While I can't give a proof, I believe what this is saying is that due to *parametricity*, the type system enforces the second law as long as the first law holds. The reason to specify both rules is that in the more general mathematical setting, you might have some category **C** where it is perfectly possible to define a "mapping" from **C** to itself (i.e. a pair of endofunctions on *Obj(***C***)* and *Hom(***C***)* respectively) which obeys the first rule but fails to obey the second rule, and therefore fails to constitute a functor.

Remember that `Functor`

s in Haskell are endofunctors on the category **Hask**, and not even everything that would mathematically be considered an endofunctor on **Hask** can be expressed in Haskell... the constraints of parametric polymorphism rule out being able to specify a functor which does not behave uniformly for all objects (types) which it maps.

Based on this thread, the general consensus seems to be that the second law follows from the first for Haskell `Functor`

instances. Edward Kmett says,

*Given* `fmap id = id`

, `fmap (f . g) = fmap f . fmap g`

*follows from the free
theorem for fmap.*

*This was published as an aside in a paper a long time back, but I forget where.*