Here's a syntax for a dependently-typed lambda calculus.

```
data TermI a = Var a
| App (TermI a) (TermC a) -- when type-checking an application, infer the type of the function and then check that its argument matches the domain
| Star -- the type of types
| Pi (Type a) (Scope () Type a) -- The range of a pi-type is allowed to refer to the argument's value
| Ann (TermC a) (Type a) -- embed a checkable term by declaring its type
deriving (Functor, Foldable, Traversable)
data TermC a = Inf (TermI a) -- embed an inferrable term
| Lam (Scope () TermC a)
deriving (Functor, Foldable, Traversable)
type Type = TermC -- types are values in a dependent type system
```

(I more-or-less lifted this from *Simply Easy*.) The type system is bidirectional, splitting terms into those whose type can be inferred from the typing context, and those which can only be checked against a goal type. This is useful in dependent type systems because in general lambda terms will have no principal type.

Anyway, I've got stuck trying to define a `Monad`

instance for this syntax:

```
instance Monad TermI where
return = Var
Var x >>= f = f x
App fun arg >>= f = App (fun >>= f) (arg >>= Inf . f) -- embed the substituted TermI into TermC using Inf
Star >>= _ = Star
Pi domain range >>= f = Pi (domain >>= Inf . f) (range >>>= Inf . f)
Ann term ty >>= f = Ann (term >>= Inf . f) (ty >>= Inf . f)
instance Monad TermC where
return = Inf . return
Lam body >>= f = Lam (body >>>= f)
Inf term >>= f = Inf (term >>= _)
```

To fill the hole in the last line of `TermC`

's instance, I need something of type `a -> TermI b`

but `f`

has a type of `a -> TermC b`

. I can't embed the resulting `TermC`

into `TermI`

using the `Ann`

constructor because I don't know the type of the `TermC`

.

Is this datatype incompatible with `bound`

's model? Or is there a trick I can use to make the `Monad`

instance go?

`(var 0 (var 1)) [\x -> x]`

, you'll get`(\x -> x) (var 1)`

, which doesn't have a syntactic representation in your type system. Note that both`subst`

s in the paper receive inferrable terms and there is no`subst : TermC -> TermC -> TermC`

. It's not necessarily to have bidirectional type system in order to define a bidirectional type checker, so you can just collapse these mutually recursive data types into a single`Term`

.`bound`

doesn't support mutual data, but (as said above) you can do your type checker with a single data definition. The indexed version of`bound`

can do mutual data (for example), but it doesn't exist as published library.`Lam`

without an annotation, which should not be syntactically valid. I suppose I could require a type in the`Lam`

constructor (`Lam (Scope () Term a) Type`

), but then you get superfluous annotations for nested lambdas, and you have to support an additional construct for annotating other terms.`bound`

doesn't do the trick, you may look into the more typey paper`bound`

simplifies. I don't know if it's the right sort of typey, but it's worth checking.de Bruijn Notation as a Nested Datatype? As far as I can tell, the main difference between`bound`

and that paper is that`bound`

's`Var`

has an extra parameter to account for the type of variables bound in a particular scope. (If anything`bound`

is the more typey of the two!)1more comment