I have this simple Expr AST and I can easily convert it to String.

import Prelude hiding (Foldable)
import qualified Prelude
import Data.Foldable as F
import Data.Functor.Foldable
import Data.Monoid
import Control.Comonad.Cofree

data ExprF r = Const Int
              | Add   r r
                deriving ( Show, Eq, Ord, Functor, Prelude.Foldable )

type Expr = Fix ExprF

testExpr = Fix $ Add (Fix (Const 1)) (Fix (Const 2))

convertToString :: Expr -> String
convertToString = cata $ \case
  e@(Const x) -> show x
  e@(Add x y) -> unwords [x, "+", y]

Now I want to add an additional data to it. So I am trying to use Cofree

type LineNumber = Int
type Expr2 = Cofree ExprF LineNumber

I can convert Expr to Expr2

addLineNumbers :: Expr -> Expr2
addLineNumbers = cata $ \case
  e@(Const _) -> 1 :< e
  e -> 2 :< e

But I cannot figure out how to convert Expr2 to String

convertToString2 :: Expr2 -> String
convertToString2 = cata $ \case
  e@(_ :< (Const x)) -> show x
  e@(_ :< (Add x y)) -> unwords [x, "+", y]

Also, is Cofree the best way to solve this annotation problem?

  • 2
    Interesting question. I don't have an answer for you right now but I will share this thought. Free is inductive and Cofree is coinductive. That is, tearing down a (well-behaved) free monad using a (total) algebra for an arbitrary functor is guaranteed terminating, and building up a cofree comonad using a coalgebra is guaranteed productive. The other way round is not true – Benjamin Hodgson Jul 19 '16 at 15:49
up vote 9 down vote accepted

An alternative way of annotating your syntax tree is to compose the annotation into the base functor.

-- constant functor
newtype K c a = K c
    deriving (Eq, Ord, Show, Read, Functor, Foldable, Traversable)

-- functor product
data (f :*: g) a = (:*:) { left :: f a, right :: g a }
    deriving (Eq, Ord, Show, Read, Functor, Foldable, Traversable)

We're going to use the functor product to attach an annotation (inside a K) to each layer of the tree.

type AnnExpr = Fix (K LineNumber :*: ExprF)

If you can generate annotations while only inspecting a single layer of the tree (that is, your annotation-generating code can be expressed as a natural transformation) then you can use the following bit of machinery to modify the functor while keeping the fixpoint structure in place:

hoistFix :: Functor f => (forall a. f a -> g a) -> Fix f -> Fix g
hoistFix f = Fix . f . fmap (hoistFix f) . unFix

This is of limited usefulness, though, as most interesting annotations such as type-checking require traversal of the syntax tree.

You can reuse the code to tear down an Expr by simply ignoring the annotations. Given an algebra for ExprF...

-- instructions for a stack machine
data Inst = PUSH Int | ADD
type Prog = [Inst]

compile_ :: ExprF Prog -> Prog
compile_ (Const x) = [PUSH x]
compile_ (Add x y) = x ++ y ++ [ADD]

... you can use it to tear down either an Expr or an AnnExpr:

compileE :: Expr -> Prog 
compileE = cata compile_

compileA :: AnnExpr -> Prog
compileA = cata (compile_ . right)
  • When you encounter this pattern often, it becomes useful to define such a constant annotation directly: data (:&) x f a = x :& f a - this is just a matter of preference, of course. – user2407038 Jul 19 '16 at 16:34
  • 1
    @user2407038 I prefer to reuse smaller bits like K and :*:, and define type/pattern synonyms for doman-specific uses. type (x :& g) = K x :*: g and pattern x :& y = K x :*: y – Benjamin Hodgson Jul 19 '16 at 16:39

Your Answer


By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.