My problem is how to combine the recursive, F-algebra-style recursive type definitions, with monadic/applicative-style parsers, in way that would scale to a realistic programming language.

I have just started with the `Expr`

definition below:

```
data ExprF a = Plus a a |
Val Integer deriving (Functor,Show)
data Rec f = In (f (Rec f))
type Expr = Rec ExprF
```

and I am trying to combine it with a parser which uses anamorphisms:

```
ana :: Functor f => (a -> f a) -> a -> Rec f
ana psi x = In $ fmap (ana psi) (psi x)
parser = ana psi
where psi :: String -> ExprF String
psi = ???
```

as far as I could understand, in my example, `psi`

should either parse just an integer, or it should decide that the string is a `<expr> + <expr>`

and then (by recursively calling `fmap (ana psi)`

), it should parse the left-hand side and the right-hand side expressions.

However, (monadic/applicative) parsers don't work like that:

- they first attempt parsing the left-hand expression,
- the
`+`

, - and the right-hand expression

One solution that I see, is to change the type definition for `Plus a a`

to `Plus Integer a`

, such that it reflects the parsing process, however this doesn't seem like the best avenue.

Any suggestions (or reading directions) would be welcome!