-- Hoogle documentation, generated by Haddock
-- See Hoogle, http://www.haskell.org/hoogle/
-- | Semigroupoids: Category sans id
--
-- Provides a wide array of (semi)groupoids and operations for working
-- with them.
--
-- A Semigroupoid is a Category without the requirement of
-- identity arrows for every object in the category.
--
-- A Category is any Semigroupoid for which the Yoneda
-- lemma holds.
--
-- When working with comonads you often have the <*>
-- portion of an Applicative, but not the pure. This
-- was captured in Uustalu and Vene's "Essence of Dataflow Programming"
-- in the form of the ComonadZip class in the days before
-- Applicative. Apply provides a weaker invariant, but for the
-- comonads used for data flow programming (found in the streams
-- package), this invariant is preserved. Applicative function
-- composition forms a semigroupoid.
--
-- Similarly many structures are nearly a comonad, but not quite, for
-- instance lists provide a reasonable extend operation in the
-- form of tails, but do not always contain a value.
--
-- Ideally the following relationships would hold:
--
--
-- Foldable ----> Traversable <--- Functor ------> Alt ---------> Plus Semigroupoid
-- | | | | |
-- v v v v v
-- Foldable1 ---> Traversable1 Apply --------> Applicative -> Alternative Category
-- | | | |
-- v v v v
-- Bind ---------> Monad -------> MonadPlus Arrow
--
--
-- Apply, Bind, and Extend (not shown) give rise the Static, Kleisli and
-- Cokleisli semigroupoids respectively.
--
-- This lets us remove many of the restrictions from various monad
-- transformers as in many cases the binding operation or
-- <*> operation does not require them.
--
-- Finally, to work with these weaker structures it is beneficial to have
-- containers that can provide stronger guarantees about their contents,
-- so versions of Traversable and Foldable that can be
-- folded with just a Semigroup are added.
@package semigroupoids
@version 4.2
-- | Placeholders for missing instances of Traversable, until base catches
-- up and adds them
module Data.Traversable.Instances
instance Traversable (Const m)
instance Foldable (Const m)
instance Traversable (Either a)
instance Foldable (Either a)
instance Traversable ((,) b)
instance Foldable ((,) b)
module Data.Functor.Extend
class Functor w => Extend w where extended f = fmap f . duplicated duplicated = extended id
duplicated :: Extend w => w a -> w (w a)
extended :: Extend w => (w a -> b) -> w a -> w b
instance [safe] Extend NonEmpty
instance [safe] Extend w => Extend (IdentityT w)
instance [safe] Extend Identity
instance [safe] (Extend w, Semigroup m) => Extend (TracedT m w)
instance [safe] Extend w => Extend (StoreT s w)
instance [safe] Extend w => Extend (EnvT e w)
instance [safe] (Extend f, Extend g) => Extend (Coproduct f g)
instance [safe] Extend Tree
instance [safe] Extend Seq
instance [safe] Semigroup m => Extend ((->) m)
instance [safe] Extend ((,) e)
instance [safe] Extend (Either a)
instance [safe] Extend Maybe
instance [safe] Extend []
-- | NB: The definitions exported through Data.Functor.Apply need to
-- be included here because otherwise the instances for the transformers
-- package have orphaned heads.
module Data.Functor.Bind
-- | The Functor class is used for types that can be mapped over.
-- Instances of Functor should satisfy the following laws:
--
--
-- fmap id == id
-- fmap (f . g) == fmap f . fmap g
--
--
-- The instances of Functor for lists, Maybe and IO
-- satisfy these laws.
class Functor (f :: * -> *)
fmap :: Functor f => (a -> b) -> f a -> f b
(<$) :: Functor f => a -> f b -> f a
-- | An infix synonym for fmap.
(<$>) :: Functor f => (a -> b) -> f a -> f b
-- | Replace the contents of a functor uniformly with a constant value.
($>) :: Functor f => f a -> b -> f b
-- | A strong lax semi-monoidal endofunctor. This is equivalent to an
-- Applicative without pure.
--
-- Laws:
--
--
-- associative composition: (.) <$> u <.> v <.> w = u <.> (v <.> w)
--
class Functor f => Apply f where a .> b = const id <$> a <.> b a <. b = const <$> a <.> b
(<.>) :: Apply f => f (a -> b) -> f a -> f b
(.>) :: Apply f => f a -> f b -> f b
(<.) :: Apply f => f a -> f b -> f a
-- | A variant of <.> with the arguments reversed.
(<..>) :: Apply w => w a -> w (a -> b) -> w b
-- | Lift a binary function into a comonad with zipping
liftF2 :: Apply w => (a -> b -> c) -> w a -> w b -> w c
-- | Lift a ternary function into a comonad with zipping
liftF3 :: Apply w => (a -> b -> c -> d) -> w a -> w b -> w c -> w d
-- | Wrap an Applicative to be used as a member of Apply
newtype WrappedApplicative f a
WrapApplicative :: f a -> WrappedApplicative f a
unwrapApplicative :: WrappedApplicative f a -> f a
-- | Transform a Apply into an Applicative by adding a unit.
newtype MaybeApply f a
MaybeApply :: Either (f a) a -> MaybeApply f a
runMaybeApply :: MaybeApply f a -> Either (f a) a
-- | A Monad sans return.
--
-- Minimal definition: Either join or >>-
--
-- If defining both, then the following laws (the default definitions)
-- must hold:
--
--
-- join = (>>- id)
-- m >>- f = join (fmap f m)
--
--
-- Laws:
--
--
-- induced definition of <.>: f <.> x = f >>- (<$> x)
--
--
-- Finally, there are two associativity conditions:
--
--
-- associativity of (>>-): (m >>- f) >>- g == m >>- (\x -> f x >>- g)
-- associativity of join: join . join = join . fmap join
--
--
-- These can both be seen as special cases of the constraint that
--
--
-- associativity of (->-): (f ->- g) ->- h = f ->- (g ->- h)
--
class Apply m => Bind m where m >>- f = join (fmap f m) join = (>>- id)
(>>-) :: Bind m => m a -> (a -> m b) -> m b
join :: Bind m => m (m a) -> m a
(-<<) :: Bind m => (a -> m b) -> m a -> m b
(-<-) :: Bind m => (b -> m c) -> (a -> m b) -> a -> m c
(->-) :: Bind m => (a -> m b) -> (b -> m c) -> a -> m c
apDefault :: Bind f => f (a -> b) -> f a -> f b
returning :: Functor f => f a -> (a -> b) -> f b
instance Bind Tree
instance Bind Seq
instance Bind IntMap
instance Ord k => Bind (Map k)
instance Bind (ContT r m)
instance (Bind m, Semigroup w) => Bind (RWST r w s m)
instance (Bind m, Semigroup w) => Bind (RWST r w s m)
instance Bind m => Bind (StateT s m)
instance Bind m => Bind (StateT s m)
instance (Bind m, Semigroup w) => Bind (WriterT w m)
instance (Bind m, Semigroup w) => Bind (WriterT w m)
instance Bind m => Bind (ReaderT e m)
instance (Bind m, Monad m) => Bind (ErrorT e m)
instance (Bind m, Monad m) => Bind (ListT m)
instance (Bind m, Monad m) => Bind (MaybeT m)
instance Monad m => Bind (WrappedMonad m)
instance Bind m => Bind (IdentityT m)
instance Bind Identity
instance Bind Option
instance Bind Maybe
instance Bind IO
instance Bind NonEmpty
instance Bind []
instance Bind ((->) m)
instance (Bind f, Bind g) => Bind (Product f g)
instance Bind (Either a)
instance Semigroup m => Bind ((,) m)
instance Apply (Cokleisli w a)
instance Comonad f => Comonad (MaybeApply f)
instance Extend f => Extend (MaybeApply f)
instance Apply f => Applicative (MaybeApply f)
instance Apply f => Apply (MaybeApply f)
instance Functor f => Functor (MaybeApply f)
instance Alternative f => Alternative (WrappedApplicative f)
instance Applicative f => Applicative (WrappedApplicative f)
instance Applicative f => Apply (WrappedApplicative f)
instance Functor f => Functor (WrappedApplicative f)
instance Apply w => Apply (TracedT m w)
instance (Apply w, Semigroup s) => Apply (StoreT s w)
instance (Semigroup e, Apply w) => Apply (EnvT e w)
instance Apply (ContT r m)
instance (Bind m, Semigroup w) => Apply (RWST r w s m)
instance (Bind m, Semigroup w) => Apply (RWST r w s m)
instance Bind m => Apply (StateT s m)
instance Bind m => Apply (StateT s m)
instance (Apply m, Semigroup w) => Apply (WriterT w m)
instance (Apply m, Semigroup w) => Apply (WriterT w m)
instance Apply m => Apply (ListT m)
instance Apply m => Apply (ReaderT e m)
instance (Bind m, Monad m) => Apply (ErrorT e m)
instance (Bind m, Monad m) => Apply (MaybeT m)
instance Apply Tree
instance Apply Seq
instance Apply IntMap
instance Ord k => Apply (Map k)
instance Arrow a => Apply (WrappedArrow a b)
instance Monad m => Apply (WrappedMonad m)
instance Apply w => Apply (IdentityT w)
instance Apply Identity
instance Apply Option
instance Apply Maybe
instance Apply IO
instance Apply []
instance Apply ZipList
instance Apply ((->) m)
instance Semigroup m => Apply (Const m)
instance Apply (Either a)
instance Apply NonEmpty
instance Semigroup m => Apply ((,) m)
instance (Apply f, Apply g) => Apply (Product f g)
instance (Apply f, Apply g) => Apply (Compose f g)
module Data.Functor.Bind.Trans
-- | A subset of monad transformers can transform any Bind as well.
class MonadTrans t => BindTrans t
liftB :: (BindTrans t, Bind b) => b a -> t b a
instance BindTrans (ContT r)
instance (Semigroup w, Monoid w) => BindTrans (RWST r w s)
instance (Semigroup w, Monoid w) => BindTrans (RWST r w s)
instance BindTrans (StateT s)
instance BindTrans (StateT s)
instance (Semigroup w, Monoid w) => BindTrans (WriterT w)
instance (Semigroup w, Monoid w) => BindTrans (WriterT w)
instance BindTrans (ReaderT e)
instance BindTrans IdentityT
-- | A semigroupoid satisfies all of the requirements to be a Category
-- except for the existence of identity arrows.
module Data.Semigroupoid
-- | Category sans id
class Semigroupoid c
o :: Semigroupoid c => c j k -> c i j -> c i k
newtype WrappedCategory k a b
WrapCategory :: k a b -> WrappedCategory k a b
unwrapCategory :: WrappedCategory k a b -> k a b
newtype Semi m a b
Semi :: m -> Semi m a b
getSemi :: Semi m a b -> m
instance Monoid m => Category (Semi m)
instance Semigroup m => Semigroupoid (Semi m)
instance Category k => Category (WrappedCategory k)
instance Category k => Semigroupoid (WrappedCategory k)
instance Semigroupoid Op
instance Extend w => Semigroupoid (Cokleisli w)
instance Bind m => Semigroupoid (Kleisli m)
instance Semigroupoid (,)
instance Semigroupoid (->)
-- | A semigroupoid satisfies all of the requirements to be a Category
-- except for the existence of identity arrows.
module Data.Semigroupoid.Dual
newtype Dual k a b
Dual :: k b a -> Dual k a b
getDual :: Dual k a b -> k b a
instance Category k => Category (Dual k)
instance Semigroupoid k => Semigroupoid (Dual k)
module Data.Groupoid
-- | semigroupoid with inverses. This technically should be a category with
-- inverses, except we need to use Ob to define the valid objects for the
-- category
class Semigroupoid k => Groupoid k
inv :: Groupoid k => k a b -> k b a
instance Groupoid k => Groupoid (Dual k)
module Data.Isomorphism
data Iso k a b
Iso :: k a b -> k b a -> Iso k a b
embed :: Iso k a b -> k a b
project :: Iso k a b -> k b a
instance Category k => Category (Iso k)
instance Semigroupoid k => Groupoid (Iso k)
instance Semigroupoid k => Semigroupoid (Iso k)
module Data.Semigroupoid.Product
data Product j k a b
Pair :: j a b -> k a' b' -> Product j k (a, a') (b, b')
distributeDualProduct :: Dual (Product j k) a b -> Product (Dual j) (Dual k) a b
factorDualProduct :: Product (Dual j) (Dual k) a b -> Dual (Product j k) a b
instance (Groupoid j, Groupoid k) => Groupoid (Product j k)
instance (Semigroupoid j, Semigroupoid k) => Semigroupoid (Product j k)
module Data.Semigroupoid.Coproduct
data L a
data R a
data Coproduct j k a b
L :: j a b -> Coproduct j k (L a) (L b)
R :: k a b -> Coproduct j k (R a) (R b)
distributeDualCoproduct :: Dual (Coproduct j k) a b -> Coproduct (Dual j) (Dual k) a b
factorDualCoproduct :: Coproduct (Dual j) (Dual k) a b -> Dual (Coproduct j k) a b
instance (Groupoid j, Groupoid k) => Groupoid (Coproduct j k)
instance (Semigroupoid j, Semigroupoid k) => Semigroupoid (Coproduct j k)
module Data.Semigroupoid.Ob
class Semigroupoid k => Ob k a
semiid :: Ob k a => k a a
instance Ob (->) a
instance (Extend w, Comonad w) => Ob (Cokleisli w) a
instance (Bind m, Monad m) => Ob (Kleisli m) a
instance (Semigroupoid l, Ob r a) => Ob (Coproduct l r) (R a)
instance (Ob l a, Semigroupoid r) => Ob (Coproduct l r) (L a)
instance (Ob l a, Ob r b) => Ob (Product l r) (a, b)
module Data.Functor.Apply
-- | The Functor class is used for types that can be mapped over.
-- Instances of Functor should satisfy the following laws:
--
--
-- fmap id == id
-- fmap (f . g) == fmap f . fmap g
--
--
-- The instances of Functor for lists, Maybe and IO
-- satisfy these laws.
class Functor (f :: * -> *)
fmap :: Functor f => (a -> b) -> f a -> f b
(<$) :: Functor f => a -> f b -> f a
-- | An infix synonym for fmap.
(<$>) :: Functor f => (a -> b) -> f a -> f b
-- | Replace the contents of a functor uniformly with a constant value.
($>) :: Functor f => f a -> b -> f b
-- | A strong lax semi-monoidal endofunctor. This is equivalent to an
-- Applicative without pure.
--
-- Laws:
--
--
-- associative composition: (.) <$> u <.> v <.> w = u <.> (v <.> w)
--
class Functor f => Apply f where a .> b = const id <$> a <.> b a <. b = const <$> a <.> b
(<.>) :: Apply f => f (a -> b) -> f a -> f b
(.>) :: Apply f => f a -> f b -> f b
(<.) :: Apply f => f a -> f b -> f a
-- | A variant of <.> with the arguments reversed.
(<..>) :: Apply w => w a -> w (a -> b) -> w b
-- | Lift a binary function into a comonad with zipping
liftF2 :: Apply w => (a -> b -> c) -> w a -> w b -> w c
-- | Lift a ternary function into a comonad with zipping
liftF3 :: Apply w => (a -> b -> c -> d) -> w a -> w b -> w c -> w d
-- | Wrap an Applicative to be used as a member of Apply
newtype WrappedApplicative f a
WrapApplicative :: f a -> WrappedApplicative f a
unwrapApplicative :: WrappedApplicative f a -> f a
-- | Transform a Apply into an Applicative by adding a unit.
newtype MaybeApply f a
MaybeApply :: Either (f a) a -> MaybeApply f a
runMaybeApply :: MaybeApply f a -> Either (f a) a
module Data.Semigroup.Foldable
class Foldable t => Foldable1 t where foldMap1 f = maybe (error "foldMap1") id . getOption . foldMap (Option . Just . f) fold1 = foldMap1 id
fold1 :: (Foldable1 t, Semigroup m) => t m -> m
foldMap1 :: (Foldable1 t, Semigroup m) => (a -> m) -> t a -> m
traverse1_ :: (Foldable1 t, Apply f) => (a -> f b) -> t a -> f ()
for1_ :: (Foldable1 t, Apply f) => t a -> (a -> f b) -> f ()
sequenceA1_ :: (Foldable1 t, Apply f) => t (f a) -> f ()
-- | Usable default for foldMap, but only if you define foldMap1 yourself
foldMapDefault1 :: (Foldable1 t, Monoid m) => (a -> m) -> t a -> m
instance Functor f => Functor (Act f)
instance Apply f => Semigroup (Act f a)
instance Foldable1 ((,) a)
instance Foldable1 NonEmpty
instance (Foldable1 f, Foldable1 g) => Foldable1 (Coproduct f g)
instance (Foldable1 f, Foldable1 g) => Foldable1 (Product f g)
instance (Foldable1 f, Foldable1 g) => Foldable1 (Compose f g)
instance Foldable1 m => Foldable1 (IdentityT m)
instance Foldable1 Identity
instance Foldable1 Tree
module Data.Semigroup.Traversable
class (Foldable1 t, Traversable t) => Traversable1 t where sequence1 = traverse1 id traverse1 f = sequence1 . fmap f
traverse1 :: (Traversable1 t, Apply f) => (a -> f b) -> t a -> f (t b)
sequence1 :: (Traversable1 t, Apply f) => t (f b) -> f (t b)
foldMap1Default :: (Traversable1 f, Semigroup m) => (a -> m) -> f a -> m
instance Traversable1 ((,) a)
instance Traversable1 NonEmpty
instance Traversable1 Tree
instance (Traversable1 f, Traversable1 g) => Traversable1 (Coproduct f g)
instance (Traversable1 f, Traversable1 g) => Traversable1 (Product f g)
instance (Traversable1 f, Traversable1 g) => Traversable1 (Compose f g)
instance Traversable1 f => Traversable1 (IdentityT f)
instance Traversable1 Identity
module Data.Semifunctor
-- | Semifunctors map objects to objects, and arrows to arrows preserving
-- connectivity as normal functors, but do not purport to preserve
-- identity arrows. We apply them to semigroupoids, because those don't
-- even claim to offer identity arrows!
class (Semigroupoid c, Semigroupoid d) => Semifunctor f c d | f c -> d, f d -> c
semimap :: Semifunctor f c d => c a b -> d (f a) (f b)
-- | Used to map a more traditional bifunctor into a semifunctor
data Bi p a
Bi :: p a b -> Bi p (a, b)
(#) :: a -> b -> Bi (,) (a, b)
semibimap :: Semifunctor p (Product l r) cod => l a b -> r c d -> cod (p (a, c)) (p (b, d))
semifirst :: (Semifunctor p (Product l r) cod, Ob r c) => l a b -> cod (p (a, c)) (p (b, c))
semisecond :: (Semifunctor p (Product l r) cod, Ob l a) => r b c -> cod (p (a, b)) (p (a, c))
first :: (Semifunctor p (Product l r) cod, Category r) => l a b -> cod (p (a, c)) (p (b, c))
second :: (Semifunctor p (Product l r) cod, Category l) => r b c -> cod (p (a, b)) (p (a, c))
data WrappedFunctor f a
WrapFunctor :: f a -> WrappedFunctor f a
unwrapFunctor :: WrappedFunctor f a -> f a
data WrappedTraversable1 f a
WrapTraversable1 :: f a -> WrappedTraversable1 f a
unwrapTraversable1 :: WrappedTraversable1 f a -> f a
instance [safe] Extend w => Semifunctor (Bi (,)) (Product (Cokleisli w) (Cokleisli w)) (Cokleisli w)
instance [safe] Bind m => Semifunctor (Bi Either) (Product (Kleisli m) (Kleisli m)) (Kleisli m)
instance [safe] Bind m => Semifunctor (Bi (,)) (Product (Kleisli m) (Kleisli m)) (Kleisli m)
instance [safe] Semifunctor (Bi Either) (Product (->) (->)) (->)
instance [safe] Semifunctor (Bi (,)) (Product (->) (->)) (->)
instance [safe] Semifunctor f c d => Semifunctor f (Dual c) (Dual d)
instance [safe] (Traversable1 f, Bind m) => Semifunctor (WrappedTraversable1 f) (Kleisli m) (Kleisli m)
instance [safe] (Distributive f, Extend w) => Semifunctor (WrappedFunctor f) (Cokleisli w) (Cokleisli w)
instance [safe] (Traversable f, Bind m, Monad m) => Semifunctor (WrappedFunctor f) (Kleisli m) (Kleisli m)
instance [safe] Functor f => Semifunctor (WrappedFunctor f) (->) (->)
module Data.Semifunctor.Associative
class Semifunctor p (Product k k) k => Associative k p
associate :: Associative k p => k (p (p (a, b), c)) (p (a, p (b, c)))
kleisliAssociate :: (Monad m, Semifunctor p (Product (Kleisli m) (Kleisli m)) (Kleisli m), Associative (->) p) => Kleisli m (p (p (a, b), c)) (p (a, p (b, c)))
cokleisliAssociate :: (Comonad m, Semifunctor p (Product (Cokleisli m) (Cokleisli m)) (Cokleisli m), Associative (->) p) => Cokleisli m (p (p (a, b), c)) (p (a, p (b, c)))
class Semifunctor p (Product k k) k => Disassociative k p
disassociate :: Disassociative k p => k (p (a, p (b, c))) (p (p (a, b), c))
kleisliDisassociate :: (Monad m, Semifunctor p (Product (Kleisli m) (Kleisli m)) (Kleisli m), Disassociative (->) p) => Kleisli m (p (a, p (b, c))) (p (p (a, b), c))
cokleisliDisassociate :: (Comonad m, Semifunctor p (Product (Cokleisli m) (Cokleisli m)) (Cokleisli m), Disassociative (->) p) => Cokleisli m (p (a, p (b, c))) (p (p (a, b), c))
instance (Extend m, Comonad m) => Disassociative (Cokleisli m) (Bi (,))
instance (Bind m, Monad m) => Disassociative (Kleisli m) (Bi (,))
instance (Bind m, Monad m) => Disassociative (Kleisli m) (Bi Either)
instance Disassociative (->) (Bi (,))
instance Disassociative (->) (Bi Either)
instance (Extend m, Comonad m) => Associative (Cokleisli m) (Bi (,))
instance (Bind m, Monad m) => Associative (Kleisli m) (Bi (,))
instance (Bind m, Monad m) => Associative (Kleisli m) (Bi Either)
instance Associative (->) (Bi (,))
instance Associative (->) (Bi Either)
module Data.Semifunctor.Braided
class Associative k p => Braided k p
braid :: Braided k p => k (p (a, b)) (p (b, a))
kleisliBraid :: (Monad m, Semifunctor p (Product (Kleisli m) (Kleisli m)) (Kleisli m), Braided (->) p) => Kleisli m (p (a, b)) (p (b, a))
cokleisliBraid :: (Extend w, Comonad w, Semifunctor p (Product (Cokleisli w) (Cokleisli w)) (Cokleisli w), Braided (->) p) => Cokleisli w (p (a, b)) (p (b, a))
class Braided k p => Symmetric k p
swap :: Symmetric k p => k (p (a, b)) (p (b, a))
instance [safe] (Extend w, Comonad w) => Symmetric (Cokleisli w) (Bi (,))
instance [safe] (Bind m, Monad m) => Symmetric (Kleisli m) (Bi (,))
instance [safe] (Bind m, Monad m) => Symmetric (Kleisli m) (Bi Either)
instance [safe] Symmetric (->) (Bi (,))
instance [safe] Symmetric (->) (Bi Either)
instance [safe] (Extend w, Comonad w) => Braided (Cokleisli w) (Bi (,))
instance [safe] (Bind m, Monad m) => Braided (Kleisli m) (Bi (,))
instance [safe] (Bind m, Monad m) => Braided (Kleisli m) (Bi Either)
instance [safe] Braided (->) (Bi (,))
instance [safe] Braided (->) (Bi Either)
module Data.Functor.Alt
-- | Laws:
--
--
-- <!> is associative: (a <!> b) <!> c = a <!> (b <!> c)
-- <$> left-distributes over <!>: f <$> (a <!> b) = (f <$> a) <!> (f <$> b)
--
--
-- If extended to an Alternative then <!> should
-- equal <|>.
--
-- Ideally, an instance of Alt also satisfies the "left
-- distributon" law of MonadPlus with respect to .:
--
--
-- <.> right-distributes over <!>: (a <!> b) <.> c = (a <.> c) <!> (b <.> c)
--
--
-- But Maybe, IO, Either a,
-- ErrorT e m, and STM satisfy the alternative
-- "left catch" law instead:
--
--
-- pure a <!> b = pure a
--
--
-- However, this variation cannot be stated purely in terms of the
-- dependencies of Alt.
--
-- When and if MonadPlus is successfully refactored, this class should
-- also be refactored to remove these instances.
--
-- The right distributive law should extend in the cases where the a
-- Bind or Monad is provided to yield variations of the
-- right distributive law:
--
--
-- (m <!> n) >>- f = (m >>- f) <!> (m >>- f)
-- (m <!> n) >>= f = (m >>= f) <!> (m >>= f)
--
class Functor f => Alt f where some v = some_v where many_v = some_v pure [] some_v = (:) <$> v <*> many_v many v = many_v where many_v = some_v pure [] some_v = (:) <$> v <*> many_v
() :: Alt f => f a -> f a -> f a
some :: (Alt f, Applicative f) => f a -> f [a]
many :: (Alt f, Applicative f) => f a -> f [a]
instance [safe] Alt f => Alt (RWST r w s f)
instance [safe] Alt f => Alt (RWST r w s f)
instance [safe] Alt f => Alt (WriterT w f)
instance [safe] Alt f => Alt (WriterT w f)
instance [safe] Alt f => Alt (StateT e f)
instance [safe] Alt f => Alt (StateT e f)
instance [safe] Apply f => Alt (ListT f)
instance [safe] (Bind f, Monad f) => Alt (ErrorT e f)
instance [safe] (Bind f, Monad f) => Alt (MaybeT f)
instance [safe] Alt f => Alt (ReaderT e f)
instance [safe] Alt f => Alt (IdentityT f)
instance [safe] Alternative f => Alt (WrappedApplicative f)
instance [safe] Alt NonEmpty
instance [safe] Alt Seq
instance [safe] Alt IntMap
instance [safe] Ord k => Alt (Map k)
instance [safe] ArrowPlus a => Alt (WrappedArrow a b)
instance [safe] MonadPlus m => Alt (WrappedMonad m)
instance [safe] Alt Option
instance [safe] Alt Maybe
instance [safe] Alt []
instance [safe] Alt IO
instance [safe] Alt (Either a)
module Data.Functor.Plus
-- | Laws:
--
--
-- zero <!> m = m
-- m <!> zero = m
--
--
-- If extended to an Alternative then zero should equal
-- empty.
class Alt f => Plus f
zero :: Plus f => f a
instance [safe] Plus f => Plus (RWST r w s f)
instance [safe] Plus f => Plus (RWST r w s f)
instance [safe] Plus f => Plus (WriterT w f)
instance [safe] Plus f => Plus (WriterT w f)
instance [safe] Plus f => Plus (StateT e f)
instance [safe] Plus f => Plus (StateT e f)
instance [safe] (Apply f, Applicative f) => Plus (ListT f)
instance [safe] (Bind f, Monad f, Error e) => Plus (ErrorT e f)
instance [safe] (Bind f, Monad f) => Plus (MaybeT f)
instance [safe] Plus f => Plus (ReaderT e f)
instance [safe] Plus f => Plus (IdentityT f)
instance [safe] Alternative f => Plus (WrappedApplicative f)
instance [safe] Plus Seq
instance [safe] Plus IntMap
instance [safe] Ord k => Plus (Map k)
instance [safe] ArrowPlus a => Plus (WrappedArrow a b)
instance [safe] MonadPlus m => Plus (WrappedMonad m)
instance [safe] Plus Option
instance [safe] Plus Maybe
instance [safe] Plus []
instance [safe] Plus IO
module Data.Semigroupoid.Static
newtype Static f a b
Static :: f (a -> b) -> Static f a b
runStatic :: Static f a b -> f (a -> b)
instance Applicative f => ArrowChoice (Static f)
instance Alternative f => ArrowPlus (Static f)
instance Alternative f => ArrowZero (Static f)
instance Applicative f => Arrow (Static f)
instance Applicative f => Category (Static f)
instance Apply f => Semigroupoid (Static f)
instance (Comonad f, Monoid a) => Comonad (Static f a)
instance (Extend f, Semigroup a) => Extend (Static f a)
instance Applicative f => Applicative (Static f a)
instance Plus f => Plus (Static f a)
instance Alt f => Alt (Static f a)
instance Apply f => Apply (Static f a)
instance Functor f => Functor (Static f a)