# Point-free functions in monadic binding

I've been investigating the usage of `>>=` with lists (when viewed as monads). In an article All about monads I found the following identity for lists: `l >>= f = concatMap f l`, where `l` is a list and `f` is some (unary) function. I tried the simple example of doubling each element of a list and arrived at the following:

``````let double :: Int -> [Int]
double = (flip (:) []) . (2*)
``````

I specifically wanted the `double` function to be written in a point-free manner. Can you think of simpler implementations of `double` so that it still can be used with `>>=`?

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`double = (:[]) . (2*)` –  Sassa NF Feb 19 '14 at 14:16
also, `double = return . (2*)` –  Sassa NF Feb 19 '14 at 14:17
For future reference, try out the `pointfree` package, which comes with a `pointfree` executable that can eta-reduce a code snippet for you. All I did was `pointfree "double x = [2 * x]"` to get `double = return . (2 *)` and `pointfree "double x = [x + x]"` to get `double = return . join (+)` –  bheklilr Feb 19 '14 at 14:31
@bheklir I meant that `return` and `join` come from different monads, which still pricks my eyes. Even though that's not unusual. –  Sassa NF Feb 19 '14 at 15:09
@bheklilr But `return . (*2) :: (Monad m, Num b) => b -> m b` too –  J. Abrahamson Feb 19 '14 at 15:42

Sassa NF's `return . (*2)` is both short and demonstrates an interesting principle of your example. If we inline the whole thing we'll get

``````list >>= double
list >>= return . (*2)
``````

The pattern `\f l -> l >>= return . f` Is common enough to have its own name: `liftM`

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

And in fact, `liftM` is equivalent to `fmap`, often known as just `map` when referring to lists:

``````list >>= return . (*2)
liftM (*2) list
fmap (*2) list
map (*2) list
``````
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Thanks for the useful additional insights, @J.Abrahamson –  Wojciech Gac Feb 19 '14 at 16:38