I would say your best bet is to just check the disabled patterns first, and then only check the enable patterns if the disabled patterns all returned false.

**Edit:**

Ok... I just worked through this with some one in the office...

It turns out there is a N^4 algorithm that you can use to do this.

Basically, you need to:

- Convert both regexes into a NFAs
- Convert the NFAs into DFAs
- Compare the DFAs to see if one is a subset of the other

To compare the DFAs you need to do a parallel depth first search of both graphs, starting at the start node, and following the inputs. Each time you follow an input in each graph you build a composite node (n1, n2) with n1 being the node from the first graph and n2 being the node from the second graph.

If either node is an accepting state, mark it with a *, so that you would have (n1*,n2) (n1, n2*), (n1*,n2*), or (n1,n2).

Once you are done, look at all the edges where n1 is an accepting state (n1*, x). if X is also an accepting state, then regex1 is a subset of regex2.

This algorithm should be at worst case O(n^4). It might be better, but it won't be worse than that.

I'll see about posting some code in a bit.

Obviously, however, you would only want to do this if the volume of changing regexes was significantly lower than the volume of incoming things you were checking. Otherwise the expense in canceling out the regexes would cancel out any perf benefits from having fewever regexes.

**Edit 2:**

My analysis of O(n^4) run time was based on the number of states in the larger DFA. This, however, neglected the fact that the number of states in the DFA, after conversion from an NFA, can end up being 2^M, where M is the number of states in the NFA.

This means that the actual complexity ends up being something like:

O(2^4M)

Which is non polynomial (which is bad).

Most of the time, the number of NFA states won't get anywhere near that high, so it shouldn't be too slow in practice.

However, I would **highly** recommend running anything like this as an offline process, not as an online one.

**Edit 3:**

It is possible to convert a regular expression directly into a DFA. However, I can't find the description of the algorithm online, every one just points to the implementation in the dragon book. Unfortunately, I don't have a copy of it right now (this is shameful, I know). So for now I'm just going to go ahead with the regex=>nfa=>dfa approach. After I find a library, get the book, and grab the algorithm out of it, I'll look into modifying the code to use the direct approach.