# Issue understanding non-recursive list comprehension concat in haskell

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

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