# Recursive bottom-up traversal of algebraic data types

When dealing with sizeable algebraic data types in Haskell, there is a particular recursive traversal not captured by folding over the data type. For instance, suppose I have a simple data type representing formulas in propositional logic, and a fold defined over it:

``````type FAlgebra α φ =
(φ, φ,                -- False, True
α -> φ,              -- Atom
φ -> φ,              -- Negation
φ -> φ -> φ,         -- Conjunction
φ -> φ -> φ,         -- Disjunction
φ -> φ -> φ,         -- Implication
φ -> φ -> φ)         -- Bi-implication

fold :: FAlgebra α φ -> Form α -> φ
fold (f,t,lit,not,con,dis,imp,iff) = fold' where
fold' (Fls)     = f
fold' (Tru)     = t
fold' (Lit α)   = lit α
fold' (Not φ)   = not (fold' φ)
fold' (Con φ ψ) = con (fold' φ) (fold' ψ)
fold' (Dis φ ψ) = dis (fold' φ) (fold' ψ)
fold' (Imp φ ψ) = imp (fold' φ) (fold' ψ)
fold' (Iff φ ψ) = iff (fold' φ) (fold' ψ)
``````

This recursion scheme provides a succinct answer to recursions like evaluation or finding literals:

``````eval :: (Ord α) => Map α Bool -> Form α -> Bool
eval v = fold (False, True, (fromJust . flip M.lookup v),
not, (&&), (||), ((||) . not), (==))

literals :: (Ord α) => Form α -> Set α
literals = fold (S.empty, S.empty, S.singleton, id,
S.union, S.union, S.union, S.union)
``````

However, it doesn't fare so well when I wish to "sweep" the data type. In the following, simp is an auxiliary function defined by necessary pattern-matching:

``````simplify :: Form α -> Form α
simplify (Not φ)   = simp (Not (simplify φ))
simplify (Con φ ψ) = simp (Con (simplify φ) (simplify ψ))
simplify (Dis φ ψ) = simp (Dis (simplify φ) (simplify ψ))
simplify (Imp φ ψ) = simp (Imp (simplify φ) (simplify ψ))
simplify (Iff φ ψ) = simp (Imp (simplify φ) (simplify ψ))
simplify φ         = φ
``````

Using a fold to define simplify, of course, generates incorrect results. For instance, the following is not equivalent:

``````simplify = fold (Fls, Tru, Lit, (simp . Not), con Con, con Dis, con Imp, con Iff)
where con f φ ψ = simp (f φ ψ)
``````

What is the best solution to recursions like simplify? Should I define a generic traversal similar to the fold over the data type, or is there a standard recursion pattern for defining such functions?

-

Did you try Uniplate? For operations that only work on a single type it can perform bottom-up rewrites and rewrites until a fixed point.

For example:

``````import Data.Generics.Uniplate.Direct
import qualified Data.Map as M

data Form a = Fls | Tru | Lit a
| Not (Form a)
| Con (Form a) (Form a)
| Dis (Form a) (Form a)
-- etc.
deriving (Show, Eq)

instance Uniplate (Form a) where
uniplate (Not f) = plate Not |* f
uniplate (Con f1 f2) = plate Con |* f1 |* f2
uniplate (Dis f1 f2) = plate Dis |* f1 |* f2
-- one case for each constructor that may contain nested (Form a)s
uniplate x = plate x

simplify :: Form a -> Form a
simplify = transform simp
where
simp (Not (Not f)) = f
simp (Not Fls) = Tru
simp (Not Tru) = Fls
simp x = x

test =
simplify (Not (Not (Not (Not (Lit "a"))))) == Lit "a"
``````

The relevant functions for you are `transform` and `rewrite`.

For a more in-depth documentation about Uniplate there's also a paper (PDF).

-
Just in case, please, add the link to the paper. –  Yasir Arsanukaev Feb 5 '11 at 13:50
@Yasir: Added. I found a working non-paywall link. –  nominolo Feb 5 '11 at 14:09
You could just add the link as a comment, in case you change your mind and update the question with more useful data later (possibly adding the link). This way you won't get your answer get CWed. :-) –  Yasir Arsanukaev Feb 5 '11 at 14:20
The Uniplate library is exactly what I was looking for. Thanks for highlighting `transform` and `rewrite` as well. It's more accessable than other SYB libraries for this kind of task because the library deals with rewriting, specifically. –  danportin Feb 5 '11 at 20:59