There's no completely standard class that does this, but it's pretty easy to make one yourself. I'll sketch one way of doing this:
data P = A | B Q deriving Show
data Q = C | D R | E deriving Show
data R = F | G deriving Show
class Finite a where
allValues :: [a]
instance Finite P where
allValues = [A] ++ map B allValues
instance Finite Q where
allValues = [C] ++ map D allValues ++ [E]
instance Finite R where
allValues = [F] ++ [G]
I've written the instances this way to show that it's very easy and mechanical and could be done by a program (e.g. with generic programming or with Template Haskell). You could also add an instance to do some legwork for you, provided the type is
instance (Bounded a, Enum a) => Finite a where
allValues = [minBound..maxBound]
If you now add
deriving (Bounded, Show) to
R, that's one less instance to write!
Anyway, now we can evaluate
allValues :: [P] and get back
[A,B C,B (D F),B (D G),B E] - which you can then
[0..] to get your encoding and so on.
But surely this has been done before! I'm not using serialization much (if ever), but a quick search shows that the binary package and the binary-derive package can do something similar for you, without having to write the instances yourself. I would see if those do what you want first.