(>>=) can sometimes be useful when used directly, its main purpose is to implement the
<- bind syntax in do notation. It has the type
m a -> (a -> m b) -> m b mainly because, when used in a do notation block, the right hand side of the
<- is of type
m a, the left hand side "binds" an
a to the given identifier and, when combined with remainder of the do block, is of type
a -> m b, the resulting monadic action is of type
m b, and this is the only type it possibly could have to make this work.
echo = do
input <- getLine
The right hand side of the
<- is of type
The left hands side of the
<- with the remainder of the do block are of type
String -> IO (). Compare with the desugared version using
echo = getLine >>= (\input -> putStrLn input)
The left hand side of the
>>= is of type
IO String. The right hand side is of type
String -> IO (). Now, by applying an eta reduction to the lambda we can instead get:
echo = getLine >>= putStrLn
which shows why
>>= is sometimes used directly rather than as the "engine" that powers do notation along with
I'd also like to provide what I think is an important correction to the concept of "unwrapping" a monadic value, which is that it doesn't happen. The Monad class does not provide a generic function of type
Monad m => m a -> a. Some particular instances do but this is not a feature of monads in general. Monads, generally speaking, cannot be "unwrapped".
m >>= k = join (fmap k m) is a law that must be true for any monad. Any particular implementation of
>>= must satisfy this law and so must be equivalent to this general implementation.
What this means is that what really happens is that the monadic "computation"
a -> m b is "lifted" to become an
m a -> m (m b) using fmap and then applied the
m a, giving an
m (m b); and then
join :: m (m a) -> m a is used to squish the two
ms together to yield a
m b. So the
a never gets "out" of the monad. The monad is never "unwrapped". This is an incorrect way to think about monads and I would strongly recommend that you not get in the habit.