Why is (=<<) id = join in Haskell?

``````(=<<) :: (a -> m b) -> m a -> m b
id :: a -> a
join :: m (m a) -> m a
``````

So shouldn't,

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

give an error because,

``````id :: a -> a
``````

and not,

``````id :: a -> m a
``````

Doesn't (=<<) expect,

``````(something -> m anything)
``````

as its first argument?

-

`m a' -> m a'` is also a kind of `a -> a`, so we can have

``````      id ::  m a' -> m a'                        -- a = m a'
(=<<) :: (m a' -> m a') -> m (m a') -> m a'   -- a = m a', b = a'

(=<<) id ::                   m (m a') -> m a'
``````
-
ooo! got it! (=<<) :: (m a' -> m a') -> m (m a') -> m a' -- a = m a', b = a' did it for me. a can be m a', all that is necessary is one get back anything wrapped in m. Thanks mate! –  louzer Aug 18 '12 at 10:02
@louzer Exactly. You can consider 1 layer of `m` to be a stable point of a monad. You can always join 2 or more layers of `m` into 1 layer using `join`, and you can always lift 0 layers of `m` into 1 layer using `return`. –  Gabriel Gonzalez Aug 18 '12 at 16:20
@GabrielGonzalez: it does get a bit more complicated when you have something like `m (n (m a))` though. –  Ben Millwood Aug 18 '12 at 22:17
@BenMillwood and in those cases, `sequenceA` (a kind of generalized `transpose`) from `Data.Traversable` can swap the outer `m` and `n` or the inner `n` and `m` so that `join` can then apply. –  Conal Aug 19 '12 at 16:35
@Conal: sure, you can do that when the types involved are in the right classes, but it's not as simple as "if you have two monad type constructors, just join them". Sometimes, of course, `IO (IO a)` actually is the type you want. –  Ben Millwood Aug 19 '12 at 19:13