Okay, let's look at `concat`

.

First, here's the implementation:

```
concat :: [[a]] -> [a]
concat = foldr (++) []
```

This parallels the structure of your `h`

where `Maybe`

is replaced by `[]`

and, more significantly, `[]`

is replaced by--to abuse syntax for a moment--`[[]]`

.

`[[]]`

is a functor as well, of course, but it's *not* a `Functor`

instance in the way that the naturality condition uses it. Translating your example directly won't work:

`concat . fmap k`

=/= `fmap k . concat`

...because both `fmap`

s are working on only the outermost `[]`

.

And although `[[]]`

is hypothetically a valid instance of `Functor`

you can't make it one directly, for practical reasons that are probably obvious.

However, you can reconstruct the correct lifting as so:

`concat . (fmap . fmap) k`

== `fmap k . concat`

...where `fmap . fmap`

is equivalent to the implementation of `fmap`

for a hypothetical `Functor`

instance for `[[]]`

.

As a related addendum, `return`

is awkward for the opposite reason: `a -> f a`

is a natural transformation from an elided identity functor. Using `: []`

the identity would be written as so:

`(:[]) . ($) k`

== `fmap k . (:[])`

...where the completely superfluous `($)`

is standing in for what would be `fmap`

over the elided identity functor.

`f a -> g a`

is a natural transformation (modulo the usual issues with bottom). This means that you don't actually have to check every individual function to see if it satisfies the conditions for being a natural transformation. They are "free theorems". The place to start reading is here: citeseer.ist.psu.edu/viewdoc/summary?doi=10.1.1.38.9875 – sigfpe Jun 7 '11 at 0:10