I was wondering to what extent `Functor`

instances in Haskell are determined (uniquely) by the functor laws.

Since `ghc`

can derive `Functor`

instances for at least "run-of-the-mill" data types, it seems that they must be unique at least in a wide variety of cases.

For convenience, the `Functor`

definition and functor laws are:

```
class Functor f where
fmap :: (a -> b) -> f a -> f b
fmap id = id
fmap (g . h) = (fmap g) . (fmap h)
```

Questions:

Can one derive the definition of

`map`

starting from the assumption that it is a`Functor`

instance for`data List a = Nil | Cons a (List a)`

? If so, what assumptions have to be made in order to do this?Are there any Haskell data types which have more than one

`Functor`

instances which satisfy the functor laws?When can

`ghc`

derive a`functor`

instance and when can't it?Does all of this depend how we define equality? The

`Functor`

laws are expressed in terms of an equality of values, yet we don't require`Functors`

to have`Eq`

instances. So is there some choice here?

Regarding equality, there is certainly a notion of what I call "constructor equality" which allows us to reason that `[a,a,a]`

is "equal" to `[a,a,a]`

for any value of `a`

of any type even if `a`

does not have `(==)`

defined for it. All other (useful) notions of equality are probably coarser that this equivalence relationship. But I suspect that the equality in the `Functor`

laws are more of an "reasoning equality" relationship and can be application specific. Any thoughts on this?

`Either a b`

can be a functor in two ways. So can`(a, b)`

... Those are both trivial examples but I think it's not out of the question that there would be some non-trivial ones.`f`

to the value of`Right`

otherwise noopHaskell typeclass`Functor`

and themathematical thing'functor'.