{-# LANGUAGE DefaultSignatures #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE DeriveGeneric #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE PolyKinds #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE Trustworthy #-} {-# LANGUAGE TypeOperators #-} ----------------------------------------------------------------------------- -- | -- Module : Data.Semigroup -- Copyright : (C) 2011-2015 Edward Kmett -- License : BSD-style (see the file LICENSE) -- -- Maintainer : libraries@haskell.org -- Stability : provisional -- Portability : portable -- -- In mathematics, a semigroup is an algebraic structure consisting of a -- set together with an associative binary operation. A semigroup -- generalizes a monoid in that there might not exist an identity -- element. It also (originally) generalized a group (a monoid with all -- inverses) to a type where every element did not have to have an inverse, -- thus the name semigroup. -- -- The use of @(\<\>)@ in this module conflicts with an operator with the same -- name that is being exported by Data.Monoid. However, this package -- re-exports (most of) the contents of Data.Monoid, so to use semigroups -- and monoids in the same package just -- -- > import Data.Semigroup -- -- @since 4.9.0.0 ---------------------------------------------------------------------------- module Data.Semigroup ( Semigroup(..) , stimesMonoid , stimesIdempotent , stimesIdempotentMonoid , mtimesDefault -- * Semigroups , Min(..) , Max(..) , First(..) , Last(..) , WrappedMonoid(..) -- * Re-exported monoids from Data.Monoid , Monoid(..) , Dual(..) , Endo(..) , All(..) , Any(..) , Sum(..) , Product(..) -- * A better monoid for Maybe , Option(..) , option -- * Difference lists of a semigroup , diff , cycle1 -- * ArgMin, ArgMax , Arg(..) , ArgMin , ArgMax ) where import Prelude hiding (foldr1) import Control.Applicative import Control.Monad import Control.Monad.Fix import Data.Bifunctor import Data.Coerce import Data.Data import Data.List.NonEmpty import Data.Monoid (All (..), Any (..), Dual (..), Endo (..), Product (..), Sum (..)) import Data.Monoid (Alt (..)) import qualified Data.Monoid as Monoid import Data.Void import GHC.Generics infixr 6 <> -- | The class of semigroups (types with an associative binary operation). -- -- @since 4.9.0.0 class Semigroup a where -- | An associative operation. -- -- @ -- (a '<>' b) '<>' c = a '<>' (b '<>' c) -- @ -- -- If @a@ is also a 'Monoid' we further require -- -- @ -- ('<>') = 'mappend' -- @ (<>) :: a -> a -> a default (<>) :: Monoid a => a -> a -> a (<>) = mappend -- | Reduce a non-empty list with @\<\>@ -- -- The default definition should be sufficient, but this can be -- overridden for efficiency. -- sconcat :: NonEmpty a -> a sconcat (a :| as) = go a as where go b (c:cs) = b <> go c cs go b [] = b -- | Repeat a value @n@ times. -- -- Given that this works on a 'Semigroup' it is allowed to fail if -- you request 0 or fewer repetitions, and the default definition -- will do so. -- -- By making this a member of the class, idempotent semigroups and monoids can -- upgrade this to execute in /O(1)/ by picking -- @stimes = stimesIdempotent@ or @stimes = stimesIdempotentMonoid@ -- respectively. stimes :: Integral b => b -> a -> a stimes y0 x0 | y0 <= 0 = errorWithoutStackTrace "stimes: positive multiplier expected" | otherwise = f x0 y0 where f x y | even y = f (x <> x) (y `quot` 2) | y == 1 = x | otherwise = g (x <> x) (pred y `quot` 2) x g x y z | even y = g (x <> x) (y `quot` 2) z | y == 1 = x <> z | otherwise = g (x <> x) (pred y `quot` 2) (x <> z) -- | A generalization of 'Data.List.cycle' to an arbitrary 'Semigroup'. -- May fail to terminate for some values in some semigroups. cycle1 :: Semigroup m => m -> m cycle1 xs = xs' where xs' = xs <> xs' instance Semigroup () where _ <> _ = () sconcat _ = () stimes _ _ = () instance Semigroup b => Semigroup (a -> b) where f <> g = \a -> f a <> g a stimes n f e = stimes n (f e) instance Semigroup [a] where (<>) = (++) stimes n x | n < 0 = errorWithoutStackTrace "stimes: [], negative multiplier" | otherwise = rep n where rep 0 = [] rep i = x ++ rep (i - 1) instance Semigroup a => Semigroup (Maybe a) where Nothing <> b = b a <> Nothing = a Just a <> Just b = Just (a <> b) stimes _ Nothing = Nothing stimes n (Just a) = case compare n 0 of LT -> errorWithoutStackTrace "stimes: Maybe, negative multiplier" EQ -> Nothing GT -> Just (stimes n a) instance Semigroup (Either a b) where Left _ <> b = b a <> _ = a stimes = stimesIdempotent instance (Semigroup a, Semigroup b) => Semigroup (a, b) where (a,b) <> (a',b') = (a<>a',b<>b') stimes n (a,b) = (stimes n a, stimes n b) instance (Semigroup a, Semigroup b, Semigroup c) => Semigroup (a, b, c) where (a,b,c) <> (a',b',c') = (a<>a',b<>b',c<>c') stimes n (a,b,c) = (stimes n a, stimes n b, stimes n c) instance (Semigroup a, Semigroup b, Semigroup c, Semigroup d) => Semigroup (a, b, c, d) where (a,b,c,d) <> (a',b',c',d') = (a<>a',b<>b',c<>c',d<>d') stimes n (a,b,c,d) = (stimes n a, stimes n b, stimes n c, stimes n d) instance (Semigroup a, Semigroup b, Semigroup c, Semigroup d, Semigroup e) => Semigroup (a, b, c, d, e) where (a,b,c,d,e) <> (a',b',c',d',e') = (a<>a',b<>b',c<>c',d<>d',e<>e') stimes n (a,b,c,d,e) = (stimes n a, stimes n b, stimes n c, stimes n d, stimes n e) instance Semigroup Ordering where LT <> _ = LT EQ <> y = y GT <> _ = GT stimes = stimesIdempotentMonoid instance Semigroup a => Semigroup (Dual a) where Dual a <> Dual b = Dual (b <> a) stimes n (Dual a) = Dual (stimes n a) instance Semigroup (Endo a) where (<>) = coerce ((.) :: (a -> a) -> (a -> a) -> (a -> a)) stimes = stimesMonoid instance Semigroup All where (<>) = coerce (&&) stimes = stimesIdempotentMonoid instance Semigroup Any where (<>) = coerce (||) stimes = stimesIdempotentMonoid instance Num a => Semigroup (Sum a) where (<>) = coerce ((+) :: a -> a -> a) stimes n (Sum a) = Sum (fromIntegral n * a) instance Num a => Semigroup (Product a) where (<>) = coerce ((*) :: a -> a -> a) stimes n (Product a) = Product (a ^ n) -- | This is a valid definition of 'stimes' for a 'Monoid'. -- -- Unlike the default definition of 'stimes', it is defined for 0 -- and so it should be preferred where possible. stimesMonoid :: (Integral b, Monoid a) => b -> a -> a stimesMonoid n x0 = case compare n 0 of LT -> errorWithoutStackTrace "stimesMonoid: negative multiplier" EQ -> mempty GT -> f x0 n where f x y | even y = f (x `mappend` x) (y `quot` 2) | y == 1 = x | otherwise = g (x `mappend` x) (pred y `quot` 2) x g x y z | even y = g (x `mappend` x) (y `quot` 2) z | y == 1 = x `mappend` z | otherwise = g (x `mappend` x) (pred y `quot` 2) (x `mappend` z) -- | This is a valid definition of 'stimes' for an idempotent 'Monoid'. -- -- When @mappend x x = x@, this definition should be preferred, because it -- works in /O(1)/ rather than /O(log n)/ stimesIdempotentMonoid :: (Integral b, Monoid a) => b -> a -> a stimesIdempotentMonoid n x = case compare n 0 of LT -> errorWithoutStackTrace "stimesIdempotentMonoid: negative multiplier" EQ -> mempty GT -> x -- | This is a valid definition of 'stimes' for an idempotent 'Semigroup'. -- -- When @x <> x = x@, this definition should be preferred, because it -- works in /O(1)/ rather than /O(log n)/. stimesIdempotent :: Integral b => b -> a -> a stimesIdempotent n x | n <= 0 = errorWithoutStackTrace "stimesIdempotent: positive multiplier expected" | otherwise = x instance Semigroup a => Semigroup (Const a b) where (<>) = coerce ((<>) :: a -> a -> a) stimes n (Const a) = Const (stimes n a) instance Semigroup (Monoid.First a) where Monoid.First Nothing <> b = b a <> _ = a stimes = stimesIdempotentMonoid instance Semigroup (Monoid.Last a) where a <> Monoid.Last Nothing = a _ <> b = b stimes = stimesIdempotentMonoid instance Alternative f => Semigroup (Alt f a) where (<>) = coerce ((<|>) :: f a -> f a -> f a) stimes = stimesMonoid instance Semigroup Void where a <> _ = a stimes = stimesIdempotent instance Semigroup (NonEmpty a) where (a :| as) <> ~(b :| bs) = a :| (as ++ b : bs) newtype Min a = Min { getMin :: a } deriving (Eq, Ord, Show, Read, Data, Typeable, Generic, Generic1) instance Bounded a => Bounded (Min a) where minBound = Min minBound maxBound = Min maxBound instance Enum a => Enum (Min a) where succ (Min a) = Min (succ a) pred (Min a) = Min (pred a) toEnum = Min . toEnum fromEnum = fromEnum . getMin enumFrom (Min a) = Min <$> enumFrom a enumFromThen (Min a) (Min b) = Min <$> enumFromThen a b enumFromTo (Min a) (Min b) = Min <$> enumFromTo a b enumFromThenTo (Min a) (Min b) (Min c) = Min <$> enumFromThenTo a b c instance Ord a => Semigroup (Min a) where (<>) = coerce (min :: a -> a -> a) stimes = stimesIdempotent instance (Ord a, Bounded a) => Monoid (Min a) where mempty = maxBound mappend = (<>) instance Functor Min where fmap f (Min x) = Min (f x) instance Foldable Min where foldMap f (Min a) = f a instance Traversable Min where traverse f (Min a) = Min <$> f a instance Applicative Min where pure = Min a <* _ = a _ *> a = a Min f <*> Min x = Min (f x) instance Monad Min where (>>) = (*>) Min a >>= f = f a instance MonadFix Min where mfix f = fix (f . getMin) instance Num a => Num (Min a) where (Min a) + (Min b) = Min (a + b) (Min a) * (Min b) = Min (a * b) (Min a) - (Min b) = Min (a - b) negate (Min a) = Min (negate a) abs (Min a) = Min (abs a) signum (Min a) = Min (signum a) fromInteger = Min . fromInteger newtype Max a = Max { getMax :: a } deriving (Eq, Ord, Show, Read, Data, Typeable, Generic, Generic1) instance Bounded a => Bounded (Max a) where minBound = Max minBound maxBound = Max maxBound instance Enum a => Enum (Max a) where succ (Max a) = Max (succ a) pred (Max a) = Max (pred a) toEnum = Max . toEnum fromEnum = fromEnum . getMax enumFrom (Max a) = Max <$> enumFrom a enumFromThen (Max a) (Max b) = Max <$> enumFromThen a b enumFromTo (Max a) (Max b) = Max <$> enumFromTo a b enumFromThenTo (Max a) (Max b) (Max c) = Max <$> enumFromThenTo a b c instance Ord a => Semigroup (Max a) where (<>) = coerce (max :: a -> a -> a) stimes = stimesIdempotent instance (Ord a, Bounded a) => Monoid (Max a) where mempty = minBound mappend = (<>) instance Functor Max where fmap f (Max x) = Max (f x) instance Foldable Max where foldMap f (Max a) = f a instance Traversable Max where traverse f (Max a) = Max <$> f a instance Applicative Max where pure = Max a <* _ = a _ *> a = a Max f <*> Max x = Max (f x) instance Monad Max where (>>) = (*>) Max a >>= f = f a instance MonadFix Max where mfix f = fix (f . getMax) instance Num a => Num (Max a) where (Max a) + (Max b) = Max (a + b) (Max a) * (Max b) = Max (a * b) (Max a) - (Max b) = Max (a - b) negate (Max a) = Max (negate a) abs (Max a) = Max (abs a) signum (Max a) = Max (signum a) fromInteger = Max . fromInteger -- | 'Arg' isn't itself a 'Semigroup' in its own right, but it can be -- placed inside 'Min' and 'Max' to compute an arg min or arg max. data Arg a b = Arg a b deriving (Show, Read, Data, Typeable, Generic, Generic1) type ArgMin a b = Min (Arg a b) type ArgMax a b = Max (Arg a b) instance Functor (Arg a) where fmap f (Arg x a) = Arg x (f a) instance Foldable (Arg a) where foldMap f (Arg _ a) = f a instance Traversable (Arg a) where traverse f (Arg x a) = Arg x <$> f a instance Eq a => Eq (Arg a b) where Arg a _ == Arg b _ = a == b instance Ord a => Ord (Arg a b) where Arg a _ `compare` Arg b _ = compare a b min x@(Arg a _) y@(Arg b _) | a <= b = x | otherwise = y max x@(Arg a _) y@(Arg b _) | a >= b = x | otherwise = y instance Bifunctor Arg where bimap f g (Arg a b) = Arg (f a) (g b) -- | Use @'Option' ('First' a)@ to get the behavior of -- 'Data.Monoid.First' from "Data.Monoid". newtype First a = First { getFirst :: a } deriving (Eq, Ord, Show, Read, Data, Typeable, Generic, Generic1) instance Bounded a => Bounded (First a) where minBound = First minBound maxBound = First maxBound instance Enum a => Enum (First a) where succ (First a) = First (succ a) pred (First a) = First (pred a) toEnum = First . toEnum fromEnum = fromEnum . getFirst enumFrom (First a) = First <$> enumFrom a enumFromThen (First a) (First b) = First <$> enumFromThen a b enumFromTo (First a) (First b) = First <$> enumFromTo a b enumFromThenTo (First a) (First b) (First c) = First <$> enumFromThenTo a b c instance Semigroup (First a) where a <> _ = a stimes = stimesIdempotent instance Functor First where fmap f (First x) = First (f x) instance Foldable First where foldMap f (First a) = f a instance Traversable First where traverse f (First a) = First <$> f a instance Applicative First where pure x = First x a <* _ = a _ *> a = a First f <*> First x = First (f x) instance Monad First where (>>) = (*>) First a >>= f = f a instance MonadFix First where mfix f = fix (f . getFirst) -- | Use @'Option' ('Last' a)@ to get the behavior of -- 'Data.Monoid.Last' from "Data.Monoid" newtype Last a = Last { getLast :: a } deriving (Eq, Ord, Show, Read, Data, Typeable, Generic, Generic1) instance Bounded a => Bounded (Last a) where minBound = Last minBound maxBound = Last maxBound instance Enum a => Enum (Last a) where succ (Last a) = Last (succ a) pred (Last a) = Last (pred a) toEnum = Last . toEnum fromEnum = fromEnum . getLast enumFrom (Last a) = Last <$> enumFrom a enumFromThen (Last a) (Last b) = Last <$> enumFromThen a b enumFromTo (Last a) (Last b) = Last <$> enumFromTo a b enumFromThenTo (Last a) (Last b) (Last c) = Last <$> enumFromThenTo a b c instance Semigroup (Last a) where _ <> b = b stimes = stimesIdempotent instance Functor Last where fmap f (Last x) = Last (f x) a <$ _ = Last a instance Foldable Last where foldMap f (Last a) = f a instance Traversable Last where traverse f (Last a) = Last <$> f a instance Applicative Last where pure = Last a <* _ = a _ *> a = a Last f <*> Last x = Last (f x) instance Monad Last where (>>) = (*>) Last a >>= f = f a instance MonadFix Last where mfix f = fix (f . getLast) -- | Provide a Semigroup for an arbitrary Monoid. newtype WrappedMonoid m = WrapMonoid { unwrapMonoid :: m } deriving (Eq, Ord, Show, Read, Data, Typeable, Generic, Generic1) instance Monoid m => Semigroup (WrappedMonoid m) where (<>) = coerce (mappend :: m -> m -> m) instance Monoid m => Monoid (WrappedMonoid m) where mempty = WrapMonoid mempty mappend = (<>) instance Bounded a => Bounded (WrappedMonoid a) where minBound = WrapMonoid minBound maxBound = WrapMonoid maxBound instance Enum a => Enum (WrappedMonoid a) where succ (WrapMonoid a) = WrapMonoid (succ a) pred (WrapMonoid a) = WrapMonoid (pred a) toEnum = WrapMonoid . toEnum fromEnum = fromEnum . unwrapMonoid enumFrom (WrapMonoid a) = WrapMonoid <$> enumFrom a enumFromThen (WrapMonoid a) (WrapMonoid b) = WrapMonoid <$> enumFromThen a b enumFromTo (WrapMonoid a) (WrapMonoid b) = WrapMonoid <$> enumFromTo a b enumFromThenTo (WrapMonoid a) (WrapMonoid b) (WrapMonoid c) = WrapMonoid <$> enumFromThenTo a b c -- | Repeat a value @n@ times. -- -- > mtimesDefault n a = a <> a <> ... <> a -- using <> (n-1) times -- -- Implemented using 'stimes' and 'mempty'. -- -- This is a suitable definition for an 'mtimes' member of 'Monoid'. mtimesDefault :: (Integral b, Monoid a) => b -> a -> a mtimesDefault n x | n == 0 = mempty | otherwise = unwrapMonoid (stimes n (WrapMonoid x)) -- | 'Option' is effectively 'Maybe' with a better instance of -- 'Monoid', built off of an underlying 'Semigroup' instead of an -- underlying 'Monoid'. -- -- Ideally, this type would not exist at all and we would just fix the -- 'Monoid' instance of 'Maybe' newtype Option a = Option { getOption :: Maybe a } deriving (Eq, Ord, Show, Read, Data, Typeable, Generic, Generic1) instance Functor Option where fmap f (Option a) = Option (fmap f a) instance Applicative Option where pure a = Option (Just a) Option a <*> Option b = Option (a <*> b) Option Nothing *> _ = Option Nothing _ *> b = b instance Monad Option where Option (Just a) >>= k = k a _ >>= _ = Option Nothing (>>) = (*>) instance Alternative Option where empty = Option Nothing Option Nothing <|> b = b a <|> _ = a instance MonadPlus Option where mzero = Option Nothing mplus = (<|>) instance MonadFix Option where mfix f = Option (mfix (getOption . f)) instance Foldable Option where foldMap f (Option (Just m)) = f m foldMap _ (Option Nothing) = mempty instance Traversable Option where traverse f (Option (Just a)) = Option . Just <$> f a traverse _ (Option Nothing) = pure (Option Nothing) -- | Fold an 'Option' case-wise, just like 'maybe'. option :: b -> (a -> b) -> Option a -> b option n j (Option m) = maybe n j m instance Semigroup a => Semigroup (Option a) where (<>) = coerce ((<>) :: Maybe a -> Maybe a -> Maybe a) stimes _ (Option Nothing) = Option Nothing stimes n (Option (Just a)) = case compare n 0 of LT -> errorWithoutStackTrace "stimes: Option, negative multiplier" EQ -> Option Nothing GT -> Option (Just (stimes n a)) instance Semigroup a => Monoid (Option a) where mempty = Option Nothing mappend = (<>) -- | This lets you use a difference list of a 'Semigroup' as a 'Monoid'. diff :: Semigroup m => m -> Endo m diff = Endo . (<>) instance Semigroup (Proxy s) where _ <> _ = Proxy sconcat _ = Proxy stimes _ _ = Proxy