{-# LANGUAGE CPP #-} {- | Free groups * https://en.wikipedia.org/wiki/Free_group * https://ncatlab.org/nlab/show/Nielsen-Schreier+theorem -} module Data.Group.Free ( FreeGroup , fromDList , toDList , normalize , FreeGroupL , fromList , toList , normalizeL ) where import Control.Monad (ap) import Data.DList (DList) import qualified Data.DList as DList import Data.Group (Group (..)) import Data.Semigroup (Semigroup (..)) import Data.Algebra.Free ( AlgebraType , AlgebraType0 , FreeAlgebra (..) , proof ) -- | -- Free group generated by a type @a@. Internally it's represented by a list -- @[Either a a]@ where inverse is given by: -- -- @ -- inverse (FreeGroup [a]) = FreeGroup [either Right Left a] -- @ -- -- It is a monad on a full subcategory of @Hask@ which constists of types which -- satisfy the @'Eq'@ constraint. -- -- @'FreeGroup' a@ is isomorphic with @'Free' Group a@ (but the latter does not -- require @Eq@ constraint, hence is more general). newtype FreeGroup a = FreeGroup { runFreeGroup :: DList (Either a a) } deriving (Eq, Ord, Show) instance Functor FreeGroup where fmap f (FreeGroup as) = FreeGroup $ fmap (either (Left . f) (Right . f)) as instance Applicative FreeGroup where pure = returnFree (<*>) = ap instance Monad FreeGroup where return a = FreeGroup $ DList.singleton (Right a) FreeGroup as >>= f = FreeGroup $ as >>= runFreeGroup . either f f -- | -- Normalize a list, i.e. remove adjusten inverses from a word, i.e. -- @ab⁻¹ba⁻¹c = c@ -- -- Complexity: @O(n)@ normalize :: Eq a => DList (Either a a) -> DList (Either a a) normalize = DList.foldr fn DList.empty where fn a as = case as of DList.Nil -> DList.singleton a _ -> let b = DList.head as bs = DList.tail as in case (a, b) of (Left x, Right y) | x == y -> bs (Right x, Left y) | x == y -> bs _ -> DList.cons a as -- | -- Smart constructor which normalizes a list. fromDList :: Eq a => DList (Either a a) -> FreeGroup a fromDList = FreeGroup . normalize toDList :: FreeGroup a -> DList (Either a a) toDList = runFreeGroup instance Eq a => Semigroup (FreeGroup a) where FreeGroup as <> FreeGroup bs = FreeGroup $ normalize (as `DList.append` bs) instance Eq a => Monoid (FreeGroup a) where mempty = FreeGroup DList.empty #if __GLASGOW_HASKELL__ <= 822 mappend = (<>) #endif instance Eq a => Group (FreeGroup a) where invert (FreeGroup as) = FreeGroup $ foldl (\acu a -> either Right Left a `DList.cons` acu) DList.empty as type instance AlgebraType0 FreeGroup a = Eq a type instance AlgebraType FreeGroup g = (Eq g, Group g) instance FreeAlgebra FreeGroup where returnFree a = FreeGroup (DList.singleton (Right a)) foldMapFree _ (FreeGroup DList.Nil) = mempty foldMapFree f (FreeGroup as) = let a' = DList.head as as' = DList.tail as in either (invert . f) f a' `mappend` foldMapFree f (FreeGroup as') codom = proof forget = proof -- | -- Free group in the class of groups which multiplication is strict on the left, i.e. -- -- prop> undefined <> a = undefined newtype FreeGroupL a = FreeGroupL { runFreeGroupL :: [Either a a] } deriving (Show, Eq, Ord) normalizeL :: Eq a => [Either a a] -> [Either a a] normalizeL = DList.toList . normalize . DList.fromList -- | -- Smart constructors fromList :: Eq a => [Either a a] -> FreeGroupL a fromList = FreeGroupL . normalizeL toList :: FreeGroupL a -> [Either a a] toList = runFreeGroupL instance Eq a => Semigroup (FreeGroupL a) where FreeGroupL as <> FreeGroupL bs = FreeGroupL $ normalizeL (as ++ bs) instance Eq a => Monoid (FreeGroupL a) where mempty = FreeGroupL [] #if __GLASGOW_HASKELL__ <= 822 mappend = (<>) #endif instance Eq a => Group (FreeGroupL a) where invert (FreeGroupL as) = FreeGroupL $ foldl (\acu a -> either Right Left a : acu) [] as type instance AlgebraType0 FreeGroupL a = Eq a type instance AlgebraType FreeGroupL g = (Eq g, Group g) instance FreeAlgebra FreeGroupL where returnFree a = FreeGroupL [Right a] foldMapFree _ (FreeGroupL []) = mempty foldMapFree f (FreeGroupL (a : as)) = either (invert . f) f a `mappend` foldMapFree f (FreeGroupL as) codom = proof forget = proof