-- 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 4.0.2
-- | Placeholders for missing instances of Traversable, until base catches
-- up and adds them
module Data.Traversable.Instances
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 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 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)