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 + (v-u) lg (v-u)) 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 length-3 arithmetic sequence in an array: that is, a sequence
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
k such that
x_i + x_j = x_k.
Find the minimum
u and maximum
O(n) time. Let
min(u, u*2) and
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
As we're building this array, we can save the indices of any duplicates we find into an auxiliary list
Z is complete, we just check for
2 * x_i for each
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 evenly-spaced 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
Z as a representation of a polynomial
p, where the coefficient for the term of degree
[1, 2, 3, 5], then
1111110001 (because we have 1, 2, 3, 4, 5, 6, and 10);
p is then 1 + x + x2 + x3 + x4 + x5 + x9.
Now, remember from high school algebra that the coefficient of xc in the product of two polynomials is the sum over all a, b with a + b = c of the first polynomial's coefficient for xa times the second's coefficient for xb. So, if we consider q = p2, the coefficient of x2j (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 evenly-spaced 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 p2 in
O(|Z| log |Z|) time, where
v' - u' + 1. We get out another array of coefficients; call it
Loop over each
X. (Recall that our desired evenly-spaced ones are all centered on an element of
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
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, and check if there's a triple with
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
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.