# Maybe and recursion on list

I try to implement the `reverse` function with `Maybe`. I don't know how to return `Just` in pattern matching using recursion. By example, `ghci> myReverse [1,2,3]` need to return `Just [3,2,1]`. Here is my code :

``````myReverse :: [a] -> Maybe [a]
myReverse [] = Nothing
myReverse [x] = Just [x]
myReverse (x:xs) = myReverse xs ++ [x] -- here's my problem.
``````

I thought that `myReverse (x:xs) = Just \$ myReverse xs ++ [x]` work, but no and I don't know how to do it. What I would to know it is how to do it and why.

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Just out of curiosity, why are you not implementing the same behavior as the original `reverse` function? Why can't the reverse of an empty list be an empty list? – Gabriel Gonzalez Apr 14 '13 at 2:11
Yeah it can be, but the goal is to learn more about Haskell (to be confronted at this kind of problem force you to try a lot of solutions and searching for answers, and so you learn new things). – vildric Apr 14 '13 at 5:42

`myReverse` returns a `Maybe [a]`, which can't be directly appended to something because it is not a list. IOW the value of `myReverse xs` will be either `Nothing`, or `Just <some list>`. You need to pattern match on the result.

``````myReverse (x:xs) =
case myReverse xs of
Just list -> ...
Nothing   -> ...
``````

And of course, you need to decide what needs to be done in each of these cases, depending on what you want `myReverse` to do.

Also keep in mind that not every function needs to be recursive, so you can call the regular `reverse` from `myReverse` if you need it.

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I've tried for a while and can't wrap my head around how to implement the recursion suggested in your coded section (I'm assuming it should supplant only the last line of vildric's code). Can you give me/us a hint? – גלעד ברקן Apr 14 '13 at 0:08
The only way I could come up with to apply your coded section is with mappend, as zurgl mentioned, but then the case syntax would seem superfluous since you could write `myReverse (x:xs) = mappend (myReverse xs) (Just [x])`. Using the case syntax: `myReverse [] = Nothing; case myReverse xs of Nothing -> Just [x]; otherwise -> mappend (myReverse xs) (Just [x])` ..Is there a way to implement your coded section without mappend? – גלעד ברקן Apr 14 '13 at 2:58
You're not even using the value bound by the case! In the `Just list ->` case, `list` is a value of type `[a]`, to which you can do as you please... for example `Just (list ++ [x])`. In any case, this answer is "low level" and I would consider it a smell if it occurred in my code; I would generally prefer to use `mappend` as you suggested. I just wanted to keep it nice and concrete for beginners. – luqui Apr 14 '13 at 6:42
It doesn't work, or at least I can't make it work. I toyed with all manner of expressions, including Just `(list ++ [x])`. Could you please show a working example without mappend? – גלעד ברקן Apr 14 '13 at 13:54
@groovy maybe you can ask another SO question about it? – luqui Apr 14 '13 at 19:54

As `[a]` is a Monoid define by,

``````instance Monoid [a] where
mempty  = []
mappend = (++)
``````

Then `Maybe [a]` is also a Monoid,

``````instance Monoid a => Monoid (Maybe a) where
mempty = Nothing
Nothing `mappend` m = m
m `mappend` Nothing = m
Just m1 `mappend` Just m2 = Just (m1 `mappend` m2)
``````

Note the type constraint in the instance declaration which impose `a` to be a Monoid or else `Maybe a` won't.

We can then use mappend, `(<>)`, to chain our recursive call at the condition to transform the head of the list to a singleton.

``````import Data.Monoid ((<>))

myReverse :: [a] -> Maybe [a]
myReverse []     = Nothing
myReverse (x:xs) = myReverse xs <> Just [x]
``````

Last note, the previous fold solution can be improve too.

``````>>> let mrev = foldl' (\x y -> Just [y] <> x ) Nothing
>>> mrev []
Nothing
>>> mrev "hello"
Just "olleh"
``````

Knowing that reverse can be define using fold as follow,

``````>>> foldl' (flip (:)) [] [1..5]
[5,4,3,2,1]
``````

This can be rewritten as,

``````>>> foldl' (\x y -> y:x) [] [1..5]
[5,4,3,2,1]
``````

To adapt for Maybe type, we do the following transformation,

• The seed `[]` become `(Just [])`
• The anonymous function must now be apply inside Just, we use fmap to do it.

``````>>> foldl' (\x y -> fmap (y:) x) (Just []) [1..5]
Just [5,4,3,2,1]
``````

Finally,

``````mreverse xs | null xs = Nothing
| foldl' (\x y -> fmap (y:) x) (Just []) xs
``````
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Cool interpretation...what about the "Nothing" for `myReverse []`? – גלעד ברקן Apr 13 '13 at 23:52
we can manage this case using pattern guard, `mreverse xs | null xs = Nothing | otherwise = foldl' (\x y -> fmap (y:) x) (Just []) xs` – zurgl Apr 13 '13 at 23:54

I thought of something along the lines of luqui's, except applying the Maybe at the end:

``````myReverse :: [a] -> Maybe [a]
myReverse ys
| null (myReverse' ys) = Nothing
| otherwise            = Just (myReverse' ys)
where
myReverse' []     = []
myReverse' (x:xs) = myReverse' xs ++ [x]
``````

Or, if you will,

``````myReverse ys | null (reverse ys) = Nothing
| otherwise         = Just (reverse ys)
``````
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This will always return `Nothing` or throw an error because `otherwise = True`. Did you mean something more like `let reversed = myReverse' ys in if null reversed then Nothing else Just reversed`? – Jon Purdy Apr 13 '13 at 23:33
@JonPurdy seems to work fine for me. Did you try it? – גלעד ברקן Apr 13 '13 at 23:35
Oh, I was misreading the pattern as an expression. I’ve never thought to call a wildcard case `otherwise` because it would shadow `Prelude.otherwise`. – Jon Purdy Apr 13 '13 at 23:57