A key ability of `Monad`

is to "look inside" the `m a`

type and see an `a`

; but a key restriction of `Monad`

is that it must be possible for monads to be "inescapable," i.e., the `Monad`

typeclass operations should not be sufficient to write a function of type `Monad m => m a -> a`

. `(>>=) :: Monad m => m a -> (a -> m b) -> m b`

gives you exactly this ability.

But there's more than one way to achieve that. The `Monad`

class could be defined like this:

```
class Functor f where
fmap :: (a -> b) -> f a -> f b
class Functor f => Monad m where
return :: a -> m a
join :: m (m a) -> m a
```

You ask why could we not have a `Monad m => m a -> (m a -> m b) -> m b`

function. Well, given `f :: a -> b`

, `fmap f :: ma -> mb`

is basically that. But `fmap`

by itself doesn't give you the ability to "look inside" a `Monad m => m a`

yet not be able to escape from it. However `join`

and `fmap`

together give you that ability. `(>>=)`

can be written generically with `fmap`

and `join`

:

```
(>>=) :: Monad m => m a -> (a -> m b) -> m b
ma >>= f = join (fmap f ma)
```

In fact this is a common trick for defining a `Monad`

instance when you're having trouble coming up with a definition for `(>>=)`

—write the `join`

function for your would-be monad, then use the generic definition of `(>>=)`

.

Well, that answers the "does it have to be the way it is" part of the question with a "no." But, why is it the way it is?

I can't speak for the designers of Haskell, but I like to think of it this way: in Haskell monadic programming, the basic building blocks are actions like these:

```
getLine :: IO String
putStrLn :: String -> IO ()
```

More generally, these basic building blocks have types that look like `Monad m => m a`

, `Monad m => a -> m b`

, `Monad m => a -> b -> m c`

, ..., `Monad m => a -> b -> ... -> m z`

. People informally call these *actions*. `Monad m => m a`

is a no-argument action, `Monad m => a -> m b`

is a one-argument action, and so on.

Well, `(>>=) :: Monad m => m a -> (a -> m b) -> m b`

is basically the simplest function that "connects" two actions. `getLine >>= putStrLn`

is the action that first executes `getLine`

, and then executes `putStrLn`

passing it the result that was obtained from executing `getLine`

. If you had `fmap`

and `join`

and not `>>=`

you'd have to write this:

```
join (fmap putStrLn getLine)
```

Even more generally, `(>>=)`

embodies a notion much like a "pipeline" of actions, and as such is the more useful operator for using monads as a kind of programming language.

Final thing: make sure you are aware of the `Control.Monad`

module. While `return`

and `(>>=)`

are the basic functions for monads, there's endless other more high-level functions that you can define using those two, and that module gathers a few dozen of the more common ones. Your code should not be forced into a straitjacket by `(>>=)`

; it's a crucial building block that's useful both on its own and as a component for larger building blocks.

`flip id`

has (among others) the type`Monad m => m a -> (m a -> m b) -> m b`

. – Daniel Wagner Aug 15 '12 at 10:35