Safe Haskell | Safe-Inferred |
---|---|
Language | Haskell2010 |
Synopsis
- type family All (p :: k -> Constraint) (as :: [k]) :: Constraint where ...
- type family If (b :: Bool) (l :: k) (r :: k) :: k where ...
- type family Foldr (c :: k -> l -> l) (n :: l) (as :: [k]) :: l where ...
- type family Foldr' (c :: Function k (Function l l -> Type) -> Type) (n :: l) (as :: [k]) :: l where ...
- type family Map (f :: Function k l -> Type) (as :: [k]) :: [l] where ...
- data ConsMap0 :: (Function k l -> Type) -> Function k (Function [l] [l] -> Type) -> Type
- data ConsMap1 :: (Function k l -> Type) -> k -> Function [l] [l] -> Type
- type family Constant (b :: l) (as :: [k]) :: [l] where ...
- type Arrows (as :: [Type]) (r :: Type) = Foldr (->) r as
- type Products (as :: [Type]) = Foldr (,) () as
- type family IsBase (t :: Type) :: Bool where ...
- type family Domains (t :: Type) :: [Type] where ...
- type family Domains' (t :: Type) :: [Type] where ...
- type family CoDomain (t :: Type) :: Type where ...
- type family CoDomain' (t :: Type) :: Type where ...
- class Currying as b where
- data Function :: Type -> Type -> Type
- data Constant0 :: Function a (Function b a -> Type) -> Type
- data Constant1 :: Type -> Function b a -> Type
- type family Apply (t :: Function k l -> Type) (u :: k) :: l
Documentation
type family All (p :: k -> Constraint) (as :: [k]) :: Constraint where ... Source #
All p as
ensures that the constraint p
is satisfied by
all the types
in as
.
(Types is between scare-quotes here because the code is
actually kind polymorphic)
type family Foldr' (c :: Function k (Function l l -> Type) -> Type) (n :: l) (as :: [k]) :: l where ... Source #
Version of Foldr
taking a defunctionalised argument so
that we can use partially applied functions.
type Arrows (as :: [Type]) (r :: Type) = Foldr (->) r as Source #
Arrows [a1,..,an] r
corresponds to a1 -> .. -> an -> r
| Products [a1,..,an]
corresponds to (a1, (..,( an, ())..))
type family IsBase (t :: Type) :: Bool where ... Source #
IsBase t
is 'True
whenever t
is *not* a function space.
type family Domains (t :: Type) :: [Type] where ... Source #
Using IsBase
we can define notions of Domains
and CoDomains
which *reduce* under positive information IsBase t ~ 'True
even
though the shape of t
is not formally exposed
class Currying as b where Source #
Currying as b
witnesses the isomorphism between Arrows as b
and Products as -> b
. It is defined as a type class rather
than by recursion on a singleton for as
so all of that these
conversions are inlined at compile time for concrete arguments.
uncurrys :: Proxy as -> Proxy b -> Arrows as b -> Products as -> b Source #
currys :: Proxy as -> Proxy b -> (Products as -> b) -> Arrows as b Source #
type family Apply (t :: Function k l -> Type) (u :: k) :: l Source #
Instances
type Apply (Constant1 a :: Function k Type -> Type) (b :: k) Source # | |
Defined in Agda.Utils.TypeLevel | |
type Apply (Constant0 :: Function Type (Function b Type -> Type) -> Type) (a :: Type) Source # | |
type Apply (ConsMap0 f :: Function k (Function [l] [l] -> Type) -> Type) (a :: k) Source # | |
type Apply (ConsMap1 f a2 :: Function [a1] [a1] -> Type) (tl :: [a1]) Source # | |
Defined in Agda.Utils.TypeLevel |