# List Nested Data Type Sum

I have this type

``````data List a = EmptyL | ConsL a (List (a,a))
``````

and I wrote this function

``````lenL :: List a -> Int
lenL EmptyL = 0
lenL (ConsL x xs) = 1 + lenL xs
``````

Can I write a function like this?

``````sumL :: List Int -> Int
``````

How?

• What have you tried? If you were able to write length in terms of recursion, can you extend that approach to sum? – Norrius Apr 16 at 0:12
• It is not really clear to me why you write `List (a,a)` as recursive part, instead of `List (a,a)`, it makes not much sense in my opinion. – Willem Van Onsem Apr 16 at 8:53
• @Norrius It is not that simple, since the `List` type is not a regular list. It recurs as `List (a,a)`, exploiting polymorphic recursion. – chi Apr 16 at 10:19
• Of course it is not a regular list, I'm trying to understand nested datatypes. – Federico Sawady Apr 17 at 14:38

Sure:

``````data List a = EmptyL | ConsL a (List (a,a))

pair f (x, y) = (f x, f y)

nest :: (a -> b) -> List a -> List b
nest f EmptyL       = EmptyL
nest f (ConsL x xs) = ConsL (f x) (nest (pair f) xs)

sumL :: List Int -> Int
sumL EmptyL       = 0
sumL (ConsL x xs) = x + sumL (nest (uncurry (+)) xs)
``````

We have:

``````*Main> sumL EmptyL
0
*Main> sumL (ConsL 1 EmptyL)
1
*Main> sumL (ConsL 1 (ConsL (2, 3) EmptyL))
6
``````

The "magic" is explained in: http://www.cs.ox.ac.uk/jeremy.gibbons/publications/efolds.pdf

For completeness, here's a full definition in terms of the generalized `fold` as described in the paper:

``````import Prelude hiding (sum, fold)

data List a = EmptyL | ConsL (a, List (a, a))

nest :: (a -> b) -> List a -> List b
nest f EmptyL          = EmptyL
nest f (ConsL (x, xs)) = ConsL (f x, nest (pair f) xs)

pair :: (a -> b) -> (a, a) -> (b, b)
pair f (x, y) = (f x, f y)

fold :: a -> ((b, a) -> a) -> ((b, b) -> b) -> List b -> a
fold e f g EmptyL          = e
fold e f g (ConsL (x, xs)) = f (x, fold e f g (nest g xs))

sum :: List Int -> Int
sum = fold 0 (uncurry (+)) (uncurry (+))
``````
• Interestingly, we can also use `deriving Functor` to derive `nest` as `fmap` (I was a bit surprised that the autoderiving engine coped with the polymorphic recursion!). – chi Apr 16 at 10:24
• @chi (Haven't tried but) I think you can even derive `Foldable` and get `sum` for free – Benjamin Hodgson Apr 16 at 10:28
• @BenjaminHodgson Indeed you can! I just tried it, and it works. – chi Apr 16 at 10:31
• That's what I want!! I thought that this was going to be much difficult. – Federico Sawady Apr 17 at 14:30
• @FedericoSawady Foldable is essentially `toList`, and the answer below gives a possible implementation. You might want to put the elements in the list in a different order. – chi Apr 17 at 14:49

The data type you have is not really for lists, more like complete binary trees. You can convert the trees you have to ordinary lists like this:

``````toList :: List a -> [a]
toList EmptyL = []
toList (ConsL x xs) = x:uncurry (++) (unzip (toList xs))
``````

Not the most efficient code and the ordering is a bit arbitrary, but it should work. If you want the sum or anything else you can just use `sum . toList`.

Note that your `lenL` function does not compute the length of the resulting list, but rather the depth of the original tree. If you want the number of elements in the tree you can use `length . toList`.

Since `sum` is a method of `Foldable`, let's see how we'd implement `foldMap`:

``````data List a = EmptyL | ConsL a (List (a,a))

instance Foldable List where
foldMap _ EmptyL = mempty
foldMap f (ConsL a as) = f a <> foldMap (\(x,y) -> f x <> f y) as
``````

We can write `sumL = getSum . foldMap Sum`.