# What's the fastest way to calculate the set of all satisfied boolean functions?

Given a set of bool funcs D1,.., Dk each of whose input arguments are some subset of X1...Xm, how do I quickly find which of the D's are satisfied? Would a generalized automata work nicely in case some D's have common expressions in the X's?

Or.. some type of graph algorithm.

Or.. am I taking the wrong approach. Internally X1...Xm represent some languages that an input W either was in dj(W, Xj) = 0 or was some constant away from being in dj(W, Xj) <= maxj. The D's themselves are languages which are and's & or's of the X's. The difference between the D's and the X's is that the X's are languages of some component of a struct Obs { a, b, c, ..}. So X1 is a language of possible values for one and only one member of Obs, say a. Xj could be another language of possible values for member a. Would it be beneficial to make sure that if Xi & Xj are languages of Obs.a, then Xi (set intersect) Xj = null or i = j, iow the languages of a are pw disjoint? This might help make an automaton algorithm for finding the D's deterministic.

More info. So as you've seen an input W is a particular value of an instance of the Obs struct, and W's membership in the described languages is fuzzily measured. Knowing that I'm definitely, have no choice, doing this fuzzy matching thing, is there a neat way to statistically find the collection of D's that were matched.

As you can see, not a well-defined question. But if anything sparks and you have time to mention something, please do.

Ty

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tl;dr. However, for your first question, if you suspect there will be many recurring sub-expressions, I would go with dynamic programming - start by "solving" the Xj's, then anything you can solve from there (!Xj, Xj&Xk, etc.). Keep doing this until all Di's are solved. Of course, don't solve "just any" boolean expression, but only the ones that are sub-expressions of D1..Dk. Use some hashing mechanism to know what you've already solved and what you still need to solve. As a further improvement, make sure X&Y is treated the same as Y&X (so you don't recalculate it), and the same goes for OR. –  Eran Zimmerman Oct 13 '12 at 17:37
Thanks. Dynamic programming, definitely. I've also thought of: for OR, D1 or D2 or ...or Dk, move Di's with the highest success rate (# of successes per unit time) up front, and for AND, D1 and D2 ... and Dk, move the ones with the highest failure rate up front. This is usually called short-circuit evaluation. –  Enjoys Math Oct 14 '12 at 19:33