The type of `map`

is `map :: (a -> b) -> [a] -> [b]`

. Hence the type of `map foo`

is obtained from `[a] -> [b]`

by substituting `a`

and `b`

with what can be derived from `foo`

's type. If, for example, `foo :: t -> t`

, you substitute `a = t, b = t`

and obtain `[t] -> [t]`

. If `foo :: [t] -> Int`

, you obtain `[[t]] -> [Int]`

.

In your case, the type of `foo`

(which is `map`

) is `(x -> y) -> [x] -> [y]`

. You have to unify that type with `a -> b`

to find out what `a`

and `b`

have to be substituted with. [Note that the function arrow is right-associative, `x -> y -> z = x -> (y -> z)`

.]

To find the type of

```
\x -> x >>= (\y -> y)
```

use the known type of `(>>=) :: Monad m => m a -> (a -> m b) -> m b`

. Ignore the constraint (`Monad m =>`

) for now.

As the first argument of `(>>=)`

, `x`

must have a type `m a`

for as yet unknown `m`

and `a`

. The second argument of `(>>=)`

is here the identity,

```
(\y -> y) :: t -> t
```

so you must unify `t -> t`

with `a -> m b`

. That gives you some information about `a`

, namely `a = m b`

.

That gives `x :: m (m b)`

, and `(\x -> x >>= (\y -> y)) :: type_of_x -> type_of_rhs`

.

Finally remember the temporarily forgotten constraint `Monad m =>`

.