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?

`Free`

is inductive and`Cofree`

is coinductive. That is,tearing downa (well-behaved) free monad using a (total) algebra for an arbitrary functor is guaranteed terminating, andbuilding upa cofree comonad using a coalgebra is guaranteed productive. The other way round is not true – Benjamin Hodgson♦ Jul 19 '16 at 15:49