Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

There are a lot of LINQ-based implementations of the Composite Specification Pattern. I have not seen one that used Subsumption.

Are there any such examples that have been documented (blogs, etc.) or published as open source? I have an idea and proof of concept for how this could work by having an ExpressionVisitor translate every specification into a canonical logical form (CNF/DNF), but I am concerned that this is overly complicated. Is there a better way?

share|improve this question
    
Did you mean conditional where clause in Linq ? –  Frank Myat Thu Dec 10 '12 at 6:52

1 Answer 1

up vote 2 down vote accepted
+50

I am concerned that this is overly complicated. Is there a better way?

The short answer is "No, there isn't" 1

The long answer: The "overly complicated" captures the essence of the problem: it is NP-hard. Here is a short informal proof relying upon the fact that the satisfiability problem is NP-complete:

  • Suppose that you have two Boolean formulas, A and B
  • You need to test if A implies B, or equivalently ¬A | B for all assignments of variables upon which A and B depend. In other words, you need a proof that F = ¬A | B is a tautology.
  • Suppose that the tautology test can be performed in polynomial time
  • Consider ¬F, the inverse of F. F is satisfiable if and only if ¬F is not a tautology
  • Use the hypothetical polynomial algorithm to test ¬F for being a tautology
  • The answer to "is F satisfiable" is the inverse of the answer to "is ¬F a tautology"
  • Therefore, an existence of a polynomial tautology checker would imply that the satisfiability problem is in P, and that P=NP.

Of course the fact that the problem is NP-hard does not mean that there would be no solutions for practical cases: in fact, your approach with the conversion to a canonical form may produce OK results in many real-world situations. However, an absence of a known "good" algorithm often discourages active development of practical solutions2.


1 With the obligatory "unless P=NP" disclaimer.

2 Unless a "reasonably good" solution would do, which may very well be the case for your problem, if you allow for "false negatives".

share|improve this answer
    
+1, Question: are you using tautology in the formal logic sense of the word or is there a similar but differently qualified definition in CS? Its my understanding that a proposition is tautologous iff it can be derived from the empty set of SC sentences. This would not adequately describe what I am trying to prove, because I have an extensive knowledge-base/database to derive from as well. On another note, the problem is difficult, but has been solved efficiently before.. Right now, I'm looking into Prolog, Euler and Microsoft Solver Foundation. –  smartcaveman Dec 13 '12 at 4:22
    
@smartcaveman I am using tautology in the formal logic sense of the word: to prove that expression A subsumes B, you need to show that A => B is always true, i.e. can be derived from the empty set of premises. The only reason I mentioned it was to get to the satisfiability problem, which is known to be NP-complete. Note that only A => B must be a tautology; the individual expressions A and B can be, and in all non-trivial cases, will be, based on non-empty sets of premises. The bigger that set is, the harder is to prove the subsumption of B by A. –  dasblinkenlight Dec 13 '12 at 4:43
    
so I had another idea as to how to address this more practically - still working it out. Instead of a pure rewriting, I could create a square-of-opposition model for each predicate and require that all my predicates are in syllogistic form. This seems like it might mitigate the complexity, b/c the content would be normalized rather than the formal representation - since my domain is a business application, I think it could be expressive enough. Any thoughts? –  smartcaveman Dec 14 '12 at 11:39
    
@smartcaveman Changing the representation would not change the fundamental hardness of the problem. Even if you normalize everything to 3-CNF, you're still in the NP space. Essentially, you are building a first-order theorem prover - it's not easy, unless you significantly restrict your predicates. Allowing false negatives in a few corner cases could be another tradeoff, if your application can tolerate it. –  dasblinkenlight Dec 14 '12 at 15:29
    
can you elaborate more about what you had in mind re: allowing false negatives for corner cases, or link me to somewhere that discusses this variation? –  smartcaveman Dec 28 '12 at 14:23

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.