Safe Haskell	None
Language	Haskell98

Data.Row.Variants

Contents

Types and constraints
Construction
- Extension
- Modification
Destruction
- Types for destruction
Native Conversion
Row operations

Description

This module implements extensible variants using closed type families.

Synopsis

data Label (s :: Symbol) = Label
class KnownSymbol (n :: Symbol)
type family AllUniqueLabels (r :: Row k) :: Constraint where ...
type WellBehaved ρ = (Forall ρ Unconstrained1, AllUniqueLabels ρ)
data Var (r :: Row *)
data Row a
type Empty = R '[]
type (≈) a b = a ~ b
class (r .! l) ≈ a => HasType l a r
pattern IsJust :: forall l r. (AllUniqueLabels r, KnownSymbol l) => Label l -> (r .! l) -> Var r
singleton :: KnownSymbol l => Label l -> a -> Var (l .== a)
unSingleton :: forall l a. KnownSymbol l => Var (l .== a) -> (Label l, a)
fromLabels :: forall c ρ f. (Alternative f, Forall ρ c, AllUniqueLabels ρ) => (forall l a. (KnownSymbol l, c a) => Label l -> f a) -> f (Var ρ)
type family (r :: Row k) .\ (l :: Symbol) :: Constraint where ...
class Lacks (l :: Symbol) (r :: Row *)
type family (l :: Row k) .\/ (r :: Row k) where ...
diversify :: forall r' r. Var r -> Var (r .\/ r')
type family (l :: Row k) .+ (r :: Row k) :: Row k where ...
update :: (KnownSymbol l, (r .! l) ≈ a) => Label l -> a -> Var r -> Var r
focus :: forall l r r' a b p f. (AllUniqueLabels r, AllUniqueLabels r', KnownSymbol l, (r .! l) ≈ a, (r' .! l) ≈ b, r' ≈ ((r .- l) .\/ (l .== b)), Applicative f, Choice p) => Label l -> p a (f b) -> p (Var r) (f (Var r'))
type family Modify (l :: Symbol) (a :: k) (r :: Row k) :: Row k where ...
rename :: (KnownSymbol l, KnownSymbol l') => Label l -> Label l' -> Var r -> Var (Rename l l' r)
type family Rename (l :: Symbol) (l' :: Symbol) (r :: Row k) :: Row k where ...
impossible :: Var Empty -> a
trial :: KnownSymbol l => Var r -> Label l -> Either (r .! l) (Var (r .- l))
trial' :: KnownSymbol l => Var r -> Label l -> Maybe (r .! l)
multiTrial :: forall x y. (AllUniqueLabels x, Forall (y .\\ x) Unconstrained1) => Var y -> Either (Var x) (Var (y .\\ x))
view :: KnownSymbol l => Label l -> Var r -> Maybe (r .! l)
restrict :: forall r r'. (WellBehaved r, Subset r r') => Var r' -> Maybe (Var r)
split :: forall s r. (WellBehaved s, Subset s r) => Var r -> Either (Var s) (Var (r .\\ s))
type family (r :: Row k) .! (t :: Symbol) :: k where ...
type family (r :: Row k) .- (s :: Symbol) :: Row k where ...
type family (l :: Row k) .\\ (r :: Row k) :: Row k where ...
type (.==) (l :: Symbol) (a :: k) = Extend l a Empty
toNative :: forall t ρ. (Generic t, ToNative (Rep t) ρ) => Var ρ -> t
fromNative :: forall t ρ. (Generic t, FromNative (Rep t) ρ) => t -> Var ρ
fromNativeExact :: forall t ρ. (Generic t, FromNativeExact (Rep t) ρ) => t -> Var ρ
type family Map (f :: a -> b) (r :: Row a) :: Row b where ...
map :: forall c f r. Forall r c => (forall a. c a => a -> f a) -> Var r -> Var (Map f r)
map' :: forall f r. Forall r Unconstrained1 => (forall a. a -> f a) -> Var r -> Var (Map f r)
transform :: forall r c (f :: * -> *) (g :: * -> *). Forall r c => (forall a. c a => f a -> g a) -> Var (Map f r) -> Var (Map g r)
transform' :: forall r (f :: * -> *) (g :: * -> *). Forall r Unconstrained1 => (forall a. f a -> g a) -> Var (Map f r) -> Var (Map g r)
class Forall (r :: Row k) (c :: k -> Constraint)
erase :: forall c ρ b. Forall ρ c => (forall a. c a => a -> b) -> Var ρ -> b
eraseWithLabels :: forall c ρ s b. (Forall ρ c, IsString s) => (forall a. c a => a -> b) -> Var ρ -> (s, b)
eraseZip :: forall c ρ b. Forall ρ c => (forall a. c a => a -> a -> b) -> Var ρ -> Var ρ -> Maybe b
sequence :: forall f r. (Forall r Unconstrained1, Applicative f) => Var (Map f r) -> f (Var r)
compose :: forall (f :: * -> *) (g :: * -> *) r. Forall r Unconstrained1 => Var (Map f (Map g r)) -> Var (Map (Compose f g) r)
uncompose :: forall (f :: * -> *) (g :: * -> *) r. Forall r Unconstrained1 => Var (Map (Compose f g) r) -> Var (Map f (Map g r))
labels :: forall ρ c s. (IsString s, Forall ρ c) => [s]
unsafeMakeVar :: forall r l. KnownSymbol l => Label l -> (r .! l) -> Var r
unsafeInjectFront :: forall l a r. KnownSymbol l => Var (R r) -> Var (R ((l :-> a) ': r))

Types and constraints

data Label (s :: Symbol) Source #

A label

Constructors

Label

Instances

x ≈ y => IsLabel x (Label y) Source #
Instance details Defined in Data.Row.Internal Methods fromLabel :: Label y #
Eq (Label s) Source #
Instance details Defined in Data.Row.Internal Methods (==) :: Label s -> Label s -> Bool # (/=) :: Label s -> Label s -> Bool #
KnownSymbol s => Show (Label s) Source #
Instance details Defined in Data.Row.Internal Methods showsPrec :: Int -> Label s -> ShowS # show :: Label s -> String # showList :: [Label s] -> ShowS #

class KnownSymbol (n :: Symbol) #

This class gives the string associated with a type-level symbol. There are instances of the class for every concrete literal: "hello", etc.

Since: base-4.7.0.0

Minimal complete definition

symbolSing

type family AllUniqueLabels (r :: Row k) :: Constraint where ... Source #

Are all of the labels in this Row unique?

Equations

AllUniqueLabels (R r) = AllUniqueLabelsR r

type WellBehaved ρ = (Forall ρ Unconstrained1, AllUniqueLabels ρ) Source #

A convenient way to provide common, easy constraints

data Var (r :: Row *) Source #

The variant type.

Instances

(AllUniqueLabels r, KnownSymbol name, (r .! name) ≈ a, r ≈ ((r .- name) .\/ (name .== a))) => AsConstructor' name (Var r) a Source #
Instance details Defined in Data.Row.Variants Methods _Ctor' :: Prism (Var r) (Var r) a a #
(AllUniqueLabels r, AllUniqueLabels r', KnownSymbol name, (r .! name) ≈ a, (r' .! name) ≈ b, r' ≈ ((r .- name) .\/ (name .== b))) => AsConstructor name (Var r) (Var r') a b Source #	Every possibility of a row-types based variant has an `AsConstructor` instance.
Instance details Defined in Data.Row.Variants Methods _Ctor :: Prism (Var r) (Var r') a b #
Forall r Eq => Eq (Var r) Source #
Instance details Defined in Data.Row.Variants Methods (==) :: Var r -> Var r -> Bool # (/=) :: Var r -> Var r -> Bool #
(Forall r Eq, Forall r Ord) => Ord (Var r) Source #
Instance details Defined in Data.Row.Variants Methods compare :: Var r -> Var r -> Ordering # (<) :: Var r -> Var r -> Bool # (<=) :: Var r -> Var r -> Bool # (>) :: Var r -> Var r -> Bool # (>=) :: Var r -> Var r -> Bool # max :: Var r -> Var r -> Var r # min :: Var r -> Var r -> Var r #
Forall r Show => Show (Var r) Source #
Instance details Defined in Data.Row.Variants Methods showsPrec :: Int -> Var r -> ShowS # show :: Var r -> String # showList :: [Var r] -> ShowS #
GenericVar r => Generic (Var r) Source #
Instance details Defined in Data.Row.Variants Associated Types type Rep (Var r) :: Type -> Type # Methods from :: Var r -> Rep (Var r) x # to :: Rep (Var r) x -> Var r #
Forall r NFData => NFData (Var r) Source #
Instance details Defined in Data.Row.Variants Methods rnf :: Var r -> () #
type Rep (Var r) Source #
Instance details Defined in Data.Row.Variants type Rep (Var r)

data Row a Source #

The kind of rows. This type is only used as a datakind. A row is a typelevel entity telling us which symbols are associated with which types.

type Empty = R '[] Source #

Type level version of empty

type (≈) a b = a ~ b infix 4 Source #

A lower fixity operator for type equality

Construction

class (r .! l) ≈ a => HasType l a r Source #

Alias for (r .! l) ≈ a. It is a class rather than an alias, so that it can be partially applied.

Instances

(r .! l) ≈ a => HasType l (a :: k) (r :: Row k) Source #
Instance details Defined in Data.Row.Internal

pattern IsJust :: forall l r. (AllUniqueLabels r, KnownSymbol l) => Label l -> (r .! l) -> Var r Source #

A pattern for variants; can be used to both destruct a variant when in a pattern position or construct one in an expression position.

singleton :: KnownSymbol l => Label l -> a -> Var (l .== a) Source #

A quick constructor to create a singleton variant.

unSingleton :: forall l a. KnownSymbol l => Var (l .== a) -> (Label l, a) Source #

A quick destructor for singleton variants.

fromLabels :: forall c ρ f. (Alternative f, Forall ρ c, AllUniqueLabels ρ) => (forall l a. (KnownSymbol l, c a) => Label l -> f a) -> f (Var ρ) Source #

Initialize a variant from a producer function that accepts labels. If this function returns more than one possibility, then one is chosen arbitrarily to be the value in the variant.

Extension

type family (r :: Row k) .\ (l :: Symbol) :: Constraint where ... infixl 4 Source #

Does the row lack (i.e. it does not have) the specified label?

Equations

(R r) .\ l = LacksR l r r

class Lacks (l :: Symbol) (r :: Row *) Source #

Alias for .\. It is a class rather than an alias, so that it can be partially applied.

Instances

r .\ l => Lacks l r Source #
Instance details Defined in Data.Row.Internal

type family (l :: Row k) .\/ (r :: Row k) where ... infixl 6 Source #

The minimum join of the two rows.

Equations

(R l) .\/ (R r) = R (MinJoinR l r)

diversify :: forall r' r. Var r -> Var (r .\/ r') Source #

Make the variant arbitrarily more diverse.

type family (l :: Row k) .+ (r :: Row k) :: Row k where ... infixl 6 Source #

Type level Row append

Equations

(R l) .+ (R r) = R (Merge l r)

Modification

update :: (KnownSymbol l, (r .! l) ≈ a) => Label l -> a -> Var r -> Var r Source #

If the variant exists at the given label, update it to the given value. Otherwise, do nothing.

focus :: forall l r r' a b p f. (AllUniqueLabels r, AllUniqueLabels r', KnownSymbol l, (r .! l) ≈ a, (r' .! l) ≈ b, r' ≈ ((r .- l) .\/ (l .== b)), Applicative f, Choice p) => Label l -> p a (f b) -> p (Var r) (f (Var r')) Source #

If the variant exists at the given label, focus on the value associated with it. Otherwise, do nothing.

type family Modify (l :: Symbol) (a :: k) (r :: Row k) :: Row k where ... Source #

Type level Row modification

Equations

Modify l a (R ρ) = R (ModifyR l a ρ)

rename :: (KnownSymbol l, KnownSymbol l') => Label l -> Label l' -> Var r -> Var (Rename l l' r) Source #

Rename the given label.

type family Rename (l :: Symbol) (l' :: Symbol) (r :: Row k) :: Row k where ... Source #

Type level row renaming

Equations

Rename l l' r = Extend l' (r .! l) (r .- l)

Destruction

impossible :: Var Empty -> a Source #

A Variant with no options is uninhabited.

trial :: KnownSymbol l => Var r -> Label l -> Either (r .! l) (Var (r .- l)) Source #

Convert a variant into either the value at the given label or a variant without that label. This is the basic variant destructor.

trial' :: KnownSymbol l => Var r -> Label l -> Maybe (r .! l) Source #

A version of trial that ignores the leftover variant.

multiTrial :: forall x y. (AllUniqueLabels x, Forall (y .\\ x) Unconstrained1) => Var y -> Either (Var x) (Var (y .\\ x)) Source #

A trial over multiple types

view :: KnownSymbol l => Label l -> Var r -> Maybe (r .! l) Source #

A convenient function for using view patterns when dispatching variants. For example:

 myShow :: Var ("y" '::= String :| "x" '::= Int :| Empty) -> String
 myShow (view x -> Just n) = "Int of "++show n
 myShow (view y -> Just s) = "String of "++s

restrict :: forall r r'. (WellBehaved r, Subset r r') => Var r' -> Maybe (Var r) Source #

Arbitrary variant restriction. Turn a variant into a subset of itself.

split :: forall s r. (WellBehaved s, Subset s r) => Var r -> Either (Var s) (Var (r .\\ s)) Source #

Split a variant into two sub-variants.

Types for destruction

type family (r :: Row k) .! (t :: Symbol) :: k where ... infixl 5 Source #

Type level label fetching

Equations

(R r) .! l = Get l r

type family (r :: Row k) .- (s :: Symbol) :: Row k where ... infixl 6 Source #

Type level Row element removal

Equations

(R r) .- l = R (Remove l r)

type family (l :: Row k) .\\ (r :: Row k) :: Row k where ... infixl 6 Source #

Type level Row difference. That is, l .\\ r is the row remaining after removing any matching elements of r from l.

Equations

(R l) .\\ (R r) = R (Diff l r)

type (.==) (l :: Symbol) (a :: k) = Extend l a Empty infix 7 Source #

A type level way to create a singleton Row.

Native Conversion

The toNative and fromNative functions allow one to convert between Vars and regular Haskell data types ("native" types) that have the same number of constructors such that each constructor has one field and the same name as one of the options of the Var, which has the same type as that field. That said, they do not compose to form the identity because fromNative allows constructors to be added: a variant with excess options can still be transformed to a native type, but when the native type is converted to a variant, the options are exactly transformed. The only requirement is that the native Haskell data type be an instance of Generic.

For example, consider the following simple data type:

>>> data Pet = Dog {age :: Int} | Cat {age :: Int} deriving (Generic, Show)

Then, we have the following:

>>> toNative $ IsJust (Label @"Dog") 3 :: Pet
Dog {age = 3}
>>> V.fromNative $ Dog 3 :: Var ("Dog" .== Int .+ "Cat" .== Int)
{Dog=3}

The fromNativeExact function is a more restricted version of fromNative that does not allow options to be added; in other words, the options in the variant must exactly match the constructors in the data type. Because of this, fromNativeExact and toNative compose to form the identity function.

toNative :: forall t ρ. (Generic t, ToNative (Rep t) ρ) => Var ρ -> t Source #

Convert a variant to a native Haskell type.

fromNative :: forall t ρ. (Generic t, FromNative (Rep t) ρ) => t -> Var ρ Source #

Convert a Haskell record to a row-types Var.

fromNativeExact :: forall t ρ. (Generic t, FromNativeExact (Rep t) ρ) => t -> Var ρ Source #

Convert a Haskell record to a row-types Var.

Row operations

Map

type family Map (f :: a -> b) (r :: Row a) :: Row b where ... Source #

Map a type level function over a Row.

Equations

Map f (R r) = R (MapR f r)

map :: forall c f r. Forall r c => (forall a. c a => a -> f a) -> Var r -> Var (Map f r) Source #

A function to map over a variant given a constraint.

map' :: forall f r. Forall r Unconstrained1 => (forall a. a -> f a) -> Var r -> Var (Map f r) Source #

A function to map over a variant given no constraint.

transform :: forall r c (f :: * -> *) (g :: * -> *). Forall r c => (forall a. c a => f a -> g a) -> Var (Map f r) -> Var (Map g r) Source #

Lifts a natrual transformation over a variant. In other words, it acts as a variant transformer to convert a variant of f a values to a variant of g a values. If no constraint is needed, instantiate the first type argument with Unconstrained1.

transform' :: forall r (f :: * -> *) (g :: * -> *). Forall r Unconstrained1 => (forall a. f a -> g a) -> Var (Map f r) -> Var (Map g r) Source #

A form of transformC that doesn't have a constraint on a

Fold

class Forall (r :: Row k) (c :: k -> Constraint) Source #

Any structure over a row in which every element is similarly constrained can be metamorphized into another structure over the same row.

Minimal complete definition

metamorph, metamorph'

Instances

(KnownSymbol ℓ, c τ, Forall (R ρ) c) => Forall (R ((ℓ :-> τ) ': ρ) :: Row k) (c :: k -> Constraint) Source #
Instance details Defined in Data.Row.Internal Methods metamorph :: Proxy h -> (f Empty -> g Empty) -> (forall (ℓ0 :: Symbol) (τ0 :: k0) (ρ0 :: [LT k0]). (KnownSymbol ℓ0, c τ0) => Label ℓ0 -> f (R ((ℓ0 :-> τ0) ': ρ0)) -> (h τ0, f (R ρ0))) -> (forall (ℓ1 :: Symbol) (τ1 :: k0) (ρ1 :: [LT k0]). (KnownSymbol ℓ1, c τ1) => Label ℓ1 -> h τ1 -> g (R ρ1) -> g (R ((ℓ1 :-> τ1) ': ρ1))) -> f (R ((ℓ :-> τ) ': ρ)) -> g (R ((ℓ :-> τ) ': ρ)) Source # metamorph' :: Proxy h -> (f Empty -> g Empty) -> (forall (ℓ0 :: Symbol) (τ0 :: k0) (ρ0 :: [LT k0]). (KnownSymbol ℓ0, c τ0) => Label ℓ0 -> f (R ((ℓ0 :-> τ0) ': ρ0)) -> Either (h τ0) (f (R ρ0))) -> (forall (ℓ1 :: Symbol) (τ1 :: k0) (ρ1 :: [LT k0]). (KnownSymbol ℓ1, c τ1) => Label ℓ1 -> Either (h τ1) (g (R ρ1)) -> g (R ((ℓ1 :-> τ1) ': ρ1))) -> f (R ((ℓ :-> τ) ': ρ)) -> g (R ((ℓ :-> τ) ': ρ)) Source #
Forall (R ([] :: [LT k]) :: Row k) (c :: k -> Constraint) Source #
Instance details Defined in Data.Row.Internal Methods metamorph :: Proxy h -> (f Empty -> g Empty) -> (forall (ℓ :: Symbol) (τ :: k0) (ρ :: [LT k0]). (KnownSymbol ℓ, c τ) => Label ℓ -> f (R ((ℓ :-> τ) ': ρ)) -> (h τ, f (R ρ))) -> (forall (ℓ :: Symbol) (τ :: k0) (ρ :: [LT k0]). (KnownSymbol ℓ, c τ) => Label ℓ -> h τ -> g (R ρ) -> g (R ((ℓ :-> τ) ': ρ))) -> f (R []) -> g (R []) Source # metamorph' :: Proxy h -> (f Empty -> g Empty) -> (forall (ℓ :: Symbol) (τ :: k0) (ρ :: [LT k0]). (KnownSymbol ℓ, c τ) => Label ℓ -> f (R ((ℓ :-> τ) ': ρ)) -> Either (h τ) (f (R ρ))) -> (forall (ℓ :: Symbol) (τ :: k0) (ρ :: [LT k0]). (KnownSymbol ℓ, c τ) => Label ℓ -> Either (h τ) (g (R ρ)) -> g (R ((ℓ :-> τ) ': ρ))) -> f (R []) -> g (R []) Source #

erase :: forall c ρ b. Forall ρ c => (forall a. c a => a -> b) -> Var ρ -> b Source #

A standard fold

eraseWithLabels :: forall c ρ s b. (Forall ρ c, IsString s) => (forall a. c a => a -> b) -> Var ρ -> (s, b) Source #

A fold with labels

eraseZip :: forall c ρ b. Forall ρ c => (forall a. c a => a -> a -> b) -> Var ρ -> Var ρ -> Maybe b Source #

A fold over two row type structures at once

Sequence

sequence :: forall f r. (Forall r Unconstrained1, Applicative f) => Var (Map f r) -> f (Var r) Source #

Applicative sequencing over a variant

Compose

We can easily convert between mapping two functors over the types of a row and mapping the composition of the two functors. The following two functions perform this composition with the gaurantee that:

>>> compose . uncompose = id

>>> uncompose . compose = id

compose :: forall (f :: * -> *) (g :: * -> *) r. Forall r Unconstrained1 => Var (Map f (Map g r)) -> Var (Map (Compose f g) r) Source #

Convert from a variant where two functors have been mapped over the types to one where the composition of the two functors is mapped over the types.

uncompose :: forall (f :: * -> *) (g :: * -> *) r. Forall r Unconstrained1 => Var (Map (Compose f g) r) -> Var (Map f (Map g r)) Source #

Convert from a variant where the composition of two functors have been mapped over the types to one where the two functors are mapped individually one at a time over the types.

labels

labels :: forall ρ c s. (IsString s, Forall ρ c) => [s] Source #

Return a list of the labels in a row type.

UNSAFE operations

unsafeMakeVar :: forall r l. KnownSymbol l => Label l -> (r .! l) -> Var r Source #

An unsafe way to make a Variant. This function does not guarantee that the labels are all unique.

unsafeInjectFront :: forall l a r. KnownSymbol l => Var (R r) -> Var (R ((l :-> a) ': r)) Source #

A helper function for unsafely adding an element to the front of a variant. This can cause the type of the resulting variant to be malformed, for instance, if the variant already contains labels that are lexicographically before the given label. Realistically, this function should only be used when writing calls to metamorph.