You don't need the case for adding `HZero`

and `HZero`

. This is already covered by the second case. Think how you'd add Peano naturals on the term level, by induction on the first argument:

```
data Nat = Zero | Succ Nat
add :: Nat -> Nat -> Nat
add Zero y = y
add (Succ x) y = Succ (add x y)
```

Now if you're using functional dependencies, you're writing a logic program. So instead of making a recursive call on the right hand side, you add a constraint for the result of the recursive call on the left:

```
class (HNat x, HNat y, HNat r) => HAdd x y r | x y -> r
instance (HNat y) => HAdd HZero y y
instance (HAdd x y r) => HAdd (HSucc x) y (HSucc r)
```

You don't need the `HNat`

constraints in the second instance. They're implied by the superclass constraints on the class.

These days, I think the nicest way of doing this sort of type-level programming is to use `DataKinds`

and `TypeFamilies`

. You define just as on the term level:

```
data Nat = Zero | Succ Nat
```

You can then use `Nat`

not only as a type, but also as a *kind*. You can then define a type family for addition on two natural numbers as follows:

```
type family Add (x :: Nat) (y :: Nat) :: Nat
type instance Add Zero y = y
type instance Add (Succ x) y = Succ (Add x y)
```

This is much closer to the term-level definition of addition. Also, using the "promoted" kind `Nat`

saves you from having to define a class such as `HNat`

.