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 :
Step 2) Compute the minimum array size that would guarantee the existence of the solution:
N_LIMIT = log_base_GRf(MAX_VAL) :
Step 3.1) if N > N_LIMIT : return
Step 3.2) else sort and use direct method
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