--- layout: post title: "Typoclassopedia: Exercise solutions" date: 2017-09-27 permalink: typoclassopedia-exercise-solutions/ categories: programming --- I wanted to get proficient in Haskell so I decided to follow [An [Essential] Haskell Reading List](http://www.stephendiehl.com/posts/essential_haskell.html), there I stumbled upon [Typoclassopedia](https://wiki.haskell.org/Typeclassopedia), while the material is great, I couldn't find solutions for the exercises to check against, so I decided I would write my own and hopefully the solutions would get fixed in case I have gone wrong by others. So if you think a solution is wrong, let me know in the comments! In each section below, I left some reference material for the exercises and then the solutions. Functor ========== ## Instances ```haskell instance Functor [] where fmap :: (a -> b) -> [a] -> [b] fmap _ [] = [] fmap g (x:xs) = g x : fmap g xs -- or we could just say fmap = map instance Functor Maybe where fmap :: (a -> b) -> Maybe a -> Maybe b fmap _ Nothing = Nothing fmap g (Just a) = Just (g a) ``` > ((,) e) represents a container which holds an “annotation” of type e along with the actual value it holds. It might be clearer to write it as (e,), by analogy with an operator section like (1+), but that syntax is not allowed in types (although it is allowed in expressions with the TupleSections extension enabled). However, you can certainly think of it as (e,). > ((->) e) (which can be thought of as (e ->); see above), the type of functions which take a value of type e as a parameter, is a Functor. As a container, (e -> a) represents a (possibly infinite) set of values of a, indexed by values of e. Alternatively, and more usefully, ((->) e) can be thought of as a context in which a value of type e is available to be consulted in a read-only fashion. This is also why ((->) e) is sometimes referred to as the reader monad; more on this later. ### Exercises 1. Implement `Functor` instances for `Either e` and `((->) e)`. **Solution**: ```haskell instance Functor (Either e) where fmap _ (Left e) = Left e fmap g (Right a) = Right (g a) instance Functor ((->) e) where fmap g f = g . f ``` 2. Implement `Functor` instances for `((,) e)` and for `Pair`, defined as below. Explain their similarities and differences. **Solution**: ```haskell instance Functor ((,) e) where fmap g (a, b) = (a, g b) data Pair a = Pair a a instance Functor Pair where fmap g (Pair a b) = Pair (g a) (g b) ``` Their similarity is in the fact that they both represent types of two values. Their difference is that `((,) e)` (tuples of two) can have values of different types (kind of `(,)` is `* -> *`) while both values of `Pair` have the same type `a`, so `Pair` has kind `*`. 3. Implement a `Functor` instance for the type `ITree`, defined as ```haskell data ITree a = Leaf (Int -> a) | Node [ITree a] ``` **Solution**: ```haskell instance Functor ITree where fmap g (Leaf f) = Leaf (g . f) fmap g (Node xs) = Node (fmap (fmap g) xs) ``` To test this instance, I defined a function to apply the tree to an `Int`: ```haskell applyTree :: ITree a -> Int -> [a] applyTree (Leaf g) i = [g i] applyTree (Node []) _ = [] applyTree (Node (x:xs)) i = applyTree x i ++ applyTree (Node xs) i ``` This is not a standard tree traversing algorithm, I just wanted it to be simple for testing. Now test the instance: ```haskell λ: let t = Node [Node [Leaf (+5), Leaf (+1)], Leaf (*2)] λ: applyTree t 1 [6,2,2] λ: applyTree (fmap id t) 1 [6,2,2] λ: applyTree (fmap (+10) t) 1 [16, 12, 12] ``` 4. Give an example of a type of kind `* -> *` which cannot be made an instance of `Functor` (without using `undefined`). I don't know the answer to this one yet! 6. Is this statement true or false? > The composition of two `Functor`s is also a `Functor`. If false, give a counterexample; if true, prove it by exhibiting some appropriate Haskell code. **Solution**: It's true, and can be proved by the following function: ```haskell ffmap :: (Functor f, Functor j) => (a -> b) -> f (j a) -> f (j b) ffmap g = fmap (fmap g) ``` You can test this on arbitrary compositions of `Functor`s: ```haskell main = do let result :: Maybe (Either String Int) = ffmap (+ 2) (Just . Right $ 5) print result -- (Just (Right 7)) ``` ## Functor Laws ```haskell fmap id = id fmap (g . h) = (fmap g) . (fmap h) ``` ### Exercises 1. Although it is not possible for a Functor instance to satisfy the first Functor law but not the second (excluding undefined), the reverse is possible. Give an example of a (bogus) Functor instance which satisfies the second law but not the first. **Solution**: This is easy, consider this instance: ```haskell instance Functor [] where fmap _ [] = [1] fmap g (x:xs) = g x: fmap g xs ``` Then, you can test the first and second laws: ```haskell λ: fmap id [] -- [1], breaks the first law λ: fmap ((+1) . (+2)) [1,2] -- [4, 5], second law holds λ: fmap (+1) . fmap (+2) $ [1,2] -- [4, 5] ``` 2. Which laws are violated by the evil Functor instance for list shown above: both laws, or the first law alone? Give specific counterexamples. ```haskell -- Evil Functor instance instance Functor [] where fmap :: (a -> b) -> [a] -> [b] fmap _ [] = [] fmap g (x:xs) = g x : g x : fmap g xs ``` **Solution**: The instance defined breaks the first law (`fmap id [1] -- [1,1]`), but holds for the second law.