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Hello I'am currently studying for exams and was having issues with an answering topic, as the title state, the goal is to create a non-recursive concat function using comprehension lists, looking at the solution it is:

concat3 :: [[a]] -> [a]
concat3 xss = [x | xs <- xss, x <-xs]

Yet I can not understand why that works, any help would be appreciated.

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List comprehensions are defined in terms of other constructs. Find the translation in e. g. the Haskell98 report and translate your function. – n.m. Jul 8 '13 at 5:42
In other words, read: Understanding Monads (List) – Julien Langlois Jul 8 '13 at 5:55
up vote 9 down vote accepted

List comprehension arrows (<-) can be read as "in", like [x | xs <- xss, x <- xs] reads "x for xs in xss and x in xs" which indicates that we're unpacking each list in our list-of-lists to its constituent elements—which is kind of like concat.

There are many ways to view this, though.

Mechanically, list comprehensions translate to do notation

do xs <- xss
   x  <- xs
   return x

and do notation translates to (>>=) and (>>)

xss >>= \xs -> xs >>= \x -> return x

and then (>>=) itself turns into concatMap and return to (\x -> [x]) when we instantiate them on lists.

concatMap (\xs -> concatMap (\x -> [x]) xs) xxs

and if you think about concatMap (\x -> [x]) you might see it as passing over a list, taking each element to a singleton list, then concatenating them... which is just a complex way of doing nothing whatsoever.

concatMap id xss

and from the definition of concatMap we have

concat (map id xss)

and finally just (from the Functor laws! Or common sense)

concat xss

so it shouldn't be surprising that the function works like concat does.

What about interpreting the do notation as we tend to think semantically when in the "list monad"?

do xs <- xss
   x  <- xs
   return x

In essence, this can be read as "choose non-deterministically one of the constituent lists from our list-of-lists, then choose non-deterministically one of the elements from that list--collect all possibilities from this procedure" which, again, leads to the idea that we're just concatenating.

We could also take a lucky correspondance from the Control.Monad function join

join              :: (Monad m) => m (m a) -> m a  -- this looks `concat`-like!
join x            =  x >>= id

If we consider the inner xs >>= \x -> return x and then use eta-conversion we have xs >>= return which is just the "right identity" monad law, helping us to see that

xss >>= \xs -> xs >>= \x -> return x
xss >>= \xs -> xs >>= return
xss >>= \xs -> xs
xss >>= id
join xss

and then we can lookup how to instantiate join in the list monad and see join = concat.

So there are many ways see concat as implemented via a list comprehension, depending on how you want to think of list comprehensions. The great part is that these are all equivalent and can build upon one another to form a basis for what the lists and their monad instances really mean.

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Good answer, but I believe it is too advanced to be helpful to the OP. – luqui Jul 8 '13 at 6:37
Thanks—I'm a little worried that it is impenetrable, but hope that a balance of intuition and calculation will lay the groundwork for the answer. I think yours is an important intuition I left out, so I'm glad you added it. – J. Abrahamson Jul 8 '13 at 13:48
Both answer did their job really well, luqui helped me understand how to create them using comprehension lists, and tels helped me understand why it works. Thanks for your time. – azthec Jul 8 '13 at 18:30

You can picture a list comprehension as a nested loop. So,

[ z | x <- list1, y <- list2 ]

means "for each x in list1, for each y in list2, yield z", and the resulting list is the collection of all yielded values in order. Notice that the value to be yielded, z here, comes first in the notation. So if we had:

[ (x,y) | x <- [1,2], y <- [3,4,5] ]

This says, "for each x in [1,2], for each y in [3,4,5], yield (x,y)", and thus we get:

[ (1,3), (1,4), (1,5),   -- when x = 1
  (2,3), (2,4), (2,5) ]  -- when x = 2

Equipped with a mnemonic for list comprehensions, we can read your concat3 definition.

concat3 xss = [ x | xs <- xss, x <- xs ]

I am going to rename the variables to make it easier to read:

concat3 listOfLists = [ x | list <- listOfLists, x <- list ]

We can now read this as, "for each list in listOfLists, for each x in list, yield x". That is, yield all the elements from the first list, then all the elements from the second list, and so on, which corresponds to concatenating all the lists.

The naming I used is unlikely to be seen in the wild. It is conventional to use "plural" names, ending with s, for variables that are meant to denote lists. Pronounce xs as "exes". Taking the linguistic analogy perhaps too far (but it is still common convention), we "double-pluralize" lists of lists, xss. I usually don't pronounce that, because "exeses" sounds too silly. So you can see by the name that xss is a list of lists, and xs is a list, which will you help read dense expressions like these.

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I've always pronounced xss about the same as excesses, ever since my funtional programming lecturer called it that decades ago! – AndrewC Jul 8 '13 at 7:02

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