an array of `n` integers contains 3 numbers which can form a triangle (i.e. the sum of any of the two numbers is bigger than the third).

Apparently, this can be done in `O(n)` time.

(the obvious `O(n log n)` solution is to sort the array so please don't)

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Couldn't you loop through once, storing the two smallest and one largest integers. Then compare in O(n)? –  Joe Oct 14 '11 at 3:03
Just to clarify, you're supposed only to check if the numbers exist, not to print the numbers? –  Michał Bentkowski Oct 14 '11 at 11:49
@IAbstractDownvoteFactory 1, 2, 3, 10, 10, 10 smallest are not necessarily the solution –  MK. Oct 14 '11 at 12:50
@MichałBentkowski I do not know. –  MK. Oct 14 '11 at 12:51
I don't believe that it can be solved. For example, given the set 1,2,7,10,13,100,114 (not necessarily sorted, of course), how can one find detect the existence of a solution in a single pass? I would really be excited to see! –  Lior Kogan Oct 14 '11 at 20:21

It's difficult to imagine N numbers (where N is moderately large) so that there is no triangle triplet. But we'll try:

Consider a growing sequence, where each next value is at the limit `N[i] = N[i-1] + N[i-2]`. It's nothing else than Fibonacci sequence. Approximately, it can be seen as a geometric progression with the factor of golden ratio (GRf ~= 1.618).
It can be seen that if the `N_largest < N_smallest * (GRf**(N-1))` then there sure will be a triangle triplet. This definition is quite fuzzy because of floating point versus integer and because of GRf, that is a limit and not an actual geometric factor. Anyway, carefully implemented it will give an O(n) test that can check if the there is sure a triplet. If not, then we have to perform some other tests (still thinking).

EDIT: A direct conclusion from fibonacci idea is that for integer input (as specified in Q) there will exist a garanteed solution for any possible input if the size of array will be larger than `log_GRf(MAX_INT)`, and this is 47 for 32 bits or 93 for 64 bits. Actually, we can use the largest value from the input array to define it better.

This gives us a following algorithm:

Step 1) Find MAX_VAL from input data :`O(n)`

Step 2) Compute the minimum array size that would guarantee the existence of the solution:
`N_LIMIT = log_base_GRf(MAX_VAL)` : `O(1)`

Step 3.1) if N > N_LIMIT : return `true` : `O(1)`

Step 3.2) else sort and use direct method `O(n*log(n))`

Because for large values of N (and it's the only case when the complexity matters) it is `O(n)` (or even `O(1)` in cases when `N > log_base_GRf(MAX_INT)`), we can say it's `O(n)`.

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The fibonacci thought is definitely interesting but I don't think I you have a real solution here... –  MK. Oct 14 '11 at 17:00
I'm not excited about having to say that O(n*log(n)) for small n is ok because it relies on the fact that we are only dealing with integers (64bit floats can get big), but I think this is pretty much the best you can do. –  MK. Oct 15 '11 at 2:58