OK, so it's not really good form to answer your own question, but I'm going to note down my thinking in case it enlightens anybody else. (I doubt it...)
If a monad can be thought of as a "container", then both
join have pretty obvious semantics.
return generates a 1-element container, and
join turns a container of containers into a single container. Nothing hard about that.
So let us focus on monads which are more naturally thought of as "actions". In that case,
m x is some sort of action which yields a value of type
x when you "execute" it.
return x does nothing special, and then yields
fmap f takes an action that yields an
x, and constructs an action that computes
x and then applies
f to it, and returns the result. So far, so good.
It's fairly obvious that if
f itself generates an action, then what you end up with is
m (m x). That is, an action that computes another action. In a way, that's maybe even simpler to wrap your mind around than the
>>= function which takes an action and a "function that produces an action" and so on.
So, logically speaking, it seems
join would run the first action, take the action it produces, and then run that. (Or rather,
join would return an action that does what I just described, if you want to split hairs.)
That seems to be the central idea. To implement
join, you want to run an action, which then gives you another action, and the you run that. (Whatever "run" happens to mean for this particular monad.)
Given this insight, I can take a stab at writing some
join Nothing = Nothing
join (Just mx) = mx
If the outer action is
Nothing, else return the inner action. Then again,
Maybe is more of a container than an action, so let's try something else...
newtype Reader s x = Reader (s -> x)
join (Reader f) = Reader (\ s -> let Reader g = f s in g s)
That was... painless. A
Reader is really just a function that takes a global state and only then returns its result. So to unstack, you apply the global state to the outer action, which returns a new
Reader. You then apply the state to this inner function as well.
In a way, it's perhaps easier than the usual way:
Reader f >>= g = Reader (\ s -> let x = f s in g x)
Now, which one is the reader function, and which one is the function that computes the next reader...?
Now let's try the good old
State monad. Here every function takes an initial state as input but also returns a new state along with its output.
data State s x = State (s -> (s, x))
join (State f) = State (\ s0 -> let (s1, State g) = f s0 in g s1)
That wasn't too hard. It's basically run followed by run.
I'm going to stop typing now. Feel free to point out all the glitches and typos in my examples... :-/