This question comes from this answer in example of a functor that is Applicative but not a Monad: It is claimed that the

```
data PoE a = Empty | Pair a a deriving (Functor,Eq)
```

cannot have a monad instance, but I fail to see that with:

```
instance Applicative PoE where
pure x = Pair x x
Pair f g <*> Pair x y = Pair (f x) (g y)
_ <*> _ = Empty
instance Monad PoE where
Empty >>= _ = Empty
Pair x y >>= f = case (f x, f y) of
(Pair x' _,Pair _ y') -> Pair x' y'
_ -> Empty
```

The actual reason why I believe this to be a monad is that it is isomorphic to `Maybe (Pair a)`

with `Pair a = P a a`

. They are both monads, both traversables so their composition should form a monad, too. Oh, I just found out not always.

Which counter-example failes which monad law? (and how to find that out systematically?)

*edit:* I did not expect such an interest in this question. Now I have to make up my mind if I accept the best example or the best answer to the "systematically" part.

Meanwhile, I want to visualize how `join`

works for the simpler `Pair a = P a a`

:

```
P
________/ \________
/ \
P P
/ \ / \
1 2 3 4
```

it always take the outer path, yielding `P 1 4`

, more commonly known as a diagonal in a matrix representation. For monad associativy I need three dimensions, a tree visualization works better. Taken from chi's answer, this is the failing example for join, and how I can comprehend it.

```
Pair
_________/\_________
/ \
Pair Pair
/\ /\
/ \ / \
Pair Empty Empty Pair
/\ /\
1 2 3 4
```

Now you do the `join . fmap join`

by collapsing the lower levels first, for `join . join`

collapse from the root.

`Pair (Pair 1 2) Empty >>= return`

returns Empty. That s not good . – mb14 Apr 9 '18 at 22:30`Empty`

– Silvio Mayolo Apr 9 '18 at 22:33`>>= id`

– mb14 Apr 10 '18 at 6:40