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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
1  
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

1 Answer 1

up vote 3 down vote accepted

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

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