The best place to look for lots of example functions using GHC Generics is the `generic-deriving`

package. There's a generic definition of the `Functor`

class in there. Copying (slightly simplified) from `Generics.Deriving.Functor`

:

```
class GFunctor' f where
gmap' :: (a -> b) -> f a -> f b
instance GFunctor' U1 where
gmap' _ U1 = U1
instance GFunctor' Par1 where
gmap' f (Par1 a) = Par1 (f a)
instance GFunctor' (K1 i c) where
gmap' _ (K1 a) = K1 a
instance (GFunctor f) => GFunctor' (Rec1 f) where
gmap' f (Rec1 a) = Rec1 (gmap f a)
instance (GFunctor' f) => GFunctor' (M1 i c f) where
gmap' f (M1 a) = M1 (gmap' f a)
instance (GFunctor' f, GFunctor' g) => GFunctor' (f :+: g) where
gmap' f (L1 a) = L1 (gmap' f a)
gmap' f (R1 a) = R1 (gmap' f a)
instance (GFunctor' f, GFunctor' g) => GFunctor' (f :*: g) where
gmap' f (a :*: b) = gmap' f a :*: gmap' f b
instance (GFunctor f, GFunctor' g) => GFunctor' (f :.: g) where
gmap' f (Comp1 x) = Comp1 (gmap (gmap' f) x)
class GFunctor f where
gmap :: (a -> b) -> f a -> f b
default gmap :: (Generic1 f, GFunctor' (Rep1 f))
=> (a -> b) -> f a -> f b
gmap = gmapdefault
gmapdefault :: (Generic1 f, GFunctor' (Rep1 f))
=> (a -> b) -> f a -> f b
gmapdefault f = to1 . gmap' f . from1
```

To use this on a datatype, you have to derive `Generic1`

rather than `Generic`

. The key difference of the `Generic1`

representation is that it makes use of the `Par1`

datatype that encodes parameter positions.