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author | William Carroll <wpcarro@gmail.com> | 2020-07-11T10·25+0100 |
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committer | William Carroll <wpcarro@gmail.com> | 2020-07-11T10·25+0100 |
commit | 3665ea457bf30e4a0de7733608e3e16c8e18090c (patch) | |
tree | fdb8e99eef3e8a3b5946c454d74dd2a8fbfeeaf7 /scratch/haskell-programming-from-first-principles | |
parent | 5e81144622d66ca011da28fb414d2a8bfe71cc7e (diff) |
Partially complete some of the exercises for Composing Types
I believe there are two exercises sets in the "Composing Types" chapter. Here are *some* of my answers so far... I'm having trouble implementing Foldable for Compose. I was able to implement a version of it by adding the (Functor f) constraint to the instance signature, but I think I cheated. I will revisit these problems as well as the earlier exercises later.
Diffstat (limited to 'scratch/haskell-programming-from-first-principles')
-rw-r--r-- | scratch/haskell-programming-from-first-principles/composing-types.hs | 75 |
1 files changed, 75 insertions, 0 deletions
diff --git a/scratch/haskell-programming-from-first-principles/composing-types.hs b/scratch/haskell-programming-from-first-principles/composing-types.hs new file mode 100644 index 000000000000..378cfb7ceae6 --- /dev/null +++ b/scratch/haskell-programming-from-first-principles/composing-types.hs @@ -0,0 +1,75 @@ +module ComposingTypesScratch where + +import Data.Function ((&)) +import Data.Bifunctor + +import qualified Data.Foldable as F + +-------------------------------------------------------------------------------- + +newtype Identity a = + Identity { getIdentity :: a } + deriving (Eq, Show) + +newtype Compose f g a = + Compose { getCompose :: f (g a) } + deriving (Eq, Show) + +-------------------------------------------------------------------------------- + +instance (Functor f, Functor g) => Functor (Compose f g) where + fmap f (Compose getCompose) = Compose $ (fmap . fmap) f getCompose + +instance (Applicative f, Applicative g) => Applicative (Compose f g) where + pure x = x & pure & pure & Compose + fgf <*> fga = undefined + +-------------------------------------------------------------------------------- + +instance (Foldable f, Foldable g) => Foldable (Compose f g) where + foldMap toMonoid x = undefined + +instance (Traversable f, Traversable g) => Traversable (Compose f g) where + traverse = undefined + +-------------------------------------------------------------------------------- + +data Deux a b = Deux a b deriving (Show, Eq) + +instance Bifunctor Deux where + bimap f g (Deux x y) = Deux (f x) (g y) + +data Const a b = Const a deriving (Show, Eq) + +instance Bifunctor Const where + bimap f _ (Const x) = Const (f x) + +data Drei a b c = Drei a b c deriving (Show, Eq) + +instance Bifunctor (Drei a) where + bimap f g (Drei x y z) = Drei x (f y) (g z) + +data SuperDrei a b c = SuperDrei a b deriving (Show, Eq) + +instance Bifunctor (SuperDrei a) where + bimap f g (SuperDrei x y) = SuperDrei x (f y) + +data SemiDrei a b c = SemiDrei a deriving (Show, Eq) + +instance Bifunctor (SemiDrei a) where + bimap _ _ (SemiDrei x) = SemiDrei x + +data Quadriceps a b c d = Quadzzz a b c d + +instance Bifunctor (Quadriceps a b) where + bimap f g (Quadzzz w x y z) = Quadzzz w x (f y) (g z) + +-- | Analogue for Either +data LeftRight a b + = Failure a + | Success b + deriving (Show, Eq) + +instance Bifunctor LeftRight where + bimap f _ (Failure x) = Failure (f x) + bimap _ g (Success y) = Success (g y) |