Can join be defined in terms of bind?

TL;DR answer: Yes.

```
join ∷ (Monad m) ⇒ m (m a) → m a
join = (=<<) id
```

The longer answer:
To add some subtleties that have yet to be mentioned I'll provide a new answer, starting by expanding upon Lee's answer, because it is worth noting that their answer can be simplified. Starting with the original:

```
join ∷ (Monad m) ⇒ m (m a) → m a
join m = m >>= id
```

One can look for an Eta conversion (η-conversion) opportunity to make the function definition point-free. To do this we want to first rewrite our function definition without the infix `>>=`

(as would likely be done if we were calling `>>=`

by the name `bind`

in the first place).

```
join m = (>>=) m id
```

Now observe that if we use the `flip`

function, recalling:

```
-- defined in Data.Function
-- for a function of two arguments, swap their order
flip ∷ (a → b → c) → b → a → c
flip f b a = f a b
```

One may now use `flip`

to put the `m`

in position for an η-reduction:

```
join m = (flip (>>=)) id m
```

Applying the η-reduction:

```
join = (flip (>>=)) id
```

Noticing now that `flip (>>=)`

can be replaced with `(=<<)`

(defined in `Control.Monad`

):

```
join = (=<<) id
```

Finally we can see shorter, point-free definition:

```
join ∷ (Monad m) ⇒ m (m a) → m a
join = (=<<) id
```

Where `(=<<)`

has type:

```
(=<<) ∷ ∀ (m ∷ * -> *) a b. (Monad m) ⇒ (a → m b) → m a → m b
```

which in the process gets instantiated to:

```
(=<<) ∷ (m a → m a) → m (m a) → m a
```

Additionally, one may also notice that if we put the code above back into infix form, the `flip`

becomes implicit, and we get the same final answer as Ben does:

```
join = (>>= id)
```

haveto be a member of`Monad`

(or wouldn't be defined for all monads), and it isn't.