
Edit: The answer below applies to a version of this problem in which you only want one triplet that adds up like that. When you want all of them, since there are potentially at least O(n^2) possible outputs (as pointed out by ex0du5), and even O(n^3) in pathological cases of repeated elements, you're not going to beat the simple O(n^2) algorithm based on hashing (mapping from a value to the list of indices with that value).
This is basically the 3SUM problem. Without potentially unboundedly large elements, the best known algorithms are approximately O(n^2) , but we've only proved that it can't be faster than O(n lg n) for most models of computation.
If the integer elements lie in the range [u, v] , you can do a slightly different version of this in O(n + (vu) lg (vu)) with an FFT. I'm going to describe a process to transform this problem into that one, solve it there, and then figure out the answer to your problem based on this transformation.
The problem that I know how to solve with FFT is to find a length3 arithmetic sequence in an array: that is, a sequence a , b , c with c  b = b  a , or equivalently, a + c = 2b .
Unfortunately, the last step of the transformation back isn't as fast as I'd like, but I'll talk about that when we get there.
Let's call your original array X , which contains integers x_1, ..., x_n . We want to find indices i , j , k such that x_i + x_j = x_k .
Find the minimum u and maximum v of X in O(n) time. Let u' be min(u, u*2) and v' be max(v, v*2) .
Construct a binary array (bitstring) Z of length v'  u' + 1 ; Z[i] will be true if either X or its double [x_1*2, ..., x_n*2] contains u' + i . This is O(n) to initialize; just walk over each element of X and set the two corresponding elements of Z .
As we're building this array, we can save the indices of any duplicates we find into an auxiliary list Y . Once Z is complete, we just check for 2 * x_i for each x_i in Y . If any are present, we're done; otherwise the duplicates are irrelevant, and we can forget about Y . (The only situation slightly more complicated is if 0 is repeated; then we need three distinct copies of it to get a solution.)
Now, a solution to your problem, i.e. x_i + x_j = x_k , will appear in Z as three evenlyspaced ones, since some simple algebraic manipulations give us 2*x_j  x_k = x_k  2*x_i . Note that the elements on the ends are our special doubled entries (from 2X ) and the one in the middle is a regular entry (from X ).
Consider Z as a representation of a polynomial p , where the coefficient for the term of degree i is Z[i] . If X is [1, 2, 3, 5] , then Z is 1111110001 (because we have 1, 2, 3, 4, 5, 6, and 10); p is then 1 + x + x^{2} + x^{3} + x^{4} + x^{5} + x^{9}.
Now, remember from high school algebra that the coefficient of x^{c} in the product of two polynomials is the sum over all a, b with a + b = c of the first polynomial's coefficient for x^{a} times the second's coefficient for x^{b}. So, if we consider q = p^{2}, the coefficient of x^{2j} (for a j with Z[j] = 1 ) will be the sum over all i of Z[i] * Z[2*j  i] . But since Z is binary, that's exactly the number of triplets i,j,k which are evenlyspaced ones in Z . Note that (j, j, j) is always such a triplet, so we only care about ones with values > 1.
We can then use a Fast Fourier Transform to find p^{2} in O(Z log Z) time, where Z is v'  u' + 1 . We get out another array of coefficients; call it W .
Loop over each x_k in X . (Recall that our desired evenlyspaced ones are all centered on an element of X , not 2*X .) If the corresponding W for twice this element, i.e. W[2*(x_k  u')] , is 1, we know it's not the center of any nontrivial progressions and we can skip it. (As argued before, it should only be a positive integer.)
Otherwise, it might be the center of a progression that we want (so we need to find i and j ). But, unfortunately, it might also be the center of a progression that doesn't have our desired form. So we need to check. Loop over the other elements x_i of X , and check if there's a triple with 2*x_i , x_k , 2*x_j for some j (by checking Z[2*(x_k  x_j)  u'] ). If so, we have an answer; if we make it through all of X without a hit, then the FFT found only spurious answers, and we have to check another element of W .
This last step is therefore O(n * 1 + (number of x_k with W[2*(x_k  u')] > 1 that aren't actually solutions)), which is maybe possibly O(n^2) , which is obviously not okay. There should be a way to avoid generating these spurious answers in the output W ; if we knew that any appropriate W coefficient definitely had an answer, this last step would be O(n) and all would be well.
I think it's possible to use a somewhat different polynomial to do this, but I haven't gotten it to actually work. I'll think about it some more....
Partially based on this answer.


answered Apr 24 '12 at 18:51

