# What should a Traversable instance look like for a Tree datatype with a nested Maybe value?

I have a Haskell exam in three days, so I thought I should practice a little and pulled up past exams, one of which features the following Tree datatype:

``````data Tree a = Leaf1 a | Leaf2 a a | Node (Tree a) (Maybe (Tree a)) deriving (Eq, Ord, Show)
``````

It didn't seem that challenging at first, but then I realized I have to write a Traversable instance for this Tree. Dealing with the leaves were easy enough:

``````instance Traversable Tree where
traverse f (Leaf1 a)   = Leaf1 <\$> f a
traverse f (Leaf2 a b) = Leaf2 <\$> f a <*> f b
``````

However, I started running into problems with the Node.

``````  traverse f (Node t Nothing)  = Node <\$> traverse f t <*> Nothing
traverse f (Node l (Just r)) = Node <\$> traverse f l <*> Just (traverse f r)
``````

Naturally, these don't work, and I can't wrap my head around what should come after the second <*>. I tried using holes, but the messages given to me by ghci didn't help much (I get that the problem is with types, but I have no idea how I'm supposed to fix it).

Here's the error message I got when I tried to compile it:

``````* Couldn't match type `f' with `Maybe'
`f' is a rigid type variable bound by
the type signature for:
traverse :: forall (f :: * -> *) a b.
Applicative f =>
(a -> f b) -> Tree a -> f (Tree b)
at exam.hs:92:3-10
Expected type: f (Maybe (Tree b))
Actual type: Maybe (Maybe (Tree b))
* In the second argument of `(<*>)', namely `Nothing'
In the expression: Node <\$> traverse f t <*> Nothing
In an equation for `traverse':
traverse f (Node t Nothing) = Node <\$> traverse f t <*> Nothing
* Relevant bindings include
f :: a -> f b (bound at exam.hs:94:12)
traverse :: (a -> f b) -> Tree a -> f (Tree b)
(bound at exam.hs:92:3)
|
94 |   traverse f (Node t Nothing)  = Node <\$> traverse f t <*> Nothing
|                                                            ^^^^^^^
``````

Could someone please give me some pointers or a possible fix for this issue?

• I'm not sure if it's right (don't have any experience writing Traversable instances for non-trivial data types), but using `pure Nothing` instead of `Nothing` would avoid this type error. – Robin Zigmond Jun 1 at 16:55

`traverse` lets you apply a "function with an effect" to every "slot" of a data structure, maintaining the structure's shape. It has the type:

``````traverse :: Applicative f => (a -> f b) -> t a -> f (t b)
``````

It relies crucially on the fact that the type of the "effects" is an `Applicative`. What operations does `Applicatve` provide?

• it lets us lift pure functions and apply them to effectful actions with `<\$>`.
• it lets us combine effectful actions with `(<*>) :: f (a -> b) -> f a -> f b`. Notice that the second parameter is an effectful action, not a pure value.
• it lets us take any pure value and put it in an effectful context, using `pure :: a -> f a`.

Now, when the node has a `Nothing`, there's no effect to perform because there aren't any values, but the `<*>` still requires an effectful action on the right. We can use `pure Nothing` to make the types fit.

When the node has a `Just t`, we can `traverse` the subtree `t` of type `Tree a` with the function `a -> f b` and end up with an action `f (Tree b)`. But the `<*>` is actually expecting an `f (Maybe (Tree b))`. The lifted `Node` constructor makes us expect that. What can we do?

The solution is to lift the `Just` constructor into the action using `<\$>`, which is another name for `fmap`.

Notice that we haven't changed the overall "shape" of the value: the `Nothing` is still `Nothing`, the `Just` is still `Just`. The structure of the subtrees didn't change either: we `traverse`d them recursively but didn't modify them otherwise.

• Thank you, your explanation was easy to follow and thanks to you I got the code to work! – kleinerbur Jun 1 at 17:35

The short answer is that you need to use `traverse` to get inside the `Maybe`.

The `Traversable` and `Foldable` instances for a type often have a similar structure to its `Functor` instance. Whereas `fmap` maps a pure function over a structure, combining the results back up with the pure constructors:

``````instance Functor Tree where
fmap f (Leaf1 a) = Leaf1 (f a)
fmap f (Leaf2 a1 a2) = Leaf2 (f a1) (f a2)
fmap f (Node ta mta) = Node (fmap f ta) (fmap (fmap f) mta)
``````

Note the `(fmap (fmap f) mta)`: the outer `fmap` maps over the `Maybe`, while the inner one maps over the `Tree`:

``````(fmap
:: (Tree a -> Tree b)
-> Maybe (Tree a) -> Maybe (Tree b))
((fmap
:: (a -> b)
-> Tree a -> Tree b)
f)
mta
``````

`traverse` instead maps an effectful function over the structure, and correspondingly lifts the constructors into `Applicative` with the `<\$>` and `<*>` operators:

``````instance Traversable Tree where
traverse f (Leaf1 a) = Leaf1 <\$> f a
traverse f (Leaf2 a1 a2) = Leaf2 <\$> f a1 <*> f a2
traverse f (Node ta mta) = Node <\$> traverse f ta <*> traverse (traverse f) mta
``````

Again, notice that we must `traverse` the `Maybe`, and within that, `traverse` the `Tree`, but instead of a pure function `a -> b`, we just have an effectful function `a -> f b`, given `Applicative f`:

``````(traverse
:: (Tree a -> f (Tree b))
-> Maybe (Tree a) -> f (Maybe (Tree b)))
((traverse
:: (a -> f b)
-> Tree a -> f (Tree b))
f)
mta
``````

Likewise, `foldMap` has a similar structure, but instead of reconstructing the data type, it combines results using a `Monoid` instance:

``````instance Foldable Tree where
foldMap f (Leaf1 a) = f a
foldMap f (Leaf2 a1 a2) = f a1 <> f a2
foldMap f (Node ta mta) = foldMap f ta <> foldMap (foldMap f) mta
``````

And here’s a simple example usage of `traverse`:

``````> traverse (\ x -> print x *> pure (x + 1)) (Node (Leaf1 10) (Just (Leaf2 20 30)))
10
20
30
Node (Leaf1 11) (Just (Leaf2 21 31))
``````

With the `DeriveFoldable`, `DeriveFunctor`, and `DeriveTraversable` extensions, you may add a `deriving (Foldable, Functor, Traversable)` clause to a data type and use the `-ddump-deriv` flag of GHC to see the generated code.