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I have a set of variables S, and a boolean function f defined on S as follows:

f(x1, x2, ... xn) = True iff f(xi, xj) = True ∀ 1 ≤ i ≤ n ∀ 1 ≤ j ≤ n, n > 1, else False.

f(a, b) is known and f(a, a) is True ∀ a, b in S.

I would appreciate some help in designing a fast algorithm that can return all subsets of S upon which f returns True.

As an example, let S = [a, b, c] and f(a, b) = f(b, c) = f(a, c) = True. The algorithm should then return [[a, b], [a, c], [b, c], [a, b, c]].

I have thought of four strategies to improve on brute force search:

1) The order of parameters of f doesn't matter.

2) Use the fact that f(a, a) is True and f(xi, xj) = f(xj, xi) so only i < j needs checking.

2) Use the fact that f(x1, x2, ... xn+1) = f(x1, x2, ... xn) ∧ (f(xi, xn+1) ∀ 1 ≤ i ≤ n) where ∀ denotes iterated conjunction.

3) note that 2) implies that if f(x1, x2, ... xn) returns False, then f(x1, x2, ... xn) also does, potentially reducing the solution space.

4) Returning False as soon as soon as f(xi, xj) is false for some i, j.

If you want to write some code, I would appreciate it if you could give it in python.

Many thanks.

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f(x1, x2, ... xn) = f(xi, xj) for all i, j. This means that all the values f(x1, x1), f(x1, x2), ..., f(x2, x1), ... are equal, right? –  Vlad Jul 4 '12 at 17:27
The for all can be thought of as iterated conjunction; it means return f(x1, x1) and f(x1, x2) and f(x2, x1) and ... where and denotes logical and. This basically means return True iff they are all True, else False. –  user1502040 Jul 4 '12 at 17:28
Then could you fix your notation to say what you mean? This is really confusing. –  Thomas Jul 4 '12 at 17:29
Just out of curiosity, have you implemented anything (in python) already? If so, can you add it? –  KurzedMetal Jul 4 '12 at 17:35

1 Answer 1

The two-argument function f(a, b) can be seen as a symmetric, reflexive relation on S, which can be seen as an undirected graph.

Viewed that way, f(x1, ..., xn) is true iff {x1, ..., xn} forms a complete subgraph.

From there, you end up at the clique problem which, unfortunately, turns out to be NP-complete. In other words, a fast algorithm is unlikely to exist.

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Thank you very much Thomas; well spotted. I suppose it's back to the drawing board. –  user1502040 Jul 4 '12 at 18:08

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