The monad laws are traditionally described in terms of `>>=`

and `pure`

:

```
pure a >>= k = k a
m >>= pure = m
m >>= (\x -> k x >>= h) = (m >>= k) >>= h
```

However, monads can also be defined in terms of `join`

instead of `>>=`

. I would like to come up with a formulation of the monad laws in terms of `join`

.

Using `x >>= f = join (fmap f x)`

, it’s easy to rewrite the existing monad laws to eliminate `>>=`

. Simplifying the results slightly with the help of the applicative laws, the first two laws are quite pleasantly expressed:

```
join . pure = id
join . fmap pure = id
```

The intuition for these laws is easy, too, since clearly, introducing an extra “layer” with `pure`

should be a no-op when combined with `join`

. The third law, however, is not nearly so nice. It ends up looking like this:

```
join (fmap (\x -> join (fmap h (k x))) m)
= join (fmap h (join (fmap k m)))
```

This does not pleasantly reduce using the applicative laws, and it’s much harder to understand without staring at it for a while. It certainly doesn’t have the same easy intuition.

Is there an equivalent, alternative formulation of the monad laws in terms of `join`

that is easier to understand? Alternatively, is there any way to simplify the above law, or to make it easier to grok? The version with `>>=`

is already less nice than the one expressed with Kleisli composition, but the version with `join`

is nearly unreadable.

`join . pure = join . fmap pure = id`

) and the right-hand diagram can be stated as`join . join = join . fmap join`

. Note that`(\h k m -> join (fmap h (join (fmap k m)))) id id = \m -> join (join m)`

- this follows from`fmap id = id`

(and likewise for the other side of the two equalities). In other words, your law expresses both functor and monad laws in one statement.