Safe Haskell	None
Language	Haskell2010

Data.SOP.Strict

Contents

NP
NS
Injections
Re-exports from sop-core

Description

Strict variant of SOP

This does not currently attempt to be exhaustive.

Synopsis

data NP :: (k -> Type) -> [k] -> Type where
- Nil :: NP f '[]
- (:*) :: !(f x) -> !(NP f xs) -> NP f (x ': xs)
hd :: NP f (x ': xs) -> f x
tl :: NP f (x ': xs) -> NP f xs
data NS :: (k -> Type) -> [k] -> Type where
- Z :: !(f x) -> NS f (x ': xs)
- S :: !(NS f xs) -> NS f (x ': xs)
unZ :: NS f '[x] -> f x
index_NS :: forall f xs. NS f xs -> Int
type Injection (f :: k -> Type) (xs :: [k]) = f -.-> K (NS f xs)
injections :: forall xs f. SListI xs => NP (Injection f xs) xs
data Proxy (t :: k) = Proxy
ccompare_SOP :: forall k (c :: k -> Constraint) proxy r (f :: k -> Type) (g :: k -> Type) (xss :: [[k]]). All2 c xss => proxy c -> r -> (forall (xs :: [k]). All c xs => NP f xs -> NP g xs -> r) -> r -> SOP f xss -> SOP g xss -> r
compare_SOP :: forall k r (f :: k -> Type) (g :: k -> Type) (xss :: [[k]]). r -> (forall (xs :: [k]). NP f xs -> NP g xs -> r) -> r -> SOP f xss -> SOP g xss -> r
ccompare_NS :: forall k c proxy r f g (xs :: [k]). All c xs => proxy c -> r -> (forall (x :: k). c x => f x -> g x -> r) -> r -> NS f xs -> NS g xs -> r
compare_NS :: forall k r f g (xs :: [k]). r -> (forall (x :: k). f x -> g x -> r) -> r -> NS f xs -> NS g xs -> r
apInjs_POP :: forall k (xss :: [[k]]) (f :: k -> Type). SListI xss => POP f xss -> [SOP f xss]
apInjs_NP :: forall k (xs :: [k]) (f :: k -> Type). SListI xs => NP f xs -> [NS f xs]
shift :: forall a1 (f :: a1 -> Type) (xs :: [a1]) (a2 :: a1) (x :: a1). Injection f xs a2 -> Injection f (x ': xs) a2
unSOP :: forall k (f :: k -> Type) (xss :: [[k]]). SOP f xss -> NS (NP f) xss
newtype SOP (f :: k -> Type) (xss :: [[k]]) = SOP (NS (NP f) xss)
hcliftA3' :: forall k (c :: k -> Constraint) (xss :: [[k]]) h proxy f f' f'' f'''. (All2 c xss, Prod h ~ (NP :: ([k] -> Type) -> [[k]] -> Type), HAp h) => proxy c -> (forall (xs :: [k]). All c xs => f xs -> f' xs -> f'' xs -> f''' xs) -> Prod h f xss -> Prod h f' xss -> h f'' xss -> h f''' xss
hcliftA2' :: forall k (c :: k -> Constraint) (xss :: [[k]]) h proxy f f' f''. (All2 c xss, Prod h ~ (NP :: ([k] -> Type) -> [[k]] -> Type), HAp h) => proxy c -> (forall (xs :: [k]). All c xs => f xs -> f' xs -> f'' xs) -> Prod h f xss -> h f' xss -> h f'' xss
hcliftA' :: forall k (c :: k -> Constraint) (xss :: [[k]]) h proxy f f'. (All2 c xss, Prod h ~ (NP :: ([k] -> Type) -> [[k]] -> Type), HAp h) => proxy c -> (forall (xs :: [k]). All c xs => f xs -> f' xs) -> h f xss -> h f' xss
shiftProjection :: forall a1 (f :: a1 -> Type) (xs :: [a1]) (a2 :: a1) (x :: a1). Projection f xs a2 -> Projection f (x ': xs) a2
projections :: forall k (xs :: [k]) (f :: k -> Type). SListI xs => NP (Projection f xs) xs
fromList :: forall k (xs :: [k]) a. SListI xs => [a] -> Maybe (NP (K a :: k -> Type) xs)
unPOP :: forall k (f :: k -> Type) (xss :: [[k]]). POP f xss -> NP (NP f) xss
newtype POP (f :: k -> Type) (xss :: [[k]]) = POP (NP (NP f) xss)
type Projection (f :: k -> Type) (xs :: [k]) = (K (NP f xs) :: k -> Type) -.-> f
lengthSList :: forall k (xs :: [k]) proxy. SListI xs => proxy xs -> Int
shape :: forall k (xs :: [k]). SListI xs => Shape xs
sList :: forall k (xs :: [k]). SListI xs => SList xs
case_SList :: forall k (xs :: [k]) r. SListI xs => r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). SListI ys => r (y ': ys)) -> r xs
para_SList :: forall k (xs :: [k]) r. SListI xs => r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). SListI ys => r ys -> r (y ': ys)) -> r xs
data SList (a :: [k]) where
- SNil :: forall k. SList ('[] :: [k])
- SCons :: forall k (xs :: [k]) (x :: k). SListI xs => SList (x ': xs)
data Shape (a :: [k]) where
- ShapeNil :: forall k. Shape ('[] :: [k])
- ShapeCons :: forall k (xs :: [k]) (x :: k). SListI xs => Shape xs -> Shape (x ': xs)
htoI :: forall k1 l1 l2 h1 (f :: k1 -> Type) (xs :: l1) (ys :: l2) h2. (AllZipN (Prod h1) (LiftedCoercible f I) xs ys, HTrans h1 h2) => h1 f xs -> h2 I ys
hfromI :: forall l1 k2 l2 h1 (f :: k2 -> Type) (xs :: l1) (ys :: l2) h2. (AllZipN (Prod h1) (LiftedCoercible I f) xs ys, HTrans h1 h2) => h1 I xs -> h2 f ys
hsequenceK :: forall k l h (xs :: l) f a. (SListIN h xs, SListIN (Prod h) xs, Applicative f, HSequence h) => h (K (f a) :: k -> Type) xs -> f (h (K a :: k -> Type) xs)
hsequence :: forall l h (xs :: l) f. (SListIN h xs, SListIN (Prod h) xs, HSequence h, Applicative f) => h f xs -> f (h I xs)
hcfor :: forall l h c (xs :: l) g proxy f. (HSequence h, AllN h c xs, Applicative g) => proxy c -> h f xs -> (forall a. c a => f a -> g a) -> g (h I xs)
hctraverse :: forall l h c (xs :: l) g proxy f. (HSequence h, AllN h c xs, Applicative g) => proxy c -> (forall a. c a => f a -> g a) -> h f xs -> g (h I xs)
hcfoldMap :: forall k l h c (xs :: l) m proxy f. (HTraverse_ h, AllN h c xs, Monoid m) => proxy c -> (forall (a :: k). c a => f a -> m) -> h f xs -> m
hcfor_ :: forall k l h c (xs :: l) g proxy f. (HTraverse_ h, AllN h c xs, Applicative g) => proxy c -> h f xs -> (forall (a :: k). c a => f a -> g ()) -> g ()
hczipWith3 :: forall k l h c (xs :: l) proxy f f' f'' f'''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs
hczipWith :: forall k l h c (xs :: l) proxy f f' f''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs
hcmap :: forall k l h c (xs :: l) proxy f f'. (AllN (Prod h) c xs, HAp h) => proxy c -> (forall (a :: k). c a => f a -> f' a) -> h f xs -> h f' xs
hcliftA3 :: forall k l h c (xs :: l) proxy f f' f'' f'''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs
hcliftA2 :: forall k l h c (xs :: l) proxy f f' f''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs
hcliftA :: forall k l h c (xs :: l) proxy f f'. (AllN (Prod h) c xs, HAp h) => proxy c -> (forall (a :: k). c a => f a -> f' a) -> h f xs -> h f' xs
hzipWith3 :: forall k l h (xs :: l) f f' f'' f'''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs
hzipWith :: forall k l h (xs :: l) f f' f''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs
hmap :: forall k l h (xs :: l) f f'. (SListIN (Prod h) xs, HAp h) => (forall (a :: k). f a -> f' a) -> h f xs -> h f' xs
hliftA3 :: forall k l h (xs :: l) f f' f'' f'''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs
hliftA2 :: forall k l h (xs :: l) f f' f''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs
hliftA :: forall k l h (xs :: l) f f'. (SListIN (Prod h) xs, HAp h) => (forall (a :: k). f a -> f' a) -> h f xs -> h f' xs
fn_4 :: forall k f (a :: k) f' f'' f''' f''''. (f a -> f' a -> f'' a -> f''' a -> f'''' a) -> (f -.-> (f' -.-> (f'' -.-> (f''' -.-> f'''')))) a
fn_3 :: forall k f (a :: k) f' f'' f'''. (f a -> f' a -> f'' a -> f''' a) -> (f -.-> (f' -.-> (f'' -.-> f'''))) a
fn_2 :: forall k f (a :: k) f' f''. (f a -> f' a -> f'' a) -> (f -.-> (f' -.-> f'')) a
fn :: forall k f (a :: k) f'. (f a -> f' a) -> (f -.-> f') a
class HPure (h :: (k -> Type) -> l -> Type) where
- hpure :: forall (xs :: l) f. SListIN h xs => (forall (a :: k). f a) -> h f xs
- hcpure :: forall c (xs :: l) proxy f. AllN h c xs => proxy c -> (forall (a :: k). c a => f a) -> h f xs
newtype ((f :: k -> Type) -.-> (g :: k -> Type)) (a :: k) = Fn {
- apFn :: f a -> g a
}
type family Prod (h :: (k -> Type) -> l -> Type) :: (k -> Type) -> l -> Type
class (Prod (Prod h) ~ Prod h, HPure (Prod h)) => HAp (h :: (k -> Type) -> l -> Type) where
- hap :: forall (f :: k -> Type) (g :: k -> Type) (xs :: l). Prod h (f -.-> g) xs -> h f xs -> h g xs
type family CollapseTo (h :: (k -> Type) -> l -> Type) x
class HCollapse (h :: (k -> Type) -> l -> Type) where
- hcollapse :: forall (xs :: l) a. SListIN h xs => h (K a :: k -> Type) xs -> CollapseTo h a
class HTraverse_ (h :: (k -> Type) -> l -> Type) where
- hctraverse_ :: forall c (xs :: l) g proxy f. (AllN h c xs, Applicative g) => proxy c -> (forall (a :: k). c a => f a -> g ()) -> h f xs -> g ()
- htraverse_ :: forall (xs :: l) g f. (SListIN h xs, Applicative g) => (forall (a :: k). f a -> g ()) -> h f xs -> g ()
class HAp h => HSequence (h :: (k -> Type) -> l -> Type) where
- hsequence' :: forall (xs :: l) f (g :: k -> Type). (SListIN h xs, Applicative f) => h (f :.: g) xs -> f (h g xs)
- hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN h c xs, Applicative g) => proxy c -> (forall (a :: k). c a => f a -> g (f' a)) -> h f xs -> g (h f' xs)
- htraverse' :: forall (xs :: l) g f f'. (SListIN h xs, Applicative g) => (forall (a :: k). f a -> g (f' a)) -> h f xs -> g (h f' xs)
class HIndex (h :: (k -> Type) -> l -> Type) where
- hindex :: forall (f :: k -> Type) (xs :: l). h f xs -> Int
type family UnProd (h :: (k -> Type) -> l -> Type) :: (k -> Type) -> l -> Type
class UnProd (Prod h) ~ h => HApInjs (h :: (k -> Type) -> l -> Type) where
- hapInjs :: forall (xs :: l) (f :: k -> Type). SListIN h xs => Prod h f xs -> [h f xs]
class HExpand (h :: (k -> Type) -> l -> Type) where
- hexpand :: forall (xs :: l) f. SListIN (Prod h) xs => (forall (x :: k). f x) -> h f xs -> Prod h f xs
- hcexpand :: forall c (xs :: l) proxy f. AllN (Prod h) c xs => proxy c -> (forall (x :: k). c x => f x) -> h f xs -> Prod h f xs
class ((Same h1 :: (k2 -> Type) -> l2 -> Type) ~ h2, (Same h2 :: (k1 -> Type) -> l1 -> Type) ~ h1) => HTrans (h1 :: (k1 -> Type) -> l1 -> Type) (h2 :: (k2 -> Type) -> l2 -> Type) where
- htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod h1) c xs ys => proxy c -> (forall (x :: k1) (y :: k2). c x y => f x -> g y) -> h1 f xs -> h2 g ys
- hcoerce :: forall (f :: k1 -> Type) (g :: k2 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod h1) (LiftedCoercible f g) xs ys => h1 f xs -> h2 g ys
ccase_SList :: forall k c (xs :: [k]) proxy r. All c xs => proxy c -> r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). (c y, All c ys) => r (y ': ys)) -> r xs
class (AllF c xs, SListI xs) => All (c :: k -> Constraint) (xs :: [k]) where
- cpara_SList :: proxy c -> r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). (c y, All c ys) => r ys -> r (y ': ys)) -> r xs
type SListI2 = All (SListI :: [k] -> Constraint)
type SListI = All (Top :: k -> Constraint)
type All2 (c :: k -> Constraint) = All (All c)
class (SListI xs, SListI ys, SameShapeAs xs ys, SameShapeAs ys xs, AllZipF c xs ys) => AllZip (c :: a -> b -> Constraint) (xs :: [a]) (ys :: [b])
type family SameShapeAs (xs :: [a]) (ys :: [b]) where ...
class Coercible (f x) (g y) => LiftedCoercible (f :: k -> k1) (g :: k2 -> k1) (x :: k) (y :: k2)
class (AllZipF (AllZip f) xss yss, SListI xss, SListI yss, SameShapeAs xss yss, SameShapeAs yss xss) => AllZip2 (f :: a -> b -> Constraint) (xss :: [[a]]) (yss :: [[b]])
class f (g x) => Compose (f :: k -> Constraint) (g :: k1 -> k) (x :: k1)
class (f x, g x) => And (f :: k -> Constraint) (g :: k -> Constraint) (x :: k)
class Top (x :: k)
type family AllN (h :: (k -> Type) -> l -> Type) (c :: k -> Constraint) :: l -> Constraint
type family AllZipN (h :: (k -> Type) -> l -> Type) (c :: k1 -> k2 -> Constraint) :: l1 -> l2 -> Constraint
mapKKK :: forall k1 k2 k3 a b c (d :: k1) (e :: k2) (f :: k3). (a -> b -> c) -> K a d -> K b e -> K c f
mapKKI :: forall k1 k2 a b c (d :: k1) (e :: k2). (a -> b -> c) -> K a d -> K b e -> I c
mapKIK :: forall k1 k2 a b c (d :: k1) (e :: k2). (a -> b -> c) -> K a d -> I b -> K c e
mapKII :: forall k a b c (d :: k). (a -> b -> c) -> K a d -> I b -> I c
mapIKK :: forall k1 k2 a b c (d :: k1) (e :: k2). (a -> b -> c) -> I a -> K b d -> K c e
mapIKI :: forall k a b c (d :: k). (a -> b -> c) -> I a -> K b d -> I c
mapIIK :: forall k a b c (d :: k). (a -> b -> c) -> I a -> I b -> K c d
mapIII :: (a -> b -> c) -> I a -> I b -> I c
mapKK :: forall k1 k2 a b (c :: k1) (d :: k2). (a -> b) -> K a c -> K b d
mapKI :: forall k a b (c :: k). (a -> b) -> K a c -> I b
mapIK :: forall k a b (c :: k). (a -> b) -> I a -> K b c
mapII :: (a -> b) -> I a -> I b
unComp :: forall l k f (g :: k -> l) (p :: k). (f :.: g) p -> f (g p)
unI :: I a -> a
unK :: forall k a (b :: k). K a b -> a
newtype K a (b :: k) = K a
newtype I a = I a
newtype ((f :: l -> Type) :.: (g :: k -> l)) (p :: k) = Comp (f (g p))
module Data.SOP.Constraint

NP

data NP :: (k -> Type) -> [k] -> Type where Source #

Constructors

Nil :: NP f '[]
(:*) :: !(f x) -> !(NP f xs) -> NP f (x ': xs) infixr 5

Instances

Instances details

HPure (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hpure :: forall (xs :: l) f. SListIN NP xs => (forall (a :: k0). f a) -> NP f xs Source # hcpure :: forall c (xs :: l) proxy f. AllN NP c xs => proxy c -> (forall (a :: k0). c a => f a) -> NP f xs Source #
HAp (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod NP (f -.-> g) xs -> NP f xs -> NP g xs Source #
HCollapse (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hcollapse :: forall (xs :: l) a. SListIN NP xs => NP (K a) xs -> CollapseTo NP a Source #
HTraverse_ (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN NP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> NP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN NP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> NP f xs -> g () Source #
HSequence (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN NP xs, Applicative f) => NP (f :.: g) xs -> f (NP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN NP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> NP f xs -> g (NP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN NP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> NP f xs -> g (NP f' xs) Source #
All (Compose Eq f) xs => Eq (NP f xs) Source #
Instance details Defined in Data.SOP.Strict Methods (==) :: NP f xs -> NP f xs -> Bool # (/=) :: NP f xs -> NP f xs -> Bool #
(All (Compose Eq f) xs, All (Compose Ord f) xs) => Ord (NP f xs) Source #
Instance details Defined in Data.SOP.Strict Methods compare :: NP f xs -> NP f xs -> Ordering # (<) :: NP f xs -> NP f xs -> Bool # (<=) :: NP f xs -> NP f xs -> Bool # (>) :: NP f xs -> NP f xs -> Bool # (>=) :: NP f xs -> NP f xs -> Bool # max :: NP f xs -> NP f xs -> NP f xs # min :: NP f xs -> NP f xs -> NP f xs #
All (Compose Show f) xs => Show (NP f xs) Source #	Copied from sop-core Not derived, since derived instance ignores associativity info
Instance details Defined in Data.SOP.Strict Methods showsPrec :: Int -> NP f xs -> ShowS # show :: NP f xs -> String # showList :: [NP f xs] -> ShowS #
All (Compose NoThunks f) xs => NoThunks (NP f xs) Source #
Instance details Defined in Data.SOP.Strict Methods noThunks :: Context -> NP f xs -> IO (Maybe ThunkInfo) Source # wNoThunks :: Context -> NP f xs -> IO (Maybe ThunkInfo) Source # showTypeOf :: Proxy (NP f xs) -> String Source #
type AllZipN (NP :: (k -> Type) -> [k] -> Type) (c :: a -> b -> Constraint) Source #
Instance details Defined in Data.SOP.Strict type AllZipN (NP :: (k -> Type) -> [k] -> Type) (c :: a -> b -> Constraint) = AllZip c
type Prod (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict type Prod (NP :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type SListIN (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict type SListIN (NP :: (k -> Type) -> [k] -> Type) = SListI :: [k] -> Constraint
type CollapseTo (NP :: (k -> Type) -> [k] -> Type) a Source #
Instance details Defined in Data.SOP.Strict type CollapseTo (NP :: (k -> Type) -> [k] -> Type) a = [a]
type AllN (NP :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) Source #
Instance details Defined in Data.SOP.Strict type AllN (NP :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c

hd :: NP f (x ': xs) -> f x Source #

tl :: NP f (x ': xs) -> NP f xs Source #

NS

data NS :: (k -> Type) -> [k] -> Type where Source #

Constructors

Z :: !(f x) -> NS f (x ': xs)
S :: !(NS f xs) -> NS f (x ': xs)

Instances

Instances details

HTrans (NS :: (k1 -> Type) -> [k1] -> Type) (NS :: (k2 -> Type) -> [k2] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod NS) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> NS f xs -> NS g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod NS) (LiftedCoercible f g) xs ys => NS f xs -> NS g ys Source #
HAp (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod NS (f -.-> g) xs -> NS f xs -> NS g xs Source #
HCollapse (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hcollapse :: forall (xs :: l) a. SListIN NS xs => NS (K a) xs -> CollapseTo NS a Source #
HSequence (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN NS xs, Applicative f) => NS (f :.: g) xs -> f (NS g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN NS c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> NS f xs -> g (NS f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN NS xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> NS f xs -> g (NS f' xs) Source #
HExpand (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hexpand :: forall (xs :: l) f. SListIN (Prod NS) xs => (forall (x :: k0). f x) -> NS f xs -> Prod NS f xs Source # hcexpand :: forall c (xs :: l) proxy f. AllN (Prod NS) c xs => proxy c -> (forall (x :: k0). c x => f x) -> NS f xs -> Prod NS f xs Source #
All (Compose Eq f) xs => Eq (NS f xs) Source #
Instance details Defined in Data.SOP.Strict Methods (==) :: NS f xs -> NS f xs -> Bool # (/=) :: NS f xs -> NS f xs -> Bool #
(All (Compose Eq f) xs, All (Compose Ord f) xs) => Ord (NS f xs) Source #
Instance details Defined in Data.SOP.Strict Methods compare :: NS f xs -> NS f xs -> Ordering # (<) :: NS f xs -> NS f xs -> Bool # (<=) :: NS f xs -> NS f xs -> Bool # (>) :: NS f xs -> NS f xs -> Bool # (>=) :: NS f xs -> NS f xs -> Bool # max :: NS f xs -> NS f xs -> NS f xs # min :: NS f xs -> NS f xs -> NS f xs #
All (Compose Show f) xs => Show (NS f xs) Source #
Instance details Defined in Data.SOP.Strict Methods showsPrec :: Int -> NS f xs -> ShowS # show :: NS f xs -> String # showList :: [NS f xs] -> ShowS #
All (Compose NoThunks f) xs => NoThunks (NS f xs) Source #
Instance details Defined in Data.SOP.Strict Methods noThunks :: Context -> NS f xs -> IO (Maybe ThunkInfo) Source # wNoThunks :: Context -> NS f xs -> IO (Maybe ThunkInfo) Source # showTypeOf :: Proxy (NS f xs) -> String Source #
type Same (NS :: (k1 -> Type) -> [k1] -> Type) Source #
Instance details Defined in Data.SOP.Strict type Same (NS :: (k1 -> Type) -> [k1] -> Type) = NS :: (k2 -> Type) -> [k2] -> Type
type Prod (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict type Prod (NS :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type SListIN (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict type SListIN (NS :: (k -> Type) -> [k] -> Type) = SListI :: [k] -> Constraint
type CollapseTo (NS :: (k -> Type) -> [k] -> Type) a Source #
Instance details Defined in Data.SOP.Strict type CollapseTo (NS :: (k -> Type) -> [k] -> Type) a = a
type AllN (NS :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) Source #
Instance details Defined in Data.SOP.Strict type AllN (NS :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c

unZ :: NS f '[x] -> f x Source #

index_NS :: forall f xs. NS f xs -> Int Source #

Injections

type Injection (f :: k -> Type) (xs :: [k]) = f -.-> K (NS f xs) Source #

injections :: forall xs f. SListI xs => NP (Injection f xs) xs Source #

Re-exports from `sop-core`

data Proxy (t :: k) #

Proxy is a type that holds no data, but has a phantom parameter of arbitrary type (or even kind). Its use is to provide type information, even though there is no value available of that type (or it may be too costly to create one).

Historically, Proxy :: Proxy a is a safer alternative to the undefined :: a idiom.

>>> Proxy :: Proxy (Void, Int -> Int)
Proxy

Proxy can even hold types of higher kinds,

>>> Proxy :: Proxy Either
Proxy

>>> Proxy :: Proxy Functor
Proxy

>>> Proxy :: Proxy complicatedStructure
Proxy

Constructors

Proxy

Instances

Instances details

Generic1 (Proxy :: k -> Type)	Since: base-4.6.0.0
Instance details Defined in GHC.Generics Associated Types type Rep1 Proxy :: k -> Type # Methods from1 :: forall (a :: k0). Proxy a -> Rep1 Proxy a # to1 :: forall (a :: k0). Rep1 Proxy a -> Proxy a #
Monad (Proxy :: Type -> Type)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods (>>=) :: Proxy a -> (a -> Proxy b) -> Proxy b # (>>) :: Proxy a -> Proxy b -> Proxy b # return :: a -> Proxy a #
Functor (Proxy :: Type -> Type)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods fmap :: (a -> b) -> Proxy a -> Proxy b # (<$) :: a -> Proxy b -> Proxy a #
Applicative (Proxy :: Type -> Type)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods pure :: a -> Proxy a # (<>) :: Proxy (a -> b) -> Proxy a -> Proxy b # liftA2 :: (a -> b -> c) -> Proxy a -> Proxy b -> Proxy c # (>) :: Proxy a -> Proxy b -> Proxy b # (<*) :: Proxy a -> Proxy b -> Proxy a #
Foldable (Proxy :: Type -> Type)	Since: base-4.7.0.0
Instance details Defined in Data.Foldable Methods fold :: Monoid m => Proxy m -> m # foldMap :: Monoid m => (a -> m) -> Proxy a -> m # foldMap' :: Monoid m => (a -> m) -> Proxy a -> m # foldr :: (a -> b -> b) -> b -> Proxy a -> b # foldr' :: (a -> b -> b) -> b -> Proxy a -> b # foldl :: (b -> a -> b) -> b -> Proxy a -> b # foldl' :: (b -> a -> b) -> b -> Proxy a -> b # foldr1 :: (a -> a -> a) -> Proxy a -> a # foldl1 :: (a -> a -> a) -> Proxy a -> a # toList :: Proxy a -> [a] # null :: Proxy a -> Bool # length :: Proxy a -> Int # elem :: Eq a => a -> Proxy a -> Bool # maximum :: Ord a => Proxy a -> a # minimum :: Ord a => Proxy a -> a # sum :: Num a => Proxy a -> a # product :: Num a => Proxy a -> a #
Traversable (Proxy :: Type -> Type)	Since: base-4.7.0.0
Instance details Defined in Data.Traversable Methods traverse :: Applicative f => (a -> f b) -> Proxy a -> f (Proxy b) # sequenceA :: Applicative f => Proxy (f a) -> f (Proxy a) # mapM :: Monad m => (a -> m b) -> Proxy a -> m (Proxy b) # sequence :: Monad m => Proxy (m a) -> m (Proxy a) #
MonadPlus (Proxy :: Type -> Type)	Since: base-4.9.0.0
Instance details Defined in Data.Proxy Methods mzero :: Proxy a # mplus :: Proxy a -> Proxy a -> Proxy a #
Alternative (Proxy :: Type -> Type)	Since: base-4.9.0.0
Instance details Defined in Data.Proxy Methods empty :: Proxy a # (<\|>) :: Proxy a -> Proxy a -> Proxy a # some :: Proxy a -> Proxy [a] # many :: Proxy a -> Proxy [a] #
Contravariant (Proxy :: Type -> Type)
Instance details Defined in Data.Functor.Contravariant Methods contramap :: (a -> b) -> Proxy b -> Proxy a # (>$) :: b -> Proxy b -> Proxy a #
Eq1 (Proxy :: Type -> Type)	Since: base-4.9.0.0
Instance details Defined in Data.Functor.Classes Methods liftEq :: (a -> b -> Bool) -> Proxy a -> Proxy b -> Bool #
Ord1 (Proxy :: Type -> Type)	Since: base-4.9.0.0
Instance details Defined in Data.Functor.Classes Methods liftCompare :: (a -> b -> Ordering) -> Proxy a -> Proxy b -> Ordering #
Read1 (Proxy :: Type -> Type)	Since: base-4.9.0.0
Instance details Defined in Data.Functor.Classes Methods liftReadsPrec :: (Int -> ReadS a) -> ReadS [a] -> Int -> ReadS (Proxy a) # liftReadList :: (Int -> ReadS a) -> ReadS [a] -> ReadS [Proxy a] # liftReadPrec :: ReadPrec a -> ReadPrec [a] -> ReadPrec (Proxy a) # liftReadListPrec :: ReadPrec a -> ReadPrec [a] -> ReadPrec [Proxy a] #
Show1 (Proxy :: Type -> Type)	Since: base-4.9.0.0
Instance details Defined in Data.Functor.Classes Methods liftShowsPrec :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> Int -> Proxy a -> ShowS # liftShowList :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> [Proxy a] -> ShowS #
NFData1 (Proxy :: Type -> Type)	Since: deepseq-1.4.3.0
Instance details Defined in Control.DeepSeq Methods liftRnf :: (a -> ()) -> Proxy a -> () #
Hashable1 (Proxy :: Type -> Type)
Instance details Defined in Data.Hashable.Class Methods liftHashWithSalt :: (Int -> a -> Int) -> Int -> Proxy a -> Int Source #
Bounded (Proxy t)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods minBound :: Proxy t # maxBound :: Proxy t #
Enum (Proxy s)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods succ :: Proxy s -> Proxy s # pred :: Proxy s -> Proxy s # toEnum :: Int -> Proxy s # fromEnum :: Proxy s -> Int # enumFrom :: Proxy s -> [Proxy s] # enumFromThen :: Proxy s -> Proxy s -> [Proxy s] # enumFromTo :: Proxy s -> Proxy s -> [Proxy s] # enumFromThenTo :: Proxy s -> Proxy s -> Proxy s -> [Proxy s] #
Eq (Proxy s)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods (==) :: Proxy s -> Proxy s -> Bool # (/=) :: Proxy s -> Proxy s -> Bool #
Ord (Proxy s)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods compare :: Proxy s -> Proxy s -> Ordering # (<) :: Proxy s -> Proxy s -> Bool # (<=) :: Proxy s -> Proxy s -> Bool # (>) :: Proxy s -> Proxy s -> Bool # (>=) :: Proxy s -> Proxy s -> Bool # max :: Proxy s -> Proxy s -> Proxy s # min :: Proxy s -> Proxy s -> Proxy s #
Read (Proxy t)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods readsPrec :: Int -> ReadS (Proxy t) # readList :: ReadS [Proxy t] # readPrec :: ReadPrec (Proxy t) # readListPrec :: ReadPrec [Proxy t] #
Show (Proxy s)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods showsPrec :: Int -> Proxy s -> ShowS # show :: Proxy s -> String # showList :: [Proxy s] -> ShowS #
Ix (Proxy s)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods range :: (Proxy s, Proxy s) -> [Proxy s] # index :: (Proxy s, Proxy s) -> Proxy s -> Int # unsafeIndex :: (Proxy s, Proxy s) -> Proxy s -> Int # inRange :: (Proxy s, Proxy s) -> Proxy s -> Bool # rangeSize :: (Proxy s, Proxy s) -> Int # unsafeRangeSize :: (Proxy s, Proxy s) -> Int #
Generic (Proxy t)	Since: base-4.6.0.0
Instance details Defined in GHC.Generics Associated Types type Rep (Proxy t) :: Type -> Type # Methods from :: Proxy t -> Rep (Proxy t) x # to :: Rep (Proxy t) x -> Proxy t #
Semigroup (Proxy s)	Since: base-4.9.0.0
Instance details Defined in Data.Proxy Methods (<>) :: Proxy s -> Proxy s -> Proxy s # sconcat :: NonEmpty (Proxy s) -> Proxy s # stimes :: Integral b => b -> Proxy s -> Proxy s #
Monoid (Proxy s)	Since: base-4.7.0.0
Instance details Defined in Data.Proxy Methods mempty :: Proxy s # mappend :: Proxy s -> Proxy s -> Proxy s # mconcat :: [Proxy s] -> Proxy s #
NFData (Proxy a)	Since: deepseq-1.4.0.0
Instance details Defined in Control.DeepSeq Methods rnf :: Proxy a -> () #
Hashable (Proxy a)
Instance details Defined in Data.Hashable.Class Methods hashWithSalt :: Int -> Proxy a -> Int Source # hash :: Proxy a -> Int Source #
Serialise (Proxy a)	Since: serialise-0.2.0.0
Instance details Defined in Codec.Serialise.Class Methods encode :: Proxy a -> Encoding Source # decode :: Decoder s (Proxy a) Source # encodeList :: [Proxy a] -> Encoding Source # decodeList :: Decoder s [Proxy a] Source #
type Rep1 (Proxy :: k -> Type)
Instance details Defined in GHC.Generics type Rep1 (Proxy :: k -> Type) = D1 ('MetaData "Proxy" "Data.Proxy" "base" 'False) (C1 ('MetaCons "Proxy" 'PrefixI 'False) (U1 :: k -> Type))
type Rep (Proxy t)
Instance details Defined in GHC.Generics type Rep (Proxy t) = D1 ('MetaData "Proxy" "Data.Proxy" "base" 'False) (C1 ('MetaCons "Proxy" 'PrefixI 'False) (U1 :: Type -> Type))

ccompare_SOP Source #

Arguments

:: forall k (c :: k -> Constraint) proxy r (f :: k -> Type) (g :: k -> Type) (xss :: [[k]]). All2 c xss
=> proxy c
-> r	what to do if first is smaller
-> (forall (xs :: [k]). All c xs => NP f xs -> NP g xs -> r)	what to do if both are equal
-> r	what to do if first is larger
-> SOP f xss
-> SOP g xss
-> r

Constrained version of compare_SOP.

Since: sop-core-0.3.2.0

compare_SOP Source #

Arguments

:: forall k r (f :: k -> Type) (g :: k -> Type) (xss :: [[k]]). r	what to do if first is smaller
-> (forall (xs :: [k]). NP f xs -> NP g xs -> r)	what to do if both are equal
-> r	what to do if first is larger
-> SOP f xss
-> SOP g xss
-> r

Compare two sums of products with respect to the choice in the sum they are making.

Only the sum structure is used for comparison. This is a small wrapper around ccompare_NS for a common special case.

Since: sop-core-0.3.2.0

ccompare_NS Source #

Arguments

:: forall k c proxy r f g (xs :: [k]). All c xs
=> proxy c
-> r	what to do if first is smaller
-> (forall (x :: k). c x => f x -> g x -> r)	what to do if both are equal
-> r	what to do if first is larger
-> NS f xs
-> NS g xs
-> r

Constrained version of compare_NS.

Since: sop-core-0.3.2.0

compare_NS Source #

Arguments

:: forall k r f g (xs :: [k]). r	what to do if first is smaller
-> (forall (x :: k). f x -> g x -> r)	what to do if both are equal
-> r	what to do if first is larger
-> NS f xs
-> NS g xs
-> r

Compare two sums with respect to the choice they are making.

A value that chooses the first option is considered smaller than one that chooses the second option.

If the choices are different, then either the first (if the first is smaller than the second) or the third (if the first is larger than the second) argument are called. If both choices are equal, then the second argument is called, which has access to the elements contained in the sums.

Since: sop-core-0.3.2.0

apInjs_POP :: forall k (xss :: [[k]]) (f :: k -> Type). SListI xss => POP f xss -> [SOP f xss] Source #

Apply injections to a product of product.

This operates on the outer product only. Given a product containing all possible choices (that are products), produce a list of sums (of products) by applying each injection to the appropriate element.

Example:

>>> apInjs_POP (POP ((I 'x' :* Nil) :* (I True :* I 2 :* Nil) :* Nil))
[SOP (Z (I 'x' :* Nil)),SOP (S (Z (I True :* I 2 :* Nil)))]

apInjs_NP :: forall k (xs :: [k]) (f :: k -> Type). SListI xs => NP f xs -> [NS f xs] Source #

Apply injections to a product.

Given a product containing all possible choices, produce a list of sums by applying each injection to the appropriate element.

Example:

>>> apInjs_NP (I 'x' :* I True :* I 2 :* Nil)
[Z (I 'x'),S (Z (I True)),S (S (Z (I 2)))]

shift :: forall a1 (f :: a1 -> Type) (xs :: [a1]) (a2 :: a1) (x :: a1). Injection f xs a2 -> Injection f (x ': xs) a2 Source #

Shift an injection.

Given an injection, return an injection into a sum that is one component larger.

unSOP :: forall k (f :: k -> Type) (xss :: [[k]]). SOP f xss -> NS (NP f) xss Source #

Unwrap a sum of products.

newtype SOP (f :: k -> Type) (xss :: [[k]]) Source #

A sum of products.

This is a 'newtype' for an NS of an NP. The elements of the (inner) products are applications of the parameter f. The type SOP is indexed by the list of lists that determines the sizes of both the (outer) sum and all the (inner) products, as well as the types of all the elements of the inner products.

A SOP I reflects the structure of a normal Haskell datatype. The sum structure represents the choice between the different constructors, the product structure represents the arguments of each constructor.

Constructors

SOP (NS (NP f) xss)

Instances

Instances details

HTrans (SOP :: (k1 -> Type) -> [[k1]] -> Type) (SOP :: (k2 -> Type) -> [[k2]] -> Type)
Instance details Defined in Data.SOP.NS Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod SOP) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> SOP f xs -> SOP g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod SOP) (LiftedCoercible f g) xs ys => SOP f xs -> SOP g ys Source #
HAp (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod SOP (f -.-> g) xs -> SOP f xs -> SOP g xs Source #
HCollapse (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hcollapse :: forall (xs :: l) a. SListIN SOP xs => SOP (K a) xs -> CollapseTo SOP a Source #
HTraverse_ (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN SOP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> SOP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN SOP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> SOP f xs -> g () Source #
HSequence (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN SOP xs, Applicative f) => SOP (f :.: g) xs -> f (SOP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN SOP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> SOP f xs -> g (SOP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN SOP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> SOP f xs -> g (SOP f' xs) Source #
HIndex (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hindex :: forall (f :: k0 -> Type) (xs :: l). SOP f xs -> Int Source #
HApInjs (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hapInjs :: forall (xs :: l) (f :: k0 -> Type). SListIN SOP xs => Prod SOP f xs -> [SOP f xs] Source #
HExpand (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hexpand :: forall (xs :: l) f. SListIN (Prod SOP) xs => (forall (x :: k0). f x) -> SOP f xs -> Prod SOP f xs Source # hcexpand :: forall c (xs :: l) proxy f. AllN (Prod SOP) c xs => proxy c -> (forall (x :: k0). c x => f x) -> SOP f xs -> Prod SOP f xs Source #
Eq (NS (NP f) xss) => Eq (SOP f xss)
Instance details Defined in Data.SOP.NS Methods (==) :: SOP f xss -> SOP f xss -> Bool # (/=) :: SOP f xss -> SOP f xss -> Bool #
Ord (NS (NP f) xss) => Ord (SOP f xss)
Instance details Defined in Data.SOP.NS Methods compare :: SOP f xss -> SOP f xss -> Ordering # (<) :: SOP f xss -> SOP f xss -> Bool # (<=) :: SOP f xss -> SOP f xss -> Bool # (>) :: SOP f xss -> SOP f xss -> Bool # (>=) :: SOP f xss -> SOP f xss -> Bool # max :: SOP f xss -> SOP f xss -> SOP f xss # min :: SOP f xss -> SOP f xss -> SOP f xss #
Show (NS (NP f) xss) => Show (SOP f xss)
Instance details Defined in Data.SOP.NS Methods showsPrec :: Int -> SOP f xss -> ShowS # show :: SOP f xss -> String # showList :: [SOP f xss] -> ShowS #
NFData (NS (NP f) xss) => NFData (SOP f xss)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.NS Methods rnf :: SOP f xss -> () #
type Same (SOP :: (k1 -> Type) -> [[k1]] -> Type)
Instance details Defined in Data.SOP.NS type Same (SOP :: (k1 -> Type) -> [[k1]] -> Type) = SOP :: (k2 -> Type) -> [[k2]] -> Type
type Prod (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS type Prod (SOP :: (k -> Type) -> [[k]] -> Type) = POP :: (k -> Type) -> [[k]] -> Type
type SListIN (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS type SListIN (SOP :: (k -> Type) -> [[k]] -> Type) = SListI2 :: [[k]] -> Constraint
type CollapseTo (SOP :: (k -> Type) -> [[k]] -> Type) a
Instance details Defined in Data.SOP.NS type CollapseTo (SOP :: (k -> Type) -> [[k]] -> Type) a = [a]
type AllN (SOP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint)
Instance details Defined in Data.SOP.NS type AllN (SOP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint) = All2 c

hcliftA3' :: forall k (c :: k -> Constraint) (xss :: [[k]]) h proxy f f' f'' f'''. (All2 c xss, Prod h ~ (NP :: ([k] -> Type) -> [[k]] -> Type), HAp h) => proxy c -> (forall (xs :: [k]). All c xs => f xs -> f' xs -> f'' xs -> f''' xs) -> Prod h f xss -> Prod h f' xss -> h f'' xss -> h f''' xss Source #

Like hcliftA', but for ternary functions.

hcliftA2' :: forall k (c :: k -> Constraint) (xss :: [[k]]) h proxy f f' f''. (All2 c xss, Prod h ~ (NP :: ([k] -> Type) -> [[k]] -> Type), HAp h) => proxy c -> (forall (xs :: [k]). All c xs => f xs -> f' xs -> f'' xs) -> Prod h f xss -> h f' xss -> h f'' xss Source #

Like hcliftA', but for binary functions.

hcliftA' :: forall k (c :: k -> Constraint) (xss :: [[k]]) h proxy f f'. (All2 c xss, Prod h ~ (NP :: ([k] -> Type) -> [[k]] -> Type), HAp h) => proxy c -> (forall (xs :: [k]). All c xs => f xs -> f' xs) -> h f xss -> h f' xss Source #

Lift a constrained function operating on a list-indexed structure to a function on a list-of-list-indexed structure.

This is a variant of hcliftA.

Specification:

hcliftA' p f xs = hpure (fn_2 $ \ AllDictC -> f) ` hap ` allDict_NP p ` hap ` xs

Instances:

hcliftA' :: All2 c xss => proxy c -> (forall xs. All c xs => f xs -> f' xs) -> NP f xss -> NP f' xss
hcliftA' :: All2 c xss => proxy c -> (forall xs. All c xs => f xs -> f' xs) -> NS f xss -> NS f' xss

shiftProjection :: forall a1 (f :: a1 -> Type) (xs :: [a1]) (a2 :: a1) (x :: a1). Projection f xs a2 -> Projection f (x ': xs) a2 Source #

projections :: forall k (xs :: [k]) (f :: k -> Type). SListI xs => NP (Projection f xs) xs Source #

Compute all projections from an n-ary product.

Each element of the resulting product contains one of the projections.

fromList :: forall k (xs :: [k]) a. SListI xs => [a] -> Maybe (NP (K a :: k -> Type) xs) Source #

Construct a homogeneous n-ary product from a normal Haskell list.

Returns Nothing if the length of the list does not exactly match the expected size of the product.

unPOP :: forall k (f :: k -> Type) (xss :: [[k]]). POP f xss -> NP (NP f) xss Source #

Unwrap a product of products.

newtype POP (f :: k -> Type) (xss :: [[k]]) Source #

A product of products.

This is a 'newtype' for an NP of an NP. The elements of the inner products are applications of the parameter f. The type POP is indexed by the list of lists that determines the lengths of both the outer and all the inner products, as well as the types of all the elements of the inner products.

A POP is reminiscent of a two-dimensional table (but the inner lists can all be of different length). In the context of the SOP approach to generic programming, a POP is useful to represent information that is available for all arguments of all constructors of a datatype.

Constructors

POP (NP (NP f) xss)

Instances

Instances details

HTrans (POP :: (k1 -> Type) -> [[k1]] -> Type) (POP :: (k2 -> Type) -> [[k2]] -> Type)
Instance details Defined in Data.SOP.NP Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod POP) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> POP f xs -> POP g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod POP) (LiftedCoercible f g) xs ys => POP f xs -> POP g ys Source #
HPure (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hpure :: forall (xs :: l) f. SListIN POP xs => (forall (a :: k0). f a) -> POP f xs Source # hcpure :: forall c (xs :: l) proxy f. AllN POP c xs => proxy c -> (forall (a :: k0). c a => f a) -> POP f xs Source #
HAp (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod POP (f -.-> g) xs -> POP f xs -> POP g xs Source #
HCollapse (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hcollapse :: forall (xs :: l) a. SListIN POP xs => POP (K a) xs -> CollapseTo POP a Source #
HTraverse_ (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN POP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> POP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN POP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> POP f xs -> g () Source #
HSequence (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN POP xs, Applicative f) => POP (f :.: g) xs -> f (POP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN POP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> POP f xs -> g (POP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN POP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> POP f xs -> g (POP f' xs) Source #
Eq (NP (NP f) xss) => Eq (POP f xss)
Instance details Defined in Data.SOP.NP Methods (==) :: POP f xss -> POP f xss -> Bool # (/=) :: POP f xss -> POP f xss -> Bool #
Ord (NP (NP f) xss) => Ord (POP f xss)
Instance details Defined in Data.SOP.NP Methods compare :: POP f xss -> POP f xss -> Ordering # (<) :: POP f xss -> POP f xss -> Bool # (<=) :: POP f xss -> POP f xss -> Bool # (>) :: POP f xss -> POP f xss -> Bool # (>=) :: POP f xss -> POP f xss -> Bool # max :: POP f xss -> POP f xss -> POP f xss # min :: POP f xss -> POP f xss -> POP f xss #
Show (NP (NP f) xss) => Show (POP f xss)
Instance details Defined in Data.SOP.NP Methods showsPrec :: Int -> POP f xss -> ShowS # show :: POP f xss -> String # showList :: [POP f xss] -> ShowS #
Semigroup (NP (NP f) xss) => Semigroup (POP f xss)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.NP Methods (<>) :: POP f xss -> POP f xss -> POP f xss # sconcat :: NonEmpty (POP f xss) -> POP f xss # stimes :: Integral b => b -> POP f xss -> POP f xss #
Monoid (NP (NP f) xss) => Monoid (POP f xss)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.NP Methods mempty :: POP f xss # mappend :: POP f xss -> POP f xss -> POP f xss # mconcat :: [POP f xss] -> POP f xss #
NFData (NP (NP f) xss) => NFData (POP f xss)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.NP Methods rnf :: POP f xss -> () #
type AllZipN (POP :: (k -> Type) -> [[k]] -> Type) (c :: a -> b -> Constraint)
Instance details Defined in Data.SOP.NP type AllZipN (POP :: (k -> Type) -> [[k]] -> Type) (c :: a -> b -> Constraint) = AllZip2 c
type Same (POP :: (k1 -> Type) -> [[k1]] -> Type)
Instance details Defined in Data.SOP.NP type Same (POP :: (k1 -> Type) -> [[k1]] -> Type) = POP :: (k2 -> Type) -> [[k2]] -> Type
type Prod (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP type Prod (POP :: (k -> Type) -> [[k]] -> Type) = POP :: (k -> Type) -> [[k]] -> Type
type UnProd (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS type UnProd (POP :: (k -> Type) -> [[k]] -> Type) = SOP :: (k -> Type) -> [[k]] -> Type
type SListIN (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP type SListIN (POP :: (k -> Type) -> [[k]] -> Type) = SListI2 :: [[k]] -> Constraint
type CollapseTo (POP :: (k -> Type) -> [[k]] -> Type) a
Instance details Defined in Data.SOP.NP type CollapseTo (POP :: (k -> Type) -> [[k]] -> Type) a = [[a]]
type AllN (POP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint)
Instance details Defined in Data.SOP.NP type AllN (POP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint) = All2 c

type Projection (f :: k -> Type) (xs :: [k]) = (K (NP f xs) :: k -> Type) -.-> f Source #

The type of projections from an n-ary product.

A projection is a function from the n-ary product to a single element.

lengthSList :: forall k (xs :: [k]) proxy. SListI xs => proxy xs -> Int Source #

The length of a type-level list.

Since: sop-core-0.2

shape :: forall k (xs :: [k]). SListI xs => Shape xs Source #

The shape of a type-level list.

sList :: forall k (xs :: [k]). SListI xs => SList xs Source #

Get hold of an explicit singleton (that one can then pattern match on) for a type-level list

case_SList :: forall k (xs :: [k]) r. SListI xs => r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). SListI ys => r (y ': ys)) -> r xs Source #

Case distinction on a type-level list.

Since: sop-core-0.4.0.0

para_SList :: forall k (xs :: [k]) r. SListI xs => r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). SListI ys => r ys -> r (y ': ys)) -> r xs Source #

Paramorphism for a type-level list.

Since: sop-core-0.4.0.0

data SList (a :: [k]) where Source #

Explicit singleton list.

A singleton list can be used to reveal the structure of a type-level list argument that the function is quantified over. For every type-level list xs, there is one non-bottom value of type SList xs.

Note that these singleton lists are polymorphic in the list elements; we do not require a singleton representation for them.

Since: sop-core-0.2

Constructors

SNil :: forall k. SList ('[] :: [k])
SCons :: forall k (xs :: [k]) (x :: k). SListI xs => SList (x ': xs)

Instances

Instances details

Eq (SList xs)
Instance details Defined in Data.SOP.Sing Methods (==) :: SList xs -> SList xs -> Bool # (/=) :: SList xs -> SList xs -> Bool #
Ord (SList xs)
Instance details Defined in Data.SOP.Sing Methods compare :: SList xs -> SList xs -> Ordering # (<) :: SList xs -> SList xs -> Bool # (<=) :: SList xs -> SList xs -> Bool # (>) :: SList xs -> SList xs -> Bool # (>=) :: SList xs -> SList xs -> Bool # max :: SList xs -> SList xs -> SList xs # min :: SList xs -> SList xs -> SList xs #
Show (SList xs)
Instance details Defined in Data.SOP.Sing Methods showsPrec :: Int -> SList xs -> ShowS # show :: SList xs -> String # showList :: [SList xs] -> ShowS #

data Shape (a :: [k]) where Source #

Occasionally it is useful to have an explicit, term-level, representation of type-level lists (esp because of https://ghc.haskell.org/trac/ghc/ticket/9108 )

Constructors

ShapeNil :: forall k. Shape ('[] :: [k])
ShapeCons :: forall k (xs :: [k]) (x :: k). SListI xs => Shape xs -> Shape (x ': xs)

Instances

Instances details

Eq (Shape xs)
Instance details Defined in Data.SOP.Sing Methods (==) :: Shape xs -> Shape xs -> Bool # (/=) :: Shape xs -> Shape xs -> Bool #
Ord (Shape xs)
Instance details Defined in Data.SOP.Sing Methods compare :: Shape xs -> Shape xs -> Ordering # (<) :: Shape xs -> Shape xs -> Bool # (<=) :: Shape xs -> Shape xs -> Bool # (>) :: Shape xs -> Shape xs -> Bool # (>=) :: Shape xs -> Shape xs -> Bool # max :: Shape xs -> Shape xs -> Shape xs # min :: Shape xs -> Shape xs -> Shape xs #
Show (Shape xs)
Instance details Defined in Data.SOP.Sing Methods showsPrec :: Int -> Shape xs -> ShowS # show :: Shape xs -> String # showList :: [Shape xs] -> ShowS #

htoI :: forall k1 l1 l2 h1 (f :: k1 -> Type) (xs :: l1) (ys :: l2) h2. (AllZipN (Prod h1) (LiftedCoercible f I) xs ys, HTrans h1 h2) => h1 f xs -> h2 I ys Source #

Specialization of hcoerce.

Since: sop-core-0.3.1.0

hfromI :: forall l1 k2 l2 h1 (f :: k2 -> Type) (xs :: l1) (ys :: l2) h2. (AllZipN (Prod h1) (LiftedCoercible I f) xs ys, HTrans h1 h2) => h1 I xs -> h2 f ys Source #

Specialization of hcoerce.

Since: sop-core-0.3.1.0

hsequenceK :: forall k l h (xs :: l) f a. (SListIN h xs, SListIN (Prod h) xs, Applicative f, HSequence h) => h (K (f a) :: k -> Type) xs -> f (h (K a :: k -> Type) xs) Source #

Special case of hsequence' where g = K a.

hsequence :: forall l h (xs :: l) f. (SListIN h xs, SListIN (Prod h) xs, HSequence h, Applicative f) => h f xs -> f (h I xs) Source #

Special case of hsequence' where g = I.

hcfor :: forall l h c (xs :: l) g proxy f. (HSequence h, AllN h c xs, Applicative g) => proxy c -> h f xs -> (forall a. c a => f a -> g a) -> g (h I xs) Source #

Flipped version of hctraverse.

Since: sop-core-0.3.2.0

hctraverse :: forall l h c (xs :: l) g proxy f. (HSequence h, AllN h c xs, Applicative g) => proxy c -> (forall a. c a => f a -> g a) -> h f xs -> g (h I xs) Source #

Special case of hctraverse' where f' = I.

Since: sop-core-0.3.2.0

hcfoldMap :: forall k l h c (xs :: l) m proxy f. (HTraverse_ h, AllN h c xs, Monoid m) => proxy c -> (forall (a :: k). c a => f a -> m) -> h f xs -> m Source #

Special case of hctraverse_.

Since: sop-core-0.3.2.0

hcfor_ :: forall k l h c (xs :: l) g proxy f. (HTraverse_ h, AllN h c xs, Applicative g) => proxy c -> h f xs -> (forall (a :: k). c a => f a -> g ()) -> g () Source #

Flipped version of hctraverse_.

Since: sop-core-0.3.2.0

hczipWith3 :: forall k l h c (xs :: l) proxy f f' f'' f'''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs Source #

Another name for hcliftA3.

Since: sop-core-0.2

hczipWith :: forall k l h c (xs :: l) proxy f f' f''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs Source #

Another name for hcliftA2.

Since: sop-core-0.2

hcmap :: forall k l h c (xs :: l) proxy f f'. (AllN (Prod h) c xs, HAp h) => proxy c -> (forall (a :: k). c a => f a -> f' a) -> h f xs -> h f' xs Source #

Another name for hcliftA.

Since: sop-core-0.2

hcliftA3 :: forall k l h c (xs :: l) proxy f f' f'' f'''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs Source #

Variant of hcliftA3 that takes a constrained function.

Specification:

hcliftA3 p f xs ys zs = hcpure p (fn_3 f) ` hap ` xs ` hap ` ys ` hap ` zs

hcliftA2 :: forall k l h c (xs :: l) proxy f f' f''. (AllN (Prod h) c xs, HAp h, HAp (Prod h)) => proxy c -> (forall (a :: k). c a => f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs Source #

Variant of hcliftA2 that takes a constrained function.

Specification:

hcliftA2 p f xs ys = hcpure p (fn_2 f) ` hap ` xs ` hap ` ys

hcliftA :: forall k l h c (xs :: l) proxy f f'. (AllN (Prod h) c xs, HAp h) => proxy c -> (forall (a :: k). c a => f a -> f' a) -> h f xs -> h f' xs Source #

Variant of hliftA that takes a constrained function.

Specification:

hcliftA p f xs = hcpure p (fn f) ` hap ` xs

hzipWith3 :: forall k l h (xs :: l) f f' f'' f'''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs Source #

Another name for hliftA3.

Since: sop-core-0.2

hzipWith :: forall k l h (xs :: l) f f' f''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs Source #

Another name for hliftA2.

Since: sop-core-0.2

hmap :: forall k l h (xs :: l) f f'. (SListIN (Prod h) xs, HAp h) => (forall (a :: k). f a -> f' a) -> h f xs -> h f' xs Source #

Another name for hliftA.

Since: sop-core-0.2

hliftA3 :: forall k l h (xs :: l) f f' f'' f'''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a -> f''' a) -> Prod h f xs -> Prod h f' xs -> h f'' xs -> h f''' xs Source #

A generalized form of liftA3, which in turn is a generalized zipWith3.

Takes a lifted ternary function and uses it to combine three structures of equal shape into a single structure.

It either takes three product structures to a product structure, or two product structures and one sum structure to a sum structure.

Specification:

hliftA3 f xs ys zs = hpure (fn_3 f) ` hap ` xs ` hap ` ys ` hap ` zs

Instances:

hliftA3, liftA3_NP  :: SListI  xs  => (forall a. f a -> f' a -> f'' a -> f''' a) -> NP  f xs  -> NP  f' xs  -> NP  f'' xs  -> NP  f''' xs
hliftA3, liftA3_NS  :: SListI  xs  => (forall a. f a -> f' a -> f'' a -> f''' a) -> NP  f xs  -> NP  f' xs  -> NS  f'' xs  -> NS  f''' xs
hliftA3, liftA3_POP :: SListI2 xss => (forall a. f a -> f' a -> f'' a -> f''' a) -> POP f xss -> POP f' xss -> POP f'' xss -> POP f''' xs
hliftA3, liftA3_SOP :: SListI2 xss => (forall a. f a -> f' a -> f'' a -> f''' a) -> POP f xss -> POP f' xss -> SOP f'' xss -> SOP f''' xs

hliftA2 :: forall k l h (xs :: l) f f' f''. (SListIN (Prod h) xs, HAp h, HAp (Prod h)) => (forall (a :: k). f a -> f' a -> f'' a) -> Prod h f xs -> h f' xs -> h f'' xs Source #

A generalized form of liftA2, which in turn is a generalized zipWith.

Takes a lifted binary function and uses it to combine two structures of equal shape into a single structure.

It either takes two product structures to a product structure, or one product and one sum structure to a sum structure.

Specification:

hliftA2 f xs ys = hpure (fn_2 f) ` hap ` xs ` hap ` ys

Instances:

hliftA2, liftA2_NP  :: SListI  xs  => (forall a. f a -> f' a -> f'' a) -> NP  f xs  -> NP  f' xs  -> NP  f'' xs
hliftA2, liftA2_NS  :: SListI  xs  => (forall a. f a -> f' a -> f'' a) -> NP  f xs  -> NS  f' xs  -> NS  f'' xs
hliftA2, liftA2_POP :: SListI2 xss => (forall a. f a -> f' a -> f'' a) -> POP f xss -> POP f' xss -> POP f'' xss
hliftA2, liftA2_SOP :: SListI2 xss => (forall a. f a -> f' a -> f'' a) -> POP f xss -> SOP f' xss -> SOP f'' xss

hliftA :: forall k l h (xs :: l) f f'. (SListIN (Prod h) xs, HAp h) => (forall (a :: k). f a -> f' a) -> h f xs -> h f' xs Source #

A generalized form of liftA, which in turn is a generalized map.

Takes a lifted function and applies it to every element of a structure while preserving its shape.

Specification:

hliftA f xs = hpure (fn f) ` hap ` xs

Instances:

hliftA, liftA_NP  :: SListI  xs  => (forall a. f a -> f' a) -> NP  f xs  -> NP  f' xs
hliftA, liftA_NS  :: SListI  xs  => (forall a. f a -> f' a) -> NS  f xs  -> NS  f' xs
hliftA, liftA_POP :: SListI2 xss => (forall a. f a -> f' a) -> POP f xss -> POP f' xss
hliftA, liftA_SOP :: SListI2 xss => (forall a. f a -> f' a) -> SOP f xss -> SOP f' xss

fn_4 :: forall k f (a :: k) f' f'' f''' f''''. (f a -> f' a -> f'' a -> f''' a -> f'''' a) -> (f -.-> (f' -.-> (f'' -.-> (f''' -.-> f'''')))) a Source #

Construct a quarternary lifted function.

fn_3 :: forall k f (a :: k) f' f'' f'''. (f a -> f' a -> f'' a -> f''' a) -> (f -.-> (f' -.-> (f'' -.-> f'''))) a Source #

Construct a ternary lifted function.

fn_2 :: forall k f (a :: k) f' f''. (f a -> f' a -> f'' a) -> (f -.-> (f' -.-> f'')) a Source #

Construct a binary lifted function.

fn :: forall k f (a :: k) f'. (f a -> f' a) -> (f -.-> f') a Source #

Construct a lifted function.

Same as Fn. Only available for uniformity with the higher-arity versions.

class HPure (h :: (k -> Type) -> l -> Type) where Source #

A generalization of pure or return to higher kinds.

Methods

hpure :: forall (xs :: l) f. SListIN h xs => (forall (a :: k). f a) -> h f xs Source #

Corresponds to pure directly.

Instances:

hpure, pure_NP  :: SListI  xs  => (forall a. f a) -> NP  f xs
hpure, pure_POP :: SListI2 xss => (forall a. f a) -> POP f xss

hcpure :: forall c (xs :: l) proxy f. AllN h c xs => proxy c -> (forall (a :: k). c a => f a) -> h f xs Source #

A variant of hpure that allows passing in a constrained argument.

Calling hcpure f s where s :: h f xs causes f to be applied at all the types that are contained in xs. Therefore, the constraint c has to be satisfied for all elements of xs, which is what AllN h c xs states.

Instances:

hcpure, cpure_NP  :: (All  c xs ) => proxy c -> (forall a. c a => f a) -> NP  f xs
hcpure, cpure_POP :: (All2 c xss) => proxy c -> (forall a. c a => f a) -> POP f xss

Instances

Instances details

HPure (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hpure :: forall (xs :: l) f. SListIN NP xs => (forall (a :: k0). f a) -> NP f xs Source # hcpure :: forall c (xs :: l) proxy f. AllN NP c xs => proxy c -> (forall (a :: k0). c a => f a) -> NP f xs Source #
HPure (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NP Methods hpure :: forall (xs :: l) f. SListIN NP xs => (forall (a :: k0). f a) -> NP f xs Source # hcpure :: forall c (xs :: l) proxy f. AllN NP c xs => proxy c -> (forall (a :: k0). c a => f a) -> NP f xs Source #
HPure (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hpure :: forall (xs :: l) f. SListIN POP xs => (forall (a :: k0). f a) -> POP f xs Source # hcpure :: forall c (xs :: l) proxy f. AllN POP c xs => proxy c -> (forall (a :: k0). c a => f a) -> POP f xs Source #

newtype ((f :: k -> Type) -.-> (g :: k -> Type)) (a :: k) infixr 1 Source #

Lifted functions.

Constructors

Fn
Fields apFn :: f a -> g a

type family Prod (h :: (k -> Type) -> l -> Type) :: (k -> Type) -> l -> Type Source #

Maps a structure containing sums to the corresponding product structure.

Instances

Instances details

type Prod (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict type Prod (NP :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type Prod (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict type Prod (NS :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type Prod (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS type Prod (NS :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type Prod (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS type Prod (SOP :: (k -> Type) -> [[k]] -> Type) = POP :: (k -> Type) -> [[k]] -> Type
type Prod (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NP type Prod (NP :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type Prod (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP type Prod (POP :: (k -> Type) -> [[k]] -> Type) = POP :: (k -> Type) -> [[k]] -> Type
type Prod (SimpleTelescope :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope type Prod (SimpleTelescope :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type Prod (Telescope g :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope type Prod (Telescope g :: (k -> Type) -> [k] -> Type) = NP :: (k -> Type) -> [k] -> Type
type Prod HardForkState Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.State.Instances type Prod HardForkState = NP :: (Type -> Type) -> [Type] -> Type

class (Prod (Prod h) ~ Prod h, HPure (Prod h)) => HAp (h :: (k -> Type) -> l -> Type) where Source #

A generalization of <*>.

Methods

hap :: forall (f :: k -> Type) (g :: k -> Type) (xs :: l). Prod h (f -.-> g) xs -> h f xs -> h g xs Source #

Corresponds to <*>.

For products (NP) as well as products of products (POP), the correspondence is rather direct. We combine a structure containing (lifted) functions and a compatible structure containing corresponding arguments into a compatible structure containing results.

The same combinator can also be used to combine a product structure of functions with a sum structure of arguments, which then results in another sum structure of results. The sum structure determines which part of the product structure will be used.

Instances:

hap, ap_NP  :: NP  (f -.-> g) xs  -> NP  f xs  -> NP  g xs
hap, ap_NS  :: NP  (f -.-> g) xs  -> NS  f xs  -> NS  g xs
hap, ap_POP :: POP (f -.-> g) xss -> POP f xss -> POP g xss
hap, ap_SOP :: POP (f -.-> g) xss -> SOP f xss -> SOP g xss

Instances

Instances details

HAp (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod NP (f -.-> g) xs -> NP f xs -> NP g xs Source #
HAp (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod NS (f -.-> g) xs -> NS f xs -> NS g xs Source #
HAp (SimpleTelescope :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod SimpleTelescope (f -.-> g) xs -> SimpleTelescope f xs -> SimpleTelescope g xs Source #
HAp (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NP Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod NP (f -.-> g) xs -> NP f xs -> NP g xs Source #
HAp (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod SOP (f -.-> g) xs -> SOP f xs -> SOP g xs Source #
HAp (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod NS (f -.-> g) xs -> NS f xs -> NS g xs Source #
HAp (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hap :: forall (f :: k0 -> Type) (g :: k0 -> Type) (xs :: l). Prod POP (f -.-> g) xs -> POP f xs -> POP g xs Source #
HAp (Telescope g :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hap :: forall (f :: k0 -> Type) (g0 :: k0 -> Type) (xs :: l). Prod (Telescope g) (f -.-> g0) xs -> Telescope g f xs -> Telescope g g0 xs Source #
HAp HardForkState Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.State.Instances Methods hap :: forall (f :: k -> Type) (g :: k -> Type) (xs :: l). Prod HardForkState (f -.-> g) xs -> HardForkState f xs -> HardForkState g xs Source #

type family CollapseTo (h :: (k -> Type) -> l -> Type) x Source #

Maps products to lists, and sums to identities.

Instances

Instances details

type CollapseTo (NP :: (k -> Type) -> [k] -> Type) a Source #
Instance details Defined in Data.SOP.Strict type CollapseTo (NP :: (k -> Type) -> [k] -> Type) a = [a]
type CollapseTo (NS :: (k -> Type) -> [k] -> Type) a Source #
Instance details Defined in Data.SOP.Strict type CollapseTo (NS :: (k -> Type) -> [k] -> Type) a = a
type CollapseTo (NS :: (k -> Type) -> [k] -> Type) a
Instance details Defined in Data.SOP.NS type CollapseTo (NS :: (k -> Type) -> [k] -> Type) a = a
type CollapseTo (SOP :: (k -> Type) -> [[k]] -> Type) a
Instance details Defined in Data.SOP.NS type CollapseTo (SOP :: (k -> Type) -> [[k]] -> Type) a = [a]
type CollapseTo (NP :: (k -> Type) -> [k] -> Type) a
Instance details Defined in Data.SOP.NP type CollapseTo (NP :: (k -> Type) -> [k] -> Type) a = [a]
type CollapseTo (POP :: (k -> Type) -> [[k]] -> Type) a
Instance details Defined in Data.SOP.NP type CollapseTo (POP :: (k -> Type) -> [[k]] -> Type) a = [[a]]
type CollapseTo (SimpleTelescope :: (k -> Type) -> [k] -> Type) a Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope type CollapseTo (SimpleTelescope :: (k -> Type) -> [k] -> Type) a = [a]
type CollapseTo HardForkState a Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.State.Instances type CollapseTo HardForkState a = a

class HCollapse (h :: (k -> Type) -> l -> Type) where Source #

A class for collapsing a heterogeneous structure into a homogeneous one.

Methods

hcollapse :: forall (xs :: l) a. SListIN h xs => h (K a :: k -> Type) xs -> CollapseTo h a Source #

Collapse a heterogeneous structure with homogeneous elements into a homogeneous structure.

If a heterogeneous structure is instantiated to the constant functor K, then it is in fact homogeneous. This function maps such a value to a simpler Haskell datatype reflecting that. An NS (K a) contains a single a, and an NP (K a) contains a list of as.

Instances:

hcollapse, collapse_NP  :: NP  (K a) xs  ->  [a]
hcollapse, collapse_NS  :: NS  (K a) xs  ->   a
hcollapse, collapse_POP :: POP (K a) xss -> [[a]]
hcollapse, collapse_SOP :: SOP (K a) xss ->  [a]

Instances

Instances details

HCollapse (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hcollapse :: forall (xs :: l) a. SListIN NP xs => NP (K a) xs -> CollapseTo NP a Source #
HCollapse (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hcollapse :: forall (xs :: l) a. SListIN NS xs => NS (K a) xs -> CollapseTo NS a Source #
HCollapse (SimpleTelescope :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hcollapse :: forall (xs :: l) a. SListIN SimpleTelescope xs => SimpleTelescope (K a) xs -> CollapseTo SimpleTelescope a Source #
HCollapse (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hcollapse :: forall (xs :: l) a. SListIN SOP xs => SOP (K a) xs -> CollapseTo SOP a Source #
HCollapse (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hcollapse :: forall (xs :: l) a. SListIN NS xs => NS (K a) xs -> CollapseTo NS a Source #
HCollapse (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hcollapse :: forall (xs :: l) a. SListIN POP xs => POP (K a) xs -> CollapseTo POP a Source #
HCollapse (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NP Methods hcollapse :: forall (xs :: l) a. SListIN NP xs => NP (K a) xs -> CollapseTo NP a Source #
HCollapse HardForkState Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.State.Instances Methods hcollapse :: forall (xs :: l) a. SListIN HardForkState xs => HardForkState (K a) xs -> CollapseTo HardForkState a Source #

class HTraverse_ (h :: (k -> Type) -> l -> Type) where Source #

A generalization of traverse_ or foldMap.

Since: sop-core-0.3.2.0

Methods

hctraverse_ :: forall c (xs :: l) g proxy f. (AllN h c xs, Applicative g) => proxy c -> (forall (a :: k). c a => f a -> g ()) -> h f xs -> g () Source #

Corresponds to traverse_.

Instances:

hctraverse_, ctraverse__NP  :: (All  c xs , Applicative g) => proxy c -> (forall a. c a => f a -> g ()) -> NP  f xs  -> g ()
hctraverse_, ctraverse__NS  :: (All2 c xs , Applicative g) => proxy c -> (forall a. c a => f a -> g ()) -> NS  f xs  -> g ()
hctraverse_, ctraverse__POP :: (All  c xss, Applicative g) => proxy c -> (forall a. c a => f a -> g ()) -> POP f xss -> g ()
hctraverse_, ctraverse__SOP :: (All2 c xss, Applicative g) => proxy c -> (forall a. c a => f a -> g ()) -> SOP f xss -> g ()

Since: sop-core-0.3.2.0

htraverse_ :: forall (xs :: l) g f. (SListIN h xs, Applicative g) => (forall (a :: k). f a -> g ()) -> h f xs -> g () Source #

Unconstrained version of hctraverse_.

Instances:

traverse_, traverse__NP  :: (SListI  xs , Applicative g) => (forall a. f a -> g ()) -> NP  f xs  -> g ()
traverse_, traverse__NS  :: (SListI  xs , Applicative g) => (forall a. f a -> g ()) -> NS  f xs  -> g ()
traverse_, traverse__POP :: (SListI2 xss, Applicative g) => (forall a. f a -> g ()) -> POP f xss -> g ()
traverse_, traverse__SOP :: (SListI2 xss, Applicative g) => (forall a. f a -> g ()) -> SOP f xss -> g ()

Since: sop-core-0.3.2.0

Instances

Instances details

HTraverse_ (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN NP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> NP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN NP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> NP f xs -> g () Source #
HTraverse_ (SimpleTelescope :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN SimpleTelescope c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> SimpleTelescope f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN SimpleTelescope xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> SimpleTelescope f xs -> g () Source #
HTraverse_ (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN SOP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> SOP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN SOP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> SOP f xs -> g () Source #
HTraverse_ (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN NS c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> NS f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN NS xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> NS f xs -> g () Source #
HTraverse_ (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN POP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> POP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN POP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> POP f xs -> g () Source #
HTraverse_ (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NP Methods hctraverse_ :: forall c (xs :: l) g proxy f. (AllN NP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g ()) -> NP f xs -> g () Source # htraverse_ :: forall (xs :: l) g f. (SListIN NP xs, Applicative g) => (forall (a :: k0). f a -> g ()) -> NP f xs -> g () Source #
HTraverse_ (Telescope g :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hctraverse_ :: forall c (xs :: l) g0 proxy f. (AllN (Telescope g) c xs, Applicative g0) => proxy c -> (forall (a :: k0). c a => f a -> g0 ()) -> Telescope g f xs -> g0 () Source # htraverse_ :: forall (xs :: l) g0 f. (SListIN (Telescope g) xs, Applicative g0) => (forall (a :: k0). f a -> g0 ()) -> Telescope g f xs -> g0 () Source #

class HAp h => HSequence (h :: (k -> Type) -> l -> Type) where Source #

A generalization of sequenceA.

Methods

hsequence' :: forall (xs :: l) f (g :: k -> Type). (SListIN h xs, Applicative f) => h (f :.: g) xs -> f (h g xs) Source #

Corresponds to sequenceA.

Lifts an applicative functor out of a structure.

Instances:

hsequence', sequence'_NP  :: (SListI  xs , Applicative f) => NP  (f :.: g) xs  -> f (NP  g xs )
hsequence', sequence'_NS  :: (SListI  xs , Applicative f) => NS  (f :.: g) xs  -> f (NS  g xs )
hsequence', sequence'_POP :: (SListI2 xss, Applicative f) => POP (f :.: g) xss -> f (POP g xss)
hsequence', sequence'_SOP :: (SListI2 xss, Applicative f) => SOP (f :.: g) xss -> f (SOP g xss)

hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN h c xs, Applicative g) => proxy c -> (forall (a :: k). c a => f a -> g (f' a)) -> h f xs -> g (h f' xs) Source #

Corresponds to traverse.

Instances:

hctraverse', ctraverse'_NP  :: (All  c xs , Applicative g) => proxy c -> (forall a. c a => f a -> g (f' a)) -> NP  f xs  -> g (NP  f' xs )
hctraverse', ctraverse'_NS  :: (All2 c xs , Applicative g) => proxy c -> (forall a. c a => f a -> g (f' a)) -> NS  f xs  -> g (NS  f' xs )
hctraverse', ctraverse'_POP :: (All  c xss, Applicative g) => proxy c -> (forall a. c a => f a -> g (f' a)) -> POP f xss -> g (POP f' xss)
hctraverse', ctraverse'_SOP :: (All2 c xss, Applicative g) => proxy c -> (forall a. c a => f a -> g (f' a)) -> SOP f xss -> g (SOP f' xss)

Since: sop-core-0.3.2.0

htraverse' :: forall (xs :: l) g f f'. (SListIN h xs, Applicative g) => (forall (a :: k). f a -> g (f' a)) -> h f xs -> g (h f' xs) Source #

Unconstrained variant of htraverse`.

Instances:

htraverse', traverse'_NP  :: (SListI  xs , Applicative g) => (forall a. c a => f a -> g (f' a)) -> NP  f xs  -> g (NP  f' xs )
htraverse', traverse'_NS  :: (SListI2 xs , Applicative g) => (forall a. c a => f a -> g (f' a)) -> NS  f xs  -> g (NS  f' xs )
htraverse', traverse'_POP :: (SListI  xss, Applicative g) => (forall a. c a => f a -> g (f' a)) -> POP f xss -> g (POP f' xss)
htraverse', traverse'_SOP :: (SListI2 xss, Applicative g) => (forall a. c a => f a -> g (f' a)) -> SOP f xss -> g (SOP f' xss)

Since: sop-core-0.3.2.0

Instances

Instances details

HSequence (NP :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN NP xs, Applicative f) => NP (f :.: g) xs -> f (NP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN NP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> NP f xs -> g (NP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN NP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> NP f xs -> g (NP f' xs) Source #
HSequence (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN NS xs, Applicative f) => NS (f :.: g) xs -> f (NS g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN NS c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> NS f xs -> g (NS f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN NS xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> NS f xs -> g (NS f' xs) Source #
HSequence (SimpleTelescope :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN SimpleTelescope xs, Applicative f) => SimpleTelescope (f :.: g) xs -> f (SimpleTelescope g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN SimpleTelescope c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> SimpleTelescope f xs -> g (SimpleTelescope f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN SimpleTelescope xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> SimpleTelescope f xs -> g (SimpleTelescope f' xs) Source #
HSequence (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN SOP xs, Applicative f) => SOP (f :.: g) xs -> f (SOP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN SOP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> SOP f xs -> g (SOP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN SOP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> SOP f xs -> g (SOP f' xs) Source #
HSequence (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN NS xs, Applicative f) => NS (f :.: g) xs -> f (NS g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN NS c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> NS f xs -> g (NS f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN NS xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> NS f xs -> g (NS f' xs) Source #
HSequence (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NP Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN POP xs, Applicative f) => POP (f :.: g) xs -> f (POP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN POP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> POP f xs -> g (POP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN POP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> POP f xs -> g (POP f' xs) Source #
HSequence (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NP Methods hsequence' :: forall (xs :: l) f (g :: k0 -> Type). (SListIN NP xs, Applicative f) => NP (f :.: g) xs -> f (NP g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN NP c xs, Applicative g) => proxy c -> (forall (a :: k0). c a => f a -> g (f' a)) -> NP f xs -> g (NP f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN NP xs, Applicative g) => (forall (a :: k0). f a -> g (f' a)) -> NP f xs -> g (NP f' xs) Source #
HSequence (Telescope g :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope Methods hsequence' :: forall (xs :: l) f (g0 :: k0 -> Type). (SListIN (Telescope g) xs, Applicative f) => Telescope g (f :.: g0) xs -> f (Telescope g g0 xs) Source # hctraverse' :: forall c (xs :: l) g0 proxy f f'. (AllN (Telescope g) c xs, Applicative g0) => proxy c -> (forall (a :: k0). c a => f a -> g0 (f' a)) -> Telescope g f xs -> g0 (Telescope g f' xs) Source # htraverse' :: forall (xs :: l) g0 f f'. (SListIN (Telescope g) xs, Applicative g0) => (forall (a :: k0). f a -> g0 (f' a)) -> Telescope g f xs -> g0 (Telescope g f' xs) Source #
HSequence HardForkState Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.State.Instances Methods hsequence' :: forall (xs :: l) f (g :: k -> Type). (SListIN HardForkState xs, Applicative f) => HardForkState (f :.: g) xs -> f (HardForkState g xs) Source # hctraverse' :: forall c (xs :: l) g proxy f f'. (AllN HardForkState c xs, Applicative g) => proxy c -> (forall (a :: k). c a => f a -> g (f' a)) -> HardForkState f xs -> g (HardForkState f' xs) Source # htraverse' :: forall (xs :: l) g f f'. (SListIN HardForkState xs, Applicative g) => (forall (a :: k). f a -> g (f' a)) -> HardForkState f xs -> g (HardForkState f' xs) Source #

class HIndex (h :: (k -> Type) -> l -> Type) where Source #

A class for determining which choice in a sum-like structure a value represents.

Methods

hindex :: forall (f :: k -> Type) (xs :: l). h f xs -> Int Source #

If h is a sum-like structure representing a choice between n different options, and x is a value of type h f xs, then hindex x returns a number between 0 and n - 1 representing the index of the choice made by x.

Instances:

hindex, index_NS  :: NS  f xs -> Int
hindex, index_SOP :: SOP f xs -> Int

Examples:

>>> hindex (S (S (Z (I False))))
2
>>> hindex (Z (K ()))
0
>>> hindex (SOP (S (Z (I True :* I 'x' :* Nil))))
1

Since: sop-core-0.2.4.0

Instances

Instances details

HIndex (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hindex :: forall (f :: k0 -> Type) (xs :: l). SOP f xs -> Int Source #
HIndex (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hindex :: forall (f :: k0 -> Type) (xs :: l). NS f xs -> Int Source #

type family UnProd (h :: (k -> Type) -> l -> Type) :: (k -> Type) -> l -> Type Source #

Maps a structure containing products to the corresponding sum structure.

Since: sop-core-0.2.4.0

Instances

Instances details

type UnProd (NP :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS type UnProd (NP :: (k -> Type) -> [k] -> Type) = NS :: (k -> Type) -> [k] -> Type
type UnProd (POP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS type UnProd (POP :: (k -> Type) -> [[k]] -> Type) = SOP :: (k -> Type) -> [[k]] -> Type

class UnProd (Prod h) ~ h => HApInjs (h :: (k -> Type) -> l -> Type) where Source #

A class for applying all injections corresponding to a sum-like structure to a table containing suitable arguments.

Methods

hapInjs :: forall (xs :: l) (f :: k -> Type). SListIN h xs => Prod h f xs -> [h f xs] Source #

For a given table (product-like structure), produce a list where each element corresponds to the application of an injection function into the corresponding sum-like structure.

Instances:

hapInjs, apInjs_NP  :: SListI  xs  => NP  f xs -> [NS  f xs ]
hapInjs, apInjs_SOP :: SListI2 xss => POP f xs -> [SOP f xss]

Examples:

>>> hapInjs (I 'x' :* I True :* I 2 :* Nil) :: [NS I '[Char, Bool, Int]]
[Z (I 'x'),S (Z (I True)),S (S (Z (I 2)))]

>>> hapInjs (POP ((I 'x' :* Nil) :* (I True :* I 2 :* Nil) :* Nil)) :: [SOP I '[ '[Char], '[Bool, Int]]]
[SOP (Z (I 'x' :* Nil)),SOP (S (Z (I True :* I 2 :* Nil)))]

Unfortunately the type-signatures are required in GHC-7.10 and older.

Since: sop-core-0.2.4.0

Instances

Instances details

HApInjs (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hapInjs :: forall (xs :: l) (f :: k0 -> Type). SListIN SOP xs => Prod SOP f xs -> [SOP f xs] Source #
HApInjs (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hapInjs :: forall (xs :: l) (f :: k0 -> Type). SListIN NS xs => Prod NS f xs -> [NS f xs] Source #

class HExpand (h :: (k -> Type) -> l -> Type) where Source #

A class for expanding sum structures into corresponding product structures, filling in the slots not targeted by the sum with default values.

Since: sop-core-0.2.5.0

Methods

hexpand :: forall (xs :: l) f. SListIN (Prod h) xs => (forall (x :: k). f x) -> h f xs -> Prod h f xs Source #

Expand a given sum structure into a corresponding product structure by placing the value contained in the sum into the corresponding position in the product, and using the given default value for all other positions.

Instances:

hexpand, expand_NS  :: SListI xs   => (forall x . f x) -> NS  f xs  -> NP  f xs
hexpand, expand_SOP :: SListI2 xss => (forall x . f x) -> SOP f xss -> POP f xss

Examples:

>>> hexpand Nothing (S (Z (Just 3))) :: NP Maybe '[Char, Int, Bool]
Nothing :* Just 3 :* Nothing :* Nil
>>> hexpand [] (SOP (S (Z ([1,2] :* "xyz" :* Nil)))) :: POP [] '[ '[Bool], '[Int, Char] ]
POP (([] :* Nil) :* ([1,2] :* "xyz" :* Nil) :* Nil)

Since: sop-core-0.2.5.0

hcexpand :: forall c (xs :: l) proxy f. AllN (Prod h) c xs => proxy c -> (forall (x :: k). c x => f x) -> h f xs -> Prod h f xs Source #

Variant of hexpand that allows passing a constrained default.

Instances:

hcexpand, cexpand_NS  :: All  c xs  => proxy c -> (forall x . c x => f x) -> NS  f xs  -> NP  f xs
hcexpand, cexpand_SOP :: All2 c xss => proxy c -> (forall x . c x => f x) -> SOP f xss -> POP f xss

Examples:

>>> hcexpand (Proxy :: Proxy Bounded) (I minBound) (S (Z (I 20))) :: NP I '[Bool, Int, Ordering]
I False :* I 20 :* I LT :* Nil
>>> hcexpand (Proxy :: Proxy Num) (I 0) (SOP (S (Z (I 1 :* I 2 :* Nil)))) :: POP I '[ '[Double], '[Int, Int] ]
POP ((I 0.0 :* Nil) :* (I 1 :* I 2 :* Nil) :* Nil)

Since: sop-core-0.2.5.0

Instances

Instances details

HExpand (NS :: (k -> Type) -> [k] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods hexpand :: forall (xs :: l) f. SListIN (Prod NS) xs => (forall (x :: k0). f x) -> NS f xs -> Prod NS f xs Source # hcexpand :: forall c (xs :: l) proxy f. AllN (Prod NS) c xs => proxy c -> (forall (x :: k0). c x => f x) -> NS f xs -> Prod NS f xs Source #
HExpand (SOP :: (k -> Type) -> [[k]] -> Type)
Instance details Defined in Data.SOP.NS Methods hexpand :: forall (xs :: l) f. SListIN (Prod SOP) xs => (forall (x :: k0). f x) -> SOP f xs -> Prod SOP f xs Source # hcexpand :: forall c (xs :: l) proxy f. AllN (Prod SOP) c xs => proxy c -> (forall (x :: k0). c x => f x) -> SOP f xs -> Prod SOP f xs Source #
HExpand (NS :: (k -> Type) -> [k] -> Type)
Instance details Defined in Data.SOP.NS Methods hexpand :: forall (xs :: l) f. SListIN (Prod NS) xs => (forall (x :: k0). f x) -> NS f xs -> Prod NS f xs Source # hcexpand :: forall c (xs :: l) proxy f. AllN (Prod NS) c xs => proxy c -> (forall (x :: k0). c x => f x) -> NS f xs -> Prod NS f xs Source #

class ((Same h1 :: (k2 -> Type) -> l2 -> Type) ~ h2, (Same h2 :: (k1 -> Type) -> l1 -> Type) ~ h1) => HTrans (h1 :: (k1 -> Type) -> l1 -> Type) (h2 :: (k2 -> Type) -> l2 -> Type) where Source #

A class for transforming structures into related structures with a different index list, as long as the index lists have the same shape and the elements and interpretation functions are suitably related.

Since: sop-core-0.3.1.0

Methods

htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod h1) c xs ys => proxy c -> (forall (x :: k1) (y :: k2). c x y => f x -> g y) -> h1 f xs -> h2 g ys Source #

Transform a structure into a related structure given a conversion function for the elements.

Since: sop-core-0.3.1.0

hcoerce :: forall (f :: k1 -> Type) (g :: k2 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod h1) (LiftedCoercible f g) xs ys => h1 f xs -> h2 g ys Source #

Safely coerce a structure into a representationally equal structure.

This is a special case of htrans, but can be implemented more efficiently; for example in terms of unsafeCoerce.

Examples:

>>> hcoerce (I (Just LT) :* I (Just 'x') :* I (Just True) :* Nil) :: NP Maybe '[Ordering, Char, Bool]
Just LT :* Just 'x' :* Just True :* Nil
>>> hcoerce (SOP (Z (K True :* K False :* Nil))) :: SOP I '[ '[Bool, Bool], '[Bool] ]
SOP (Z (I True :* I False :* Nil))

Since: sop-core-0.3.1.0

Instances

Instances details

HTrans (NS :: (k1 -> Type) -> [k1] -> Type) (NS :: (k2 -> Type) -> [k2] -> Type) Source #
Instance details Defined in Data.SOP.Strict Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod NS) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> NS f xs -> NS g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod NS) (LiftedCoercible f g) xs ys => NS f xs -> NS g ys Source #
HTrans (SOP :: (k1 -> Type) -> [[k1]] -> Type) (SOP :: (k2 -> Type) -> [[k2]] -> Type)
Instance details Defined in Data.SOP.NS Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod SOP) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> SOP f xs -> SOP g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod SOP) (LiftedCoercible f g) xs ys => SOP f xs -> SOP g ys Source #
HTrans (NS :: (k1 -> Type) -> [k1] -> Type) (NS :: (k2 -> Type) -> [k2] -> Type)
Instance details Defined in Data.SOP.NS Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod NS) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> NS f xs -> NS g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod NS) (LiftedCoercible f g) xs ys => NS f xs -> NS g ys Source #
HTrans (POP :: (k1 -> Type) -> [[k1]] -> Type) (POP :: (k2 -> Type) -> [[k2]] -> Type)
Instance details Defined in Data.SOP.NP Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod POP) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> POP f xs -> POP g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod POP) (LiftedCoercible f g) xs ys => POP f xs -> POP g ys Source #
HTrans (NP :: (k1 -> Type) -> [k1] -> Type) (NP :: (k2 -> Type) -> [k2] -> Type)
Instance details Defined in Data.SOP.NP Methods htrans :: forall c (xs :: l1) (ys :: l2) proxy f g. AllZipN (Prod NP) c xs ys => proxy c -> (forall (x :: k10) (y :: k20). c x y => f x -> g y) -> NP f xs -> NP g ys Source # hcoerce :: forall (f :: k10 -> Type) (g :: k20 -> Type) (xs :: l1) (ys :: l2). AllZipN (Prod NP) (LiftedCoercible f g) xs ys => NP f xs -> NP g ys Source #

ccase_SList :: forall k c (xs :: [k]) proxy r. All c xs => proxy c -> r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). (c y, All c ys) => r (y ': ys)) -> r xs Source #

Constrained case distinction on a type-level list.

Since: sop-core-0.4.0.0

class (AllF c xs, SListI xs) => All (c :: k -> Constraint) (xs :: [k]) where Source #

Require a constraint for every element of a list.

If you have a datatype that is indexed over a type-level list, then you can use All to indicate that all elements of that type-level list must satisfy a given constraint.

Example: The constraint

All Eq '[ Int, Bool, Char ]

is equivalent to the constraint

(Eq Int, Eq Bool, Eq Char)

Example: A type signature such as

f :: All Eq xs => NP I xs -> ...

means that f can assume that all elements of the n-ary product satisfy Eq.

Note on superclasses: ghc cannot deduce superclasses from All constraints. You might expect the following to compile

class (Eq a) => MyClass a

foo :: (All Eq xs) => NP f xs -> z
foo = [..]

bar :: (All MyClass xs) => NP f xs -> x
bar = foo

but it will fail with an error saying that it was unable to deduce the class constraint AllF Eq xs (or similar) in the definition of bar. In cases like this you can use Dict from Data.SOP.Dict to prove conversions between constraints. See this answer on SO for more details.

Methods

cpara_SList :: proxy c -> r ('[] :: [k]) -> (forall (y :: k) (ys :: [k]). (c y, All c ys) => r ys -> r (y ': ys)) -> r xs Source #

Constrained paramorphism for a type-level list.

The advantage of writing functions in terms of cpara_SList is that they are then typically not recursive, and can be unfolded statically if the type-level list is statically known.

Since: sop-core-0.4.0.0

Instances

Instances details

All (c :: k -> Constraint) ('[] :: [k])
Instance details Defined in Data.SOP.Constraint Methods cpara_SList :: proxy c -> r '[] -> (forall (y :: k0) (ys :: [k0]). (c y, All c ys) => r ys -> r (y ': ys)) -> r '[] Source #
(c x, All c xs) => All (c :: a -> Constraint) (x ': xs :: [a])
Instance details Defined in Data.SOP.Constraint Methods cpara_SList :: proxy c -> r '[] -> (forall (y :: k) (ys :: [k]). (c y, All c ys) => r ys -> r (y ': ys)) -> r (x ': xs) Source #

type SListI2 = All (SListI :: [k] -> Constraint) Source #

Require a singleton for every inner list in a list of lists.

type SListI = All (Top :: k -> Constraint) Source #

Implicit singleton list.

A singleton list can be used to reveal the structure of a type-level list argument that the function is quantified over.

Since 0.4.0.0, this is now defined in terms of All. A singleton list provides a witness for a type-level list where the elements need not satisfy any additional constraints.

Since: sop-core-0.4.0.0

type All2 (c :: k -> Constraint) = All (All c) Source #

Require a constraint for every element of a list of lists.

If you have a datatype that is indexed over a type-level list of lists, then you can use All2 to indicate that all elements of the inner lists must satisfy a given constraint.

Example: The constraint

All2 Eq '[ '[ Int ], '[ Bool, Char ] ]

is equivalent to the constraint

(Eq Int, Eq Bool, Eq Char)

Example: A type signature such as

f :: All2 Eq xss => SOP I xs -> ...

means that f can assume that all elements of the sum of product satisfy Eq.

Since 0.4.0.0, this is merely a synonym for 'All (All c)'.

Since: sop-core-0.4.0.0

class (SListI xs, SListI ys, SameShapeAs xs ys, SameShapeAs ys xs, AllZipF c xs ys) => AllZip (c :: a -> b -> Constraint) (xs :: [a]) (ys :: [b]) Source #

Require a constraint pointwise for every pair of elements from two lists.

Example: The constraint

All (~) '[ Int, Bool, Char ] '[ a, b, c ]

is equivalent to the constraint

(Int ~ a, Bool ~ b, Char ~ c)

Since: sop-core-0.3.1.0

Instances

Instances details

(SListI xs, SListI ys, SameShapeAs xs ys, SameShapeAs ys xs, AllZipF c xs ys) => AllZip (c :: a -> b -> Constraint) (xs :: [a]) (ys :: [b])
Instance details Defined in Data.SOP.Constraint

type family SameShapeAs (xs :: [a]) (ys :: [b]) where ... Source #

Type family that forces a type-level list to be of the same shape as the given type-level list.

Since 0.5.0.0, this only tests the top-level structure of the list, and is intended to be used in conjunction with a separate construct (such as the AllZip, AllZipF combination to tie the recursive knot). The reason is that making SameShapeAs directly recursive leads to quadratic compile times.

The main use of this constraint is to help type inference to learn something about otherwise unknown type-level lists.

Since: sop-core-0.5.0.0

Equations

SameShapeAs ('[] :: [a]) (ys :: [b]) = ys ~ ('[] :: [b])
SameShapeAs (x ': xs :: [a1]) (ys :: [a2]) = ys ~ (Head ys ': Tail ys)

class Coercible (f x) (g y) => LiftedCoercible (f :: k -> k1) (g :: k2 -> k1) (x :: k) (y :: k2) Source #

The constraint LiftedCoercible f g x y is equivalent to Coercible (f x) (g y).

Since: sop-core-0.3.1.0

Instances

Instances details

Coercible (f x) (g y) => LiftedCoercible (f :: k1 -> k2) (g :: k3 -> k2) (x :: k1) (y :: k3)
Instance details Defined in Data.SOP.Constraint

class (AllZipF (AllZip f) xss yss, SListI xss, SListI yss, SameShapeAs xss yss, SameShapeAs yss xss) => AllZip2 (f :: a -> b -> Constraint) (xss :: [[a]]) (yss :: [[b]]) Source #

Require a constraint pointwise for every pair of elements from two lists of lists.

Instances

Instances details

(AllZipF (AllZip f) xss yss, SListI xss, SListI yss, SameShapeAs xss yss, SameShapeAs yss xss) => AllZip2 (f :: a -> b -> Constraint) (xss :: [[a]]) (yss :: [[b]])
Instance details Defined in Data.SOP.Constraint

class f (g x) => Compose (f :: k -> Constraint) (g :: k1 -> k) (x :: k1) infixr 9 Source #

Composition of constraints.

Note that the result of the composition must be a constraint, and therefore, in Compose f g, the kind of f is k -> Constraint. The kind of g, however, is l -> k and can thus be a normal type constructor.

A typical use case is in connection with All on an NP or an NS. For example, in order to denote that all elements on an NP f xs satisfy Show, we can say All (Compose Show f) xs.

Since: sop-core-0.2

Instances

Instances details

f (g x) => Compose (f :: k1 -> Constraint) (g :: k2 -> k1) (x :: k2)
Instance details Defined in Data.SOP.Constraint

class (f x, g x) => And (f :: k -> Constraint) (g :: k -> Constraint) (x :: k) infixl 7 Source #

Pairing of constraints.

Since: sop-core-0.2

Instances

Instances details

(f x, g x) => And (f :: k -> Constraint) (g :: k -> Constraint) (x :: k)
Instance details Defined in Data.SOP.Constraint

class Top (x :: k) Source #

A constraint that can always be satisfied.

Since: sop-core-0.2

Instances

Instances details

Top (x :: k)
Instance details Defined in Data.SOP.Constraint

type family AllN (h :: (k -> Type) -> l -> Type) (c :: k -> Constraint) :: l -> Constraint Source #

A generalization of All and All2.

The family AllN expands to All or All2 depending on whether the argument is indexed by a list or a list of lists.

Instances

Instances details

type AllN (NP :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) Source #
Instance details Defined in Data.SOP.Strict type AllN (NP :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c
type AllN (NS :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) Source #
Instance details Defined in Data.SOP.Strict type AllN (NS :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c
type AllN (NS :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint)
Instance details Defined in Data.SOP.NS type AllN (NS :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c
type AllN (SOP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint)
Instance details Defined in Data.SOP.NS type AllN (SOP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint) = All2 c
type AllN (NP :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint)
Instance details Defined in Data.SOP.NP type AllN (NP :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c
type AllN (POP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint)
Instance details Defined in Data.SOP.NP type AllN (POP :: (k -> Type) -> [[k]] -> Type) (c :: k -> Constraint) = All2 c
type AllN (SimpleTelescope :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope type AllN (SimpleTelescope :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c
type AllN (Telescope g :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Util.Telescope type AllN (Telescope g :: (k -> Type) -> [k] -> Type) (c :: k -> Constraint) = All c
type AllN HardForkState (c :: Type -> Constraint) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.State.Instances type AllN HardForkState (c :: Type -> Constraint) = All c

type family AllZipN (h :: (k -> Type) -> l -> Type) (c :: k1 -> k2 -> Constraint) :: l1 -> l2 -> Constraint Source #

A generalization of AllZip and AllZip2.

The family AllZipN expands to AllZip or AllZip2 depending on whther the argument is indexed by a list or a list of lists.

Instances

Instances details

type AllZipN (NP :: (k -> Type) -> [k] -> Type) (c :: a -> b -> Constraint) Source #
Instance details Defined in Data.SOP.Strict type AllZipN (NP :: (k -> Type) -> [k] -> Type) (c :: a -> b -> Constraint) = AllZip c
type AllZipN (NP :: (k -> Type) -> [k] -> Type) (c :: a -> b -> Constraint)
Instance details Defined in Data.SOP.NP type AllZipN (NP :: (k -> Type) -> [k] -> Type) (c :: a -> b -> Constraint) = AllZip c
type AllZipN (POP :: (k -> Type) -> [[k]] -> Type) (c :: a -> b -> Constraint)
Instance details Defined in Data.SOP.NP type AllZipN (POP :: (k -> Type) -> [[k]] -> Type) (c :: a -> b -> Constraint) = AllZip2 c

mapKKK :: forall k1 k2 k3 a b c (d :: k1) (e :: k2) (f :: k3). (a -> b -> c) -> K a d -> K b e -> K c f Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapKKI :: forall k1 k2 a b c (d :: k1) (e :: k2). (a -> b -> c) -> K a d -> K b e -> I c Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapKIK :: forall k1 k2 a b c (d :: k1) (e :: k2). (a -> b -> c) -> K a d -> I b -> K c e Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapKII :: forall k a b c (d :: k). (a -> b -> c) -> K a d -> I b -> I c Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapIKK :: forall k1 k2 a b c (d :: k1) (e :: k2). (a -> b -> c) -> I a -> K b d -> K c e Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapIKI :: forall k a b c (d :: k). (a -> b -> c) -> I a -> K b d -> I c Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapIIK :: forall k a b c (d :: k). (a -> b -> c) -> I a -> I b -> K c d Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapIII :: (a -> b -> c) -> I a -> I b -> I c Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapKK :: forall k1 k2 a b (c :: k1) (d :: k2). (a -> b) -> K a c -> K b d Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapKI :: forall k a b (c :: k). (a -> b) -> K a c -> I b Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapIK :: forall k a b (c :: k). (a -> b) -> I a -> K b c Source #

Lift the given function.

Since: sop-core-0.2.5.0

mapII :: (a -> b) -> I a -> I b Source #

Lift the given function.

Since: sop-core-0.2.5.0

unComp :: forall l k f (g :: k -> l) (p :: k). (f :.: g) p -> f (g p) Source #

Extract the contents of a Comp value.

unI :: I a -> a Source #

Extract the contents of an I value.

unK :: forall k a (b :: k). K a b -> a Source #

Extract the contents of a K value.

newtype K a (b :: k) Source #

The constant type functor.

Like Constant, but kind-polymorphic in its second argument and with a shorter name.

Constructors

K a

Instances

Instances details

Show (Ticked a) => Show (Ticked (K a x)) Source #
Instance details Defined in Ouroboros.Consensus.Ticked Methods showsPrec :: Int -> Ticked (K a x) -> ShowS # show :: Ticked (K a x) -> String # showList :: [Ticked (K a x)] -> ShowS #
(SListI xs, Show (Ticked a)) => Show (Ticked (HardForkLedgerView_ (K a :: Type -> Type) xs)) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Protocol.LedgerView Methods showsPrec :: Int -> Ticked (HardForkLedgerView_ (K a) xs) -> ShowS # show :: Ticked (HardForkLedgerView_ (K a) xs) -> String # showList :: [Ticked (HardForkLedgerView_ (K a) xs)] -> ShowS #
Eq2 (K :: Type -> Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftEq2 :: (a -> b -> Bool) -> (c -> d -> Bool) -> K a c -> K b d -> Bool #
Ord2 (K :: Type -> Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftCompare2 :: (a -> b -> Ordering) -> (c -> d -> Ordering) -> K a c -> K b d -> Ordering #
Read2 (K :: Type -> Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftReadsPrec2 :: (Int -> ReadS a) -> ReadS [a] -> (Int -> ReadS b) -> ReadS [b] -> Int -> ReadS (K a b) # liftReadList2 :: (Int -> ReadS a) -> ReadS [a] -> (Int -> ReadS b) -> ReadS [b] -> ReadS [K a b] # liftReadPrec2 :: ReadPrec a -> ReadPrec [a] -> ReadPrec b -> ReadPrec [b] -> ReadPrec (K a b) # liftReadListPrec2 :: ReadPrec a -> ReadPrec [a] -> ReadPrec b -> ReadPrec [b] -> ReadPrec [K a b] #
Show2 (K :: Type -> Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftShowsPrec2 :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> (Int -> b -> ShowS) -> ([b] -> ShowS) -> Int -> K a b -> ShowS # liftShowList2 :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> (Int -> b -> ShowS) -> ([b] -> ShowS) -> [K a b] -> ShowS #
NFData2 (K :: Type -> Type -> Type)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftRnf2 :: (a -> ()) -> (b -> ()) -> K a b -> () #
Functor (K a :: Type -> Type)
Instance details Defined in Data.SOP.BasicFunctors Methods fmap :: (a0 -> b) -> K a a0 -> K a b # (<$) :: a0 -> K a b -> K a a0 #
(SListI xs, Show a) => Show (HardForkLedgerView_ (K a :: Type -> Type) xs) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Protocol.LedgerView Methods showsPrec :: Int -> HardForkLedgerView_ (K a) xs -> ShowS # show :: HardForkLedgerView_ (K a) xs -> String # showList :: [HardForkLedgerView_ (K a) xs] -> ShowS #
Monoid a => Applicative (K a :: Type -> Type)
Instance details Defined in Data.SOP.BasicFunctors Methods pure :: a0 -> K a a0 # (<>) :: K a (a0 -> b) -> K a a0 -> K a b # liftA2 :: (a0 -> b -> c) -> K a a0 -> K a b -> K a c # (>) :: K a a0 -> K a b -> K a b # (<*) :: K a a0 -> K a b -> K a a0 #
Foldable (K a :: Type -> Type)
Instance details Defined in Data.SOP.BasicFunctors Methods fold :: Monoid m => K a m -> m # foldMap :: Monoid m => (a0 -> m) -> K a a0 -> m # foldMap' :: Monoid m => (a0 -> m) -> K a a0 -> m # foldr :: (a0 -> b -> b) -> b -> K a a0 -> b # foldr' :: (a0 -> b -> b) -> b -> K a a0 -> b # foldl :: (b -> a0 -> b) -> b -> K a a0 -> b # foldl' :: (b -> a0 -> b) -> b -> K a a0 -> b # foldr1 :: (a0 -> a0 -> a0) -> K a a0 -> a0 # foldl1 :: (a0 -> a0 -> a0) -> K a a0 -> a0 # toList :: K a a0 -> [a0] # null :: K a a0 -> Bool # length :: K a a0 -> Int # elem :: Eq a0 => a0 -> K a a0 -> Bool # maximum :: Ord a0 => K a a0 -> a0 # minimum :: Ord a0 => K a a0 -> a0 # sum :: Num a0 => K a a0 -> a0 # product :: Num a0 => K a a0 -> a0 #
Traversable (K a :: Type -> Type)
Instance details Defined in Data.SOP.BasicFunctors Methods traverse :: Applicative f => (a0 -> f b) -> K a a0 -> f (K a b) # sequenceA :: Applicative f => K a (f a0) -> f (K a a0) # mapM :: Monad m => (a0 -> m b) -> K a a0 -> m (K a b) # sequence :: Monad m => K a (m a0) -> m (K a a0) #
Eq a => Eq1 (K a :: Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftEq :: (a0 -> b -> Bool) -> K a a0 -> K a b -> Bool #
Ord a => Ord1 (K a :: Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftCompare :: (a0 -> b -> Ordering) -> K a a0 -> K a b -> Ordering #
Read a => Read1 (K a :: Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftReadsPrec :: (Int -> ReadS a0) -> ReadS [a0] -> Int -> ReadS (K a a0) # liftReadList :: (Int -> ReadS a0) -> ReadS [a0] -> ReadS [K a a0] # liftReadPrec :: ReadPrec a0 -> ReadPrec [a0] -> ReadPrec (K a a0) # liftReadListPrec :: ReadPrec a0 -> ReadPrec [a0] -> ReadPrec [K a a0] #
Show a => Show1 (K a :: Type -> Type)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftShowsPrec :: (Int -> a0 -> ShowS) -> ([a0] -> ShowS) -> Int -> K a a0 -> ShowS # liftShowList :: (Int -> a0 -> ShowS) -> ([a0] -> ShowS) -> [K a a0] -> ShowS #
NFData a => NFData1 (K a :: Type -> Type)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftRnf :: (a0 -> ()) -> K a a0 -> () #
Eq a => Eq (K a b)
Instance details Defined in Data.SOP.BasicFunctors Methods (==) :: K a b -> K a b -> Bool # (/=) :: K a b -> K a b -> Bool #
Ord a => Ord (K a b)
Instance details Defined in Data.SOP.BasicFunctors Methods compare :: K a b -> K a b -> Ordering # (<) :: K a b -> K a b -> Bool # (<=) :: K a b -> K a b -> Bool # (>) :: K a b -> K a b -> Bool # (>=) :: K a b -> K a b -> Bool # max :: K a b -> K a b -> K a b # min :: K a b -> K a b -> K a b #
Read a => Read (K a b)
Instance details Defined in Data.SOP.BasicFunctors Methods readsPrec :: Int -> ReadS (K a b) # readList :: ReadS [K a b] # readPrec :: ReadPrec (K a b) # readListPrec :: ReadPrec [K a b] #
Show a => Show (K a b)
Instance details Defined in Data.SOP.BasicFunctors Methods showsPrec :: Int -> K a b -> ShowS # show :: K a b -> String # showList :: [K a b] -> ShowS #
Generic (K a b)
Instance details Defined in Data.SOP.BasicFunctors Associated Types type Rep (K a b) :: Type -> Type # Methods from :: K a b -> Rep (K a b) x # to :: Rep (K a b) x -> K a b #
Semigroup a => Semigroup (K a b)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.BasicFunctors Methods (<>) :: K a b -> K a b -> K a b # sconcat :: NonEmpty (K a b) -> K a b # stimes :: Integral b0 => b0 -> K a b -> K a b #
Monoid a => Monoid (K a b)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.BasicFunctors Methods mempty :: K a b # mappend :: K a b -> K a b -> K a b # mconcat :: [K a b] -> K a b #
NFData a => NFData (K a b)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods rnf :: K a b -> () #
NoThunks a => NoThunks (K a b) Source #
Instance details Defined in Ouroboros.Consensus.Util.Orphans Methods noThunks :: Context -> K a b -> IO (Maybe ThunkInfo) Source # wNoThunks :: Context -> K a b -> IO (Maybe ThunkInfo) Source # showTypeOf :: Proxy (K a b) -> String Source #
type Rep (K a b)
Instance details Defined in Data.SOP.BasicFunctors type Rep (K a b) = D1 ('MetaData "K" "Data.SOP.BasicFunctors" "sop-core-0.5.0.1-LSgc1wfRk3m3wHkiLjj5ug" 'True) (C1 ('MetaCons "K" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 a)))
newtype Ticked (K a x) Source #
Instance details Defined in Ouroboros.Consensus.Ticked newtype Ticked (K a x) = TickedK { getTickedK :: Ticked a }

newtype I a Source #

The identity type functor.

Like Identity, but with a shorter name.

Constructors

I a

Instances

Instances details

Monad I
Instance details Defined in Data.SOP.BasicFunctors Methods (>>=) :: I a -> (a -> I b) -> I b # (>>) :: I a -> I b -> I b # return :: a -> I a #
Functor I
Instance details Defined in Data.SOP.BasicFunctors Methods fmap :: (a -> b) -> I a -> I b # (<$) :: a -> I b -> I a #
Applicative I
Instance details Defined in Data.SOP.BasicFunctors Methods pure :: a -> I a # (<>) :: I (a -> b) -> I a -> I b # liftA2 :: (a -> b -> c) -> I a -> I b -> I c # (>) :: I a -> I b -> I b # (<*) :: I a -> I b -> I a #
Foldable I
Instance details Defined in Data.SOP.BasicFunctors Methods fold :: Monoid m => I m -> m # foldMap :: Monoid m => (a -> m) -> I a -> m # foldMap' :: Monoid m => (a -> m) -> I a -> m # foldr :: (a -> b -> b) -> b -> I a -> b # foldr' :: (a -> b -> b) -> b -> I a -> b # foldl :: (b -> a -> b) -> b -> I a -> b # foldl' :: (b -> a -> b) -> b -> I a -> b # foldr1 :: (a -> a -> a) -> I a -> a # foldl1 :: (a -> a -> a) -> I a -> a # toList :: I a -> [a] # null :: I a -> Bool # length :: I a -> Int # elem :: Eq a => a -> I a -> Bool # maximum :: Ord a => I a -> a # minimum :: Ord a => I a -> a # sum :: Num a => I a -> a # product :: Num a => I a -> a #
Traversable I
Instance details Defined in Data.SOP.BasicFunctors Methods traverse :: Applicative f => (a -> f b) -> I a -> f (I b) # sequenceA :: Applicative f => I (f a) -> f (I a) # mapM :: Monad m => (a -> m b) -> I a -> m (I b) # sequence :: Monad m => I (m a) -> m (I a) #
Eq1 I	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftEq :: (a -> b -> Bool) -> I a -> I b -> Bool #
Ord1 I	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftCompare :: (a -> b -> Ordering) -> I a -> I b -> Ordering #
Read1 I	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftReadsPrec :: (Int -> ReadS a) -> ReadS [a] -> Int -> ReadS (I a) # liftReadList :: (Int -> ReadS a) -> ReadS [a] -> ReadS [I a] # liftReadPrec :: ReadPrec a -> ReadPrec [a] -> ReadPrec (I a) # liftReadListPrec :: ReadPrec a -> ReadPrec [a] -> ReadPrec [I a] #
Show1 I	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftShowsPrec :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> Int -> I a -> ShowS # liftShowList :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> [I a] -> ShowS #
NFData1 I	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftRnf :: (a -> ()) -> I a -> () #
Isomorphic I Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Unary Methods project :: NoHardForks blk => I (HardForkBlock '[blk]) -> I blk Source # inject :: NoHardForks blk => I blk -> I (HardForkBlock '[blk]) Source #
DecodeDisk blk blk => DecodeDisk blk (I blk) Source #
Instance details Defined in Ouroboros.Consensus.Storage.Serialisation Methods decodeDisk :: CodecConfig blk -> forall s. Decoder s (I blk) Source #
(DecodeDiskDepIx f blk, DecodeDiskDep f blk) => DecodeDisk blk (DepPair (f blk)) Source #
Instance details Defined in Ouroboros.Consensus.Storage.Serialisation Methods decodeDisk :: CodecConfig blk -> forall s. Decoder s (DepPair (f blk)) Source #
EncodeDisk blk blk => EncodeDisk blk (I blk) Source #
Instance details Defined in Ouroboros.Consensus.Storage.Serialisation Methods encodeDisk :: CodecConfig blk -> I blk -> Encoding Source #
(EncodeDiskDepIx f blk, EncodeDiskDep f blk) => EncodeDisk blk (DepPair (f blk)) Source #
Instance details Defined in Ouroboros.Consensus.Storage.Serialisation Methods encodeDisk :: CodecConfig blk -> DepPair (f blk) -> Encoding Source #
SerialiseNodeToClient blk blk => SerialiseNodeToClient blk (I blk) Source #
Instance details Defined in Ouroboros.Consensus.Node.Serialisation Methods encodeNodeToClient :: CodecConfig blk -> BlockNodeToClientVersion blk -> I blk -> Encoding Source # decodeNodeToClient :: CodecConfig blk -> BlockNodeToClientVersion blk -> forall s. Decoder s (I blk) Source #
SerialiseNodeToNode blk blk => SerialiseNodeToNode blk (I blk) Source #
Instance details Defined in Ouroboros.Consensus.Node.Serialisation Methods encodeNodeToNode :: CodecConfig blk -> BlockNodeToNodeVersion blk -> I blk -> Encoding Source # decodeNodeToNode :: CodecConfig blk -> BlockNodeToNodeVersion blk -> forall s. Decoder s (I blk) Source #
Eq a => Eq (I a)
Instance details Defined in Data.SOP.BasicFunctors Methods (==) :: I a -> I a -> Bool # (/=) :: I a -> I a -> Bool #
Ord a => Ord (I a)
Instance details Defined in Data.SOP.BasicFunctors Methods compare :: I a -> I a -> Ordering # (<) :: I a -> I a -> Bool # (<=) :: I a -> I a -> Bool # (>) :: I a -> I a -> Bool # (>=) :: I a -> I a -> Bool # max :: I a -> I a -> I a # min :: I a -> I a -> I a #
Read a => Read (I a)
Instance details Defined in Data.SOP.BasicFunctors Methods readsPrec :: Int -> ReadS (I a) # readList :: ReadS [I a] # readPrec :: ReadPrec (I a) # readListPrec :: ReadPrec [I a] #
Show a => Show (I a)
Instance details Defined in Data.SOP.BasicFunctors Methods showsPrec :: Int -> I a -> ShowS # show :: I a -> String # showList :: [I a] -> ShowS #
Generic (I a)
Instance details Defined in Data.SOP.BasicFunctors Associated Types type Rep (I a) :: Type -> Type # Methods from :: I a -> Rep (I a) x # to :: Rep (I a) x -> I a #
Semigroup a => Semigroup (I a)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.BasicFunctors Methods (<>) :: I a -> I a -> I a # sconcat :: NonEmpty (I a) -> I a # stimes :: Integral b => b -> I a -> I a #
Monoid a => Monoid (I a)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.BasicFunctors Methods mempty :: I a # mappend :: I a -> I a -> I a # mconcat :: [I a] -> I a #
NFData a => NFData (I a)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods rnf :: I a -> () #
Condense a => Condense (I a) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Condense Methods condense :: I a -> String Source #
type Rep (I a)
Instance details Defined in Data.SOP.BasicFunctors type Rep (I a) = D1 ('MetaData "I" "Data.SOP.BasicFunctors" "sop-core-0.5.0.1-LSgc1wfRk3m3wHkiLjj5ug" 'True) (C1 ('MetaCons "I" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 a)))

newtype ((f :: l -> Type) :.: (g :: k -> l)) (p :: k) infixr 7 Source #

Composition of functors.

Like Compose, but kind-polymorphic and with a shorter name.

Constructors

Comp (f (g p))

Instances

Instances details

DecodeDisk blk (a -> f blk) => DecodeDisk blk ((((->) a :: Type -> Type) :.: f) blk) Source #
Instance details Defined in Ouroboros.Consensus.Storage.Serialisation Methods decodeDisk :: CodecConfig blk -> forall s. Decoder s (((->) a :.: f) blk) Source #
(Functor f, Functor g) => Functor (f :.: g)
Instance details Defined in Data.SOP.BasicFunctors Methods fmap :: (a -> b) -> (f :.: g) a -> (f :.: g) b # (<$) :: a -> (f :.: g) b -> (f :.: g) a #
(Applicative f, Applicative g) => Applicative (f :.: g)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods pure :: a -> (f :.: g) a # (<>) :: (f :.: g) (a -> b) -> (f :.: g) a -> (f :.: g) b # liftA2 :: (a -> b -> c) -> (f :.: g) a -> (f :.: g) b -> (f :.: g) c # (>) :: (f :.: g) a -> (f :.: g) b -> (f :.: g) b # (<*) :: (f :.: g) a -> (f :.: g) b -> (f :.: g) a #
(Foldable f, Foldable g) => Foldable (f :.: g)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods fold :: Monoid m => (f :.: g) m -> m # foldMap :: Monoid m => (a -> m) -> (f :.: g) a -> m # foldMap' :: Monoid m => (a -> m) -> (f :.: g) a -> m # foldr :: (a -> b -> b) -> b -> (f :.: g) a -> b # foldr' :: (a -> b -> b) -> b -> (f :.: g) a -> b # foldl :: (b -> a -> b) -> b -> (f :.: g) a -> b # foldl' :: (b -> a -> b) -> b -> (f :.: g) a -> b # foldr1 :: (a -> a -> a) -> (f :.: g) a -> a # foldl1 :: (a -> a -> a) -> (f :.: g) a -> a # toList :: (f :.: g) a -> [a] # null :: (f :.: g) a -> Bool # length :: (f :.: g) a -> Int # elem :: Eq a => a -> (f :.: g) a -> Bool # maximum :: Ord a => (f :.: g) a -> a # minimum :: Ord a => (f :.: g) a -> a # sum :: Num a => (f :.: g) a -> a # product :: Num a => (f :.: g) a -> a #
(Traversable f, Traversable g) => Traversable (f :.: g)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods traverse :: Applicative f0 => (a -> f0 b) -> (f :.: g) a -> f0 ((f :.: g) b) # sequenceA :: Applicative f0 => (f :.: g) (f0 a) -> f0 ((f :.: g) a) # mapM :: Monad m => (a -> m b) -> (f :.: g) a -> m ((f :.: g) b) # sequence :: Monad m => (f :.: g) (m a) -> m ((f :.: g) a) #
(Eq1 f, Eq1 g) => Eq1 (f :.: g)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftEq :: (a -> b -> Bool) -> (f :.: g) a -> (f :.: g) b -> Bool #
(Ord1 f, Ord1 g) => Ord1 (f :.: g)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftCompare :: (a -> b -> Ordering) -> (f :.: g) a -> (f :.: g) b -> Ordering #
(Read1 f, Read1 g) => Read1 (f :.: g)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftReadsPrec :: (Int -> ReadS a) -> ReadS [a] -> Int -> ReadS ((f :.: g) a) # liftReadList :: (Int -> ReadS a) -> ReadS [a] -> ReadS [(f :.: g) a] # liftReadPrec :: ReadPrec a -> ReadPrec [a] -> ReadPrec ((f :.: g) a) # liftReadListPrec :: ReadPrec a -> ReadPrec [a] -> ReadPrec [(f :.: g) a] #
(Show1 f, Show1 g) => Show1 (f :.: g)	Since: sop-core-0.2.4.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftShowsPrec :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> Int -> (f :.: g) a -> ShowS # liftShowList :: (Int -> a -> ShowS) -> ([a] -> ShowS) -> [(f :.: g) a] -> ShowS #
(NFData1 f, NFData1 g) => NFData1 (f :.: g)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods liftRnf :: (a -> ()) -> (f :.: g) a -> () #
Isomorphic (Ticked :.: LedgerState) Source #
Instance details Defined in Ouroboros.Consensus.HardFork.Combinator.Unary Methods project :: NoHardForks blk => (Ticked :.: LedgerState) (HardForkBlock '[blk]) -> (Ticked :.: LedgerState) blk Source # inject :: NoHardForks blk => (Ticked :.: LedgerState) blk -> (Ticked :.: LedgerState) (HardForkBlock '[blk]) Source #
(Eq1 f, Eq1 g, Eq a) => Eq ((f :.: g) a)
Instance details Defined in Data.SOP.BasicFunctors Methods (==) :: (f :.: g) a -> (f :.: g) a -> Bool # (/=) :: (f :.: g) a -> (f :.: g) a -> Bool #
(Ord1 f, Ord1 g, Ord a) => Ord ((f :.: g) a)
Instance details Defined in Data.SOP.BasicFunctors Methods compare :: (f :.: g) a -> (f :.: g) a -> Ordering # (<) :: (f :.: g) a -> (f :.: g) a -> Bool # (<=) :: (f :.: g) a -> (f :.: g) a -> Bool # (>) :: (f :.: g) a -> (f :.: g) a -> Bool # (>=) :: (f :.: g) a -> (f :.: g) a -> Bool # max :: (f :.: g) a -> (f :.: g) a -> (f :.: g) a # min :: (f :.: g) a -> (f :.: g) a -> (f :.: g) a #
(Read1 f, Read1 g, Read a) => Read ((f :.: g) a)
Instance details Defined in Data.SOP.BasicFunctors Methods readsPrec :: Int -> ReadS ((f :.: g) a) # readList :: ReadS [(f :.: g) a] # readPrec :: ReadPrec ((f :.: g) a) # readListPrec :: ReadPrec [(f :.: g) a] #
(Show1 f, Show1 g, Show a) => Show ((f :.: g) a)
Instance details Defined in Data.SOP.BasicFunctors Methods showsPrec :: Int -> (f :.: g) a -> ShowS # show :: (f :.: g) a -> String # showList :: [(f :.: g) a] -> ShowS #
Show (Ticked (f a)) => Show ((Ticked :.: f) a) Source #
Instance details Defined in Ouroboros.Consensus.Ticked Methods showsPrec :: Int -> (Ticked :.: f) a -> ShowS # show :: (Ticked :.: f) a -> String # showList :: [(Ticked :.: f) a] -> ShowS #
Generic ((f :.: g) p)
Instance details Defined in Data.SOP.BasicFunctors Associated Types type Rep ((f :.: g) p) :: Type -> Type # Methods from :: (f :.: g) p -> Rep ((f :.: g) p) x # to :: Rep ((f :.: g) p) x -> (f :.: g) p #
Semigroup (f (g x)) => Semigroup ((f :.: g) x)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.BasicFunctors Methods (<>) :: (f :.: g) x -> (f :.: g) x -> (f :.: g) x # sconcat :: NonEmpty ((f :.: g) x) -> (f :.: g) x # stimes :: Integral b => b -> (f :.: g) x -> (f :.: g) x #
Monoid (f (g x)) => Monoid ((f :.: g) x)	Since: sop-core-0.4.0.0
Instance details Defined in Data.SOP.BasicFunctors Methods mempty :: (f :.: g) x # mappend :: (f :.: g) x -> (f :.: g) x -> (f :.: g) x # mconcat :: [(f :.: g) x] -> (f :.: g) x #
NFData (f (g a)) => NFData ((f :.: g) a)	Since: sop-core-0.2.5.0
Instance details Defined in Data.SOP.BasicFunctors Methods rnf :: (f :.: g) a -> () #
NoThunks (Ticked (f a)) => NoThunks ((Ticked :.: f) a) Source #
Instance details Defined in Ouroboros.Consensus.Ticked Methods noThunks :: Context -> (Ticked :.: f) a -> IO (Maybe ThunkInfo) Source # wNoThunks :: Context -> (Ticked :.: f) a -> IO (Maybe ThunkInfo) Source # showTypeOf :: Proxy ((Ticked :.: f) a) -> String Source #
type Rep ((f :.: g) p)
Instance details Defined in Data.SOP.BasicFunctors type Rep ((f :.: g) p) = D1 ('MetaData ":.:" "Data.SOP.BasicFunctors" "sop-core-0.5.0.1-LSgc1wfRk3m3wHkiLjj5ug" 'True) (C1 ('MetaCons "Comp" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 (f (g p)))))

module Data.SOP.Constraint

NP

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NS

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Injections

Re-exports from sop-core

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Re-exports from `sop-core`