# Extending LINQ-based Specification Pattern to implement subsumption

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?

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

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".

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+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