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I found some question here: Redefining monad list instance. I'm currently trying to get my head wrapped around monads. But I need some help here, I don't get the instance-definition of lists as monads.

This is my given definition of a list-instance for a monad:

    instance Monad [] where
    xs >>= f = concat $ map f xs
    return x = [x]
    fail _ = []

I dont understand, why I need concat in the bind-function. This is my definition of (>>=):

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

So I have some monadic value m a and a function, taking a value a and producing a monadic value m b given as parameters. I 'feed' a from m a into the function (a -> m b) and thus get a monadic value m b as a result. In my own words: The bind-operator (>>=) allows to chain monadic functions (returning monadic values) where the value of the output of the earlier function is the input for the next function. Right?

Back to the list-instance. map f xs uses the function f on every value in xs. So map (*2) [1,2,3] results in [2,4,6]. And that's all I wanted here or not? How should I use concat here? The definition of concat is as follows:

    concat :: [[a]] -> [a]

Why do I get a list of lists in the (>>=)-function? Is it because list is the monad and I take every single value from that list to feed it to f and map just gets singleton-inputs? But how do I iterate over the whole list then? Where does the 'picking each value' happen? And if map takes the whole list xs as input (that's how I understand it) why should I get a list of lists?

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    Becaue the type of >>= is (a -> m b) -> m a -> m b. So the f we use with map will produce a list of lists of bs, so we need to convert that to a [b] again. – Willem Van Onsem Feb 7 '18 at 13:01
  • Ah! If it was (a -> m b) -> m a -> b I would not need concat. But because of that m b where m is the list I get a list of singleton-lists? – Lyndra Feb 7 '18 at 13:04
  • The type signature in your comment is a bit of a weird one. Do you mean (a -> b) -> m a -> m b? That seems to match more with your conclusion that you wouldn't need concat. And in fact that is a very useful function: it is fmap, from Functor. – amalloy Feb 7 '18 at 13:05
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    Note that in category theory, monads are defined using return :: a -> m a and join :: m (m a) -> m a. concat is effectively filling the purpose of join, which can be used to implement xs >>= f = join (fmap f xs). – chepner Feb 7 '18 at 13:14
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If

x :: [a]
f :: a -> [b]

then

map f :: [a] -> [[b]]
map f x :: [[b]]

so, we need to flatten the latter into [b]. This is done by concat.

Note how f was already producing a list, so map makes that into a list-of-lists. This is crucial: if f was not producing a list but were f :: a->b, then we don't need concat -- we don't even need a monad, since a functor providing fmap=map :: (a->b) -> [a] -> [b] would be enough.

The added benefit of a monad over a functor mainly lies in letting f produce a value in a monadic type.

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