It turns out that you can do this with a vanilla regular expression. It's just not pretty.

`^((cc|bb)*((bc|cb)(bb|cc)*(bc|cb))*)*(b|c((cc|bb)*((bc|cb)(bb|cc)*(bc|cb))*)*b((cc|bb)*((bc|cb)(bb|cc)*(bc|cb))*)*c)((cc|bb)*((bc|cb)(bb|cc)*(bc|cb))*)*$`

To understand the regular expression, draw a DFA with four states arranged in a square, linked forwards and backwards around the perimeter of the square. The horizontal links represent consuming a B, while the vertical links represent consuming a C. At the top left is the start state, representing having an even number of Cs and an even number of Bs. The top right is the accept state, reached by consuming a B. The bottom states are reached from the top states (and visa-versa) by consuming a C. Now, we can make any number of transitions that preserve the parity of our Cs and Bs, and we'll end up back at the start state. Then we consume a B, bringing us to our accept state. Then from there, so long as we maintain the parities, we're good. Two Cs maintain parity, as do two Bs. That's the `(cc|bb)*`

bit.

But you can also maintain parity by going to the opposite corner (via a C and a B in either order), doing as many BB/CC as you like, then returning to the corner you were in (again, either way). That's this bit: `((bc|cb)(bb|cc)*(bc|cb))*`

So, we have `((cc|bb)*((bc|cb)(bb|cc)*(bc|cb))*)*`

, being a set of transitions that gets us back where we started (call it a noop). You can make your odd B transition on either the top, in which case `b`

will do, or the bottom, in which case you need to get down to the bottom with a `c`

, do another noop, then have your `b`

, then another noop, then the `c`

back to the top.

I should mention that you can always take two regular expressions and generate a regular expression that matches only strings matched by both of the expressions.

`\b(?=[^A]*A([^A]*A[^A]A)[^A])([^C](C[^C]C[^C])*[^C]*)\b`

is missing several stars and one \b, it must read`\b(?=[^A]*A([^A]*A[^A]*A)*[^A]\b)([^C]*(C[^C]*C[^C]*)*[^C]*)\b`

– maaartinus Jan 20 '11 at 22:13