{-# LANGUAGE CPP #-} {-# LANGUAGE DataKinds #-} {-# LANGUAGE DeriveFunctor #-} {-# LANGUAGE DeriveGeneric #-} {-# LANGUAGE EmptyDataDeriving #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE KindSignatures #-} {-# LANGUAGE MagicHash #-} {-# LANGUAGE NoImplicitPrelude #-} {-# LANGUAGE PolyKinds #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE StandaloneDeriving #-} {-# LANGUAGE Trustworthy #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE TypeOperators #-} {-# LANGUAGE TypeSynonymInstances #-} {-# LANGUAGE UndecidableInstances #-} ----------------------------------------------------------------------------- -- | -- Module : GHC.Generics -- Copyright : (c) Universiteit Utrecht 2010-2011, University of Oxford 2012-2014 -- License : see libraries/base/LICENSE -- -- Maintainer : libraries@haskell.org -- Stability : internal -- Portability : non-portable -- -- @since 4.6.0.0 -- -- If you're using @GHC.Generics@, you should consider using the -- <http://hackage.haskell.org/package/generic-deriving> package, which -- contains many useful generic functions. module GHC.Generics ( -- * Introduction -- -- | -- -- Datatype-generic functions are based on the idea of converting values of -- a datatype @T@ into corresponding values of a (nearly) isomorphic type @'Rep' T@. -- The type @'Rep' T@ is -- built from a limited set of type constructors, all provided by this module. A -- datatype-generic function is then an overloaded function with instances -- for most of these type constructors, together with a wrapper that performs -- the mapping between @T@ and @'Rep' T@. By using this technique, we merely need -- a few generic instances in order to implement functionality that works for any -- representable type. -- -- Representable types are collected in the 'Generic' class, which defines the -- associated type 'Rep' as well as conversion functions 'from' and 'to'. -- Typically, you will not define 'Generic' instances by hand, but have the compiler -- derive them for you. -- ** Representing datatypes -- -- | -- -- The key to defining your own datatype-generic functions is to understand how to -- represent datatypes using the given set of type constructors. -- -- Let us look at an example first: -- -- @ -- data Tree a = Leaf a | Node (Tree a) (Tree a) -- deriving 'Generic' -- @ -- -- The above declaration (which requires the language pragma @DeriveGeneric@) -- causes the following representation to be generated: -- -- @ -- instance 'Generic' (Tree a) where -- type 'Rep' (Tree a) = -- 'D1' ('MetaData \"Tree\" \"Main\" \"package-name\" 'False) -- ('C1' ('MetaCons \"Leaf\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ('Rec0' a)) -- ':+:' -- 'C1' ('MetaCons \"Node\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ('Rec0' (Tree a)) -- ':*:' -- 'S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ('Rec0' (Tree a)))) -- ... -- @ -- -- /Hint:/ You can obtain information about the code being generated from GHC by passing -- the @-ddump-deriv@ flag. In GHCi, you can expand a type family such as 'Rep' using -- the @:kind!@ command. -- -- This is a lot of information! However, most of it is actually merely meta-information -- that makes names of datatypes and constructors and more available on the type level. -- -- Here is a reduced representation for @Tree@ with nearly all meta-information removed, -- for now keeping only the most essential aspects: -- -- @ -- instance 'Generic' (Tree a) where -- type 'Rep' (Tree a) = -- 'Rec0' a -- ':+:' -- ('Rec0' (Tree a) ':*:' 'Rec0' (Tree a)) -- @ -- -- The @Tree@ datatype has two constructors. The representation of individual constructors -- is combined using the binary type constructor ':+:'. -- -- The first constructor consists of a single field, which is the parameter @a@. This is -- represented as @'Rec0' a@. -- -- The second constructor consists of two fields. Each is a recursive field of type @Tree a@, -- represented as @'Rec0' (Tree a)@. Representations of individual fields are combined using -- the binary type constructor ':*:'. -- -- Now let us explain the additional tags being used in the complete representation: -- -- * The @'S1' ('MetaSel 'Nothing 'NoSourceUnpackedness 'NoSourceStrictness -- 'DecidedLazy)@ tag indicates several things. The @'Nothing@ indicates -- that there is no record field selector associated with this field of -- the constructor (if there were, it would have been marked @'Just -- \"recordName\"@ instead). The other types contain meta-information on -- the field's strictness: -- -- * There is no @{\-\# UNPACK \#-\}@ or @{\-\# NOUNPACK \#-\}@ annotation -- in the source, so it is tagged with @'NoSourceUnpackedness@. -- -- * There is no strictness (@!@) or laziness (@~@) annotation in the -- source, so it is tagged with @'NoSourceStrictness@. -- -- * The compiler infers that the field is lazy, so it is tagged with -- @'DecidedLazy@. Bear in mind that what the compiler decides may be -- quite different from what is written in the source. See -- 'DecidedStrictness' for a more detailed explanation. -- -- The @'MetaSel@ type is also an instance of the type class 'Selector', -- which can be used to obtain information about the field at the value -- level. -- -- * The @'C1' ('MetaCons \"Leaf\" 'PrefixI 'False)@ and -- @'C1' ('MetaCons \"Node\" 'PrefixI 'False)@ invocations indicate that the enclosed part is -- the representation of the first and second constructor of datatype @Tree@, respectively. -- Here, the meta-information regarding constructor names, fixity and whether -- it has named fields or not is encoded at the type level. The @'MetaCons@ -- type is also an instance of the type class 'Constructor'. This type class can be used -- to obtain information about the constructor at the value level. -- -- * The @'D1' ('MetaData \"Tree\" \"Main\" \"package-name\" 'False)@ tag -- indicates that the enclosed part is the representation of the -- datatype @Tree@. Again, the meta-information is encoded at the type level. -- The @'MetaData@ type is an instance of class 'Datatype', which -- can be used to obtain the name of a datatype, the module it has been -- defined in, the package it is located under, and whether it has been -- defined using @data@ or @newtype@ at the value level. -- ** Derived and fundamental representation types -- -- | -- -- There are many datatype-generic functions that do not distinguish between positions that -- are parameters or positions that are recursive calls. There are also many datatype-generic -- functions that do not care about the names of datatypes and constructors at all. To keep -- the number of cases to consider in generic functions in such a situation to a minimum, -- it turns out that many of the type constructors introduced above are actually synonyms, -- defining them to be variants of a smaller set of constructors. -- *** Individual fields of constructors: 'K1' -- -- | -- -- The type constructor 'Rec0' is a variant of 'K1': -- -- @ -- type 'Rec0' = 'K1' 'R' -- @ -- -- Here, 'R' is a type-level proxy that does not have any associated values. -- -- There used to be another variant of 'K1' (namely @Par0@), but it has since -- been deprecated. -- *** Meta information: 'M1' -- -- | -- -- The type constructors 'S1', 'C1' and 'D1' are all variants of 'M1': -- -- @ -- type 'S1' = 'M1' 'S' -- type 'C1' = 'M1' 'C' -- type 'D1' = 'M1' 'D' -- @ -- -- The types 'S', 'C' and 'D' are once again type-level proxies, just used to create -- several variants of 'M1'. -- *** Additional generic representation type constructors -- -- | -- -- Next to 'K1', 'M1', ':+:' and ':*:' there are a few more type constructors that occur -- in the representations of other datatypes. -- **** Empty datatypes: 'V1' -- -- | -- -- For empty datatypes, 'V1' is used as a representation. For example, -- -- @ -- data Empty deriving 'Generic' -- @ -- -- yields -- -- @ -- instance 'Generic' Empty where -- type 'Rep' Empty = -- 'D1' ('MetaData \"Empty\" \"Main\" \"package-name\" 'False) 'V1' -- @ -- **** Constructors without fields: 'U1' -- -- | -- -- If a constructor has no arguments, then 'U1' is used as its representation. For example -- the representation of 'Bool' is -- -- @ -- instance 'Generic' Bool where -- type 'Rep' Bool = -- 'D1' ('MetaData \"Bool\" \"Data.Bool\" \"package-name\" 'False) -- ('C1' ('MetaCons \"False\" 'PrefixI 'False) 'U1' ':+:' 'C1' ('MetaCons \"True\" 'PrefixI 'False) 'U1') -- @ -- *** Representation of types with many constructors or many fields -- -- | -- -- As ':+:' and ':*:' are just binary operators, one might ask what happens if the -- datatype has more than two constructors, or a constructor with more than two -- fields. The answer is simple: the operators are used several times, to combine -- all the constructors and fields as needed. However, users /should not rely on -- a specific nesting strategy/ for ':+:' and ':*:' being used. The compiler is -- free to choose any nesting it prefers. (In practice, the current implementation -- tries to produce a more-or-less balanced nesting, so that the traversal of -- the structure of the datatype from the root to a particular component can be -- performed in logarithmic rather than linear time.) -- ** Defining datatype-generic functions -- -- | -- -- A datatype-generic function comprises two parts: -- -- 1. /Generic instances/ for the function, implementing it for most of the representation -- type constructors introduced above. -- -- 2. A /wrapper/ that for any datatype that is in `Generic`, performs the conversion -- between the original value and its `Rep`-based representation and then invokes the -- generic instances. -- -- As an example, let us look at a function @encode@ that produces a naive, but lossless -- bit encoding of values of various datatypes. So we are aiming to define a function -- -- @ -- encode :: 'Generic' a => a -> [Bool] -- @ -- -- where we use 'Bool' as our datatype for bits. -- -- For part 1, we define a class @Encode'@. Perhaps surprisingly, this class is parameterized -- over a type constructor @f@ of kind @* -> *@. This is a technicality: all the representation -- type constructors operate with kind @* -> *@ as base kind. But the type argument is never -- being used. This may be changed at some point in the future. The class has a single method, -- and we use the type we want our final function to have, but we replace the occurrences of -- the generic type argument @a@ with @f p@ (where the @p@ is any argument; it will not be used). -- -- > class Encode' f where -- > encode' :: f p -> [Bool] -- -- With the goal in mind to make @encode@ work on @Tree@ and other datatypes, we now define -- instances for the representation type constructors 'V1', 'U1', ':+:', ':*:', 'K1', and 'M1'. -- *** Definition of the generic representation types -- -- | -- -- In order to be able to do this, we need to know the actual definitions of these types: -- -- @ -- data 'V1' p -- lifted version of Empty -- data 'U1' p = 'U1' -- lifted version of () -- data (':+:') f g p = 'L1' (f p) | 'R1' (g p) -- lifted version of 'Either' -- data (':*:') f g p = (f p) ':*:' (g p) -- lifted version of (,) -- newtype 'K1' i c p = 'K1' { 'unK1' :: c } -- a container for a c -- newtype 'M1' i t f p = 'M1' { 'unM1' :: f p } -- a wrapper -- @ -- -- So, 'U1' is just the unit type, ':+:' is just a binary choice like 'Either', -- ':*:' is a binary pair like the pair constructor @(,)@, and 'K1' is a value -- of a specific type @c@, and 'M1' wraps a value of the generic type argument, -- which in the lifted world is an @f p@ (where we do not care about @p@). -- *** Generic instances -- -- | -- -- The instance for 'V1' is slightly awkward (but also rarely used): -- -- @ -- instance Encode' 'V1' where -- encode' x = undefined -- @ -- -- There are no values of type @V1 p@ to pass (except undefined), so this is -- actually impossible. One can ask why it is useful to define an instance for -- 'V1' at all in this case? Well, an empty type can be used as an argument to -- a non-empty type, and you might still want to encode the resulting type. -- As a somewhat contrived example, consider @[Empty]@, which is not an empty -- type, but contains just the empty list. The 'V1' instance ensures that we -- can call the generic function on such types. -- -- There is exactly one value of type 'U1', so encoding it requires no -- knowledge, and we can use zero bits: -- -- @ -- instance Encode' 'U1' where -- encode' 'U1' = [] -- @ -- -- In the case for ':+:', we produce 'False' or 'True' depending on whether -- the constructor of the value provided is located on the left or on the right: -- -- @ -- instance (Encode' f, Encode' g) => Encode' (f ':+:' g) where -- encode' ('L1' x) = False : encode' x -- encode' ('R1' x) = True : encode' x -- @ -- -- (Note that this encoding strategy may not be reliable across different -- versions of GHC. Recall that the compiler is free to choose any nesting -- of ':+:' it chooses, so if GHC chooses @(a ':+:' b) ':+:' c@, then the -- encoding for @a@ would be @[False, False]@, @b@ would be @[False, True]@, -- and @c@ would be @[True]@. However, if GHC chooses @a ':+:' (b ':+:' c)@, -- then the encoding for @a@ would be @[False]@, @b@ would be @[True, False]@, -- and @c@ would be @[True, True]@.) -- -- In the case for ':*:', we append the encodings of the two subcomponents: -- -- @ -- instance (Encode' f, Encode' g) => Encode' (f ':*:' g) where -- encode' (x ':*:' y) = encode' x ++ encode' y -- @ -- -- The case for 'K1' is rather interesting. Here, we call the final function -- @encode@ that we yet have to define, recursively. We will use another type -- class @Encode@ for that function: -- -- @ -- instance (Encode c) => Encode' ('K1' i c) where -- encode' ('K1' x) = encode x -- @ -- -- Note how we can define a uniform instance for 'M1', because we completely -- disregard all meta-information: -- -- @ -- instance (Encode' f) => Encode' ('M1' i t f) where -- encode' ('M1' x) = encode' x -- @ -- -- Unlike in 'K1', the instance for 'M1' refers to @encode'@, not @encode@. -- *** The wrapper and generic default -- -- | -- -- We now define class @Encode@ for the actual @encode@ function: -- -- @ -- class Encode a where -- encode :: a -> [Bool] -- default encode :: (Generic a, Encode' (Rep a)) => a -> [Bool] -- encode x = encode' ('from' x) -- @ -- -- The incoming @x@ is converted using 'from', then we dispatch to the -- generic instances using @encode'@. We use this as a default definition -- for @encode@. We need the @default encode@ signature because ordinary -- Haskell default methods must not introduce additional class constraints, -- but our generic default does. -- -- Defining a particular instance is now as simple as saying -- -- @ -- instance (Encode a) => Encode (Tree a) -- @ -- #if 0 -- /TODO:/ Add usage example? -- #endif -- The generic default is being used. In the future, it will hopefully be -- possible to use @deriving Encode@ as well, but GHC does not yet support -- that syntax for this situation. -- -- Having @Encode@ as a class has the advantage that we can define -- non-generic special cases, which is particularly useful for abstract -- datatypes that have no structural representation. For example, given -- a suitable integer encoding function @encodeInt@, we can define -- -- @ -- instance Encode Int where -- encode = encodeInt -- @ -- *** Omitting generic instances -- -- | -- -- It is not always required to provide instances for all the generic -- representation types, but omitting instances restricts the set of -- datatypes the functions will work for: -- -- * If no ':+:' instance is given, the function may still work for -- empty datatypes or datatypes that have a single constructor, -- but will fail on datatypes with more than one constructor. -- -- * If no ':*:' instance is given, the function may still work for -- datatypes where each constructor has just zero or one field, -- in particular for enumeration types. -- -- * If no 'K1' instance is given, the function may still work for -- enumeration types, where no constructor has any fields. -- -- * If no 'V1' instance is given, the function may still work for -- any datatype that is not empty. -- -- * If no 'U1' instance is given, the function may still work for -- any datatype where each constructor has at least one field. -- -- An 'M1' instance is always required (but it can just ignore the -- meta-information, as is the case for @encode@ above). #if 0 -- *** Using meta-information -- -- | -- -- TODO #endif -- ** Generic constructor classes -- -- | -- -- Datatype-generic functions as defined above work for a large class -- of datatypes, including parameterized datatypes. (We have used @Tree@ -- as our example above, which is of kind @* -> *@.) However, the -- 'Generic' class ranges over types of kind @*@, and therefore, the -- resulting generic functions (such as @encode@) must be parameterized -- by a generic type argument of kind @*@. -- -- What if we want to define generic classes that range over type -- constructors (such as 'Data.Functor.Functor', -- 'Data.Traversable.Traversable', or 'Data.Foldable.Foldable')? -- *** The 'Generic1' class -- -- | -- -- Like 'Generic', there is a class 'Generic1' that defines a -- representation 'Rep1' and conversion functions 'from1' and 'to1', -- only that 'Generic1' ranges over types of kind @* -> *@. (More generally, -- it can range over types of kind @k -> *@, for any kind @k@, if the -- @PolyKinds@ extension is enabled. More on this later.) -- The 'Generic1' class is also derivable. -- -- The representation 'Rep1' is ever so slightly different from 'Rep'. -- Let us look at @Tree@ as an example again: -- -- @ -- data Tree a = Leaf a | Node (Tree a) (Tree a) -- deriving 'Generic1' -- @ -- -- The above declaration causes the following representation to be generated: -- -- @ -- instance 'Generic1' Tree where -- type 'Rep1' Tree = -- 'D1' ('MetaData \"Tree\" \"Main\" \"package-name\" 'False) -- ('C1' ('MetaCons \"Leaf\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- 'Par1') -- ':+:' -- 'C1' ('MetaCons \"Node\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ('Rec1' Tree) -- ':*:' -- 'S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ('Rec1' Tree))) -- ... -- @ -- -- The representation reuses 'D1', 'C1', 'S1' (and thereby 'M1') as well -- as ':+:' and ':*:' from 'Rep'. (This reusability is the reason that we -- carry around the dummy type argument for kind-@*@-types, but there are -- already enough different names involved without duplicating each of -- these.) -- -- What's different is that we now use 'Par1' to refer to the parameter -- (and that parameter, which used to be @a@), is not mentioned explicitly -- by name anywhere; and we use 'Rec1' to refer to a recursive use of @Tree a@. -- *** Representation of @* -> *@ types -- -- | -- -- Unlike 'Rec0', the 'Par1' and 'Rec1' type constructors do not -- map to 'K1'. They are defined directly, as follows: -- -- @ -- newtype 'Par1' p = 'Par1' { 'unPar1' :: p } -- gives access to parameter p -- newtype 'Rec1' f p = 'Rec1' { 'unRec1' :: f p } -- a wrapper -- @ -- -- In 'Par1', the parameter @p@ is used for the first time, whereas 'Rec1' simply -- wraps an application of @f@ to @p@. -- -- Note that 'K1' (in the guise of 'Rec0') can still occur in a 'Rep1' representation, -- namely when the datatype has a field that does not mention the parameter. -- -- The declaration -- -- @ -- data WithInt a = WithInt Int a -- deriving 'Generic1' -- @ -- -- yields -- -- @ -- instance 'Generic1' WithInt where -- type 'Rep1' WithInt = -- 'D1' ('MetaData \"WithInt\" \"Main\" \"package-name\" 'False) -- ('C1' ('MetaCons \"WithInt\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ('Rec0' Int) -- ':*:' -- 'S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- 'Par1')) -- @ -- -- If the parameter @a@ appears underneath a composition of other type constructors, -- then the representation involves composition, too: -- -- @ -- data Rose a = Fork a [Rose a] -- @ -- -- yields -- -- @ -- instance 'Generic1' Rose where -- type 'Rep1' Rose = -- 'D1' ('MetaData \"Rose\" \"Main\" \"package-name\" 'False) -- ('C1' ('MetaCons \"Fork\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- 'Par1' -- ':*:' -- 'S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- ([] ':.:' 'Rec1' Rose))) -- @ -- -- where -- -- @ -- newtype (':.:') f g p = 'Comp1' { 'unComp1' :: f (g p) } -- @ -- *** Representation of @k -> *@ types -- -- | -- -- The 'Generic1' class can be generalized to range over types of kind -- @k -> *@, for any kind @k@. To do so, derive a 'Generic1' instance with the -- @PolyKinds@ extension enabled. For example, the declaration -- -- @ -- data Proxy (a :: k) = Proxy deriving 'Generic1' -- @ -- -- yields a slightly different instance depending on whether @PolyKinds@ is -- enabled. If compiled without @PolyKinds@, then @'Rep1' Proxy :: * -> *@, but -- if compiled with @PolyKinds@, then @'Rep1' Proxy :: k -> *@. -- *** Representation of unlifted types -- -- | -- -- If one were to attempt to derive a Generic instance for a datatype with an -- unlifted argument (for example, 'Int#'), one might expect the occurrence of -- the 'Int#' argument to be marked with @'Rec0' 'Int#'@. This won't work, -- though, since 'Int#' is of an unlifted kind, and 'Rec0' expects a type of -- kind @*@. -- -- One solution would be to represent an occurrence of 'Int#' with 'Rec0 Int' -- instead. With this approach, however, the programmer has no way of knowing -- whether the 'Int' is actually an 'Int#' in disguise. -- -- Instead of reusing 'Rec0', a separate data family 'URec' is used to mark -- occurrences of common unlifted types: -- -- @ -- data family URec a p -- -- data instance 'URec' ('Ptr' ()) p = 'UAddr' { 'uAddr#' :: 'Addr#' } -- data instance 'URec' 'Char' p = 'UChar' { 'uChar#' :: 'Char#' } -- data instance 'URec' 'Double' p = 'UDouble' { 'uDouble#' :: 'Double#' } -- data instance 'URec' 'Int' p = 'UFloat' { 'uFloat#' :: 'Float#' } -- data instance 'URec' 'Float' p = 'UInt' { 'uInt#' :: 'Int#' } -- data instance 'URec' 'Word' p = 'UWord' { 'uWord#' :: 'Word#' } -- @ -- -- Several type synonyms are provided for convenience: -- -- @ -- type 'UAddr' = 'URec' ('Ptr' ()) -- type 'UChar' = 'URec' 'Char' -- type 'UDouble' = 'URec' 'Double' -- type 'UFloat' = 'URec' 'Float' -- type 'UInt' = 'URec' 'Int' -- type 'UWord' = 'URec' 'Word' -- @ -- -- The declaration -- -- @ -- data IntHash = IntHash Int# -- deriving 'Generic' -- @ -- -- yields -- -- @ -- instance 'Generic' IntHash where -- type 'Rep' IntHash = -- 'D1' ('MetaData \"IntHash\" \"Main\" \"package-name\" 'False) -- ('C1' ('MetaCons \"IntHash\" 'PrefixI 'False) -- ('S1' ('MetaSel 'Nothing -- 'NoSourceUnpackedness -- 'NoSourceStrictness -- 'DecidedLazy) -- 'UInt')) -- @ -- -- Currently, only the six unlifted types listed above are generated, but this -- may be extended to encompass more unlifted types in the future. #if 0 -- *** Limitations -- -- | -- -- /TODO/ -- -- /TODO:/ Also clear up confusion about 'Rec0' and 'Rec1' not really indicating recursion. -- #endif ----------------------------------------------------------------------------- -- * Generic representation types V1, U1(..), Par1(..), Rec1(..), K1(..), M1(..) , (:+:)(..), (:*:)(..), (:.:)(..) -- ** Unboxed representation types , URec(..) , type UAddr, type UChar, type UDouble , type UFloat, type UInt, type UWord -- ** Synonyms for convenience , Rec0, R , D1, C1, S1, D, C, S -- * Meta-information , Datatype(..), Constructor(..), Selector(..) , Fixity(..), FixityI(..), Associativity(..), prec , SourceUnpackedness(..), SourceStrictness(..), DecidedStrictness(..) , Meta(..) -- * Generic type classes , Generic(..), Generic1(..) ) where -- We use some base types import Data.Either ( Either (..) ) import Data.Maybe ( Maybe(..), fromMaybe ) import Data.Ord ( Down(..) ) import GHC.Integer ( Integer, integerToInt ) import GHC.Prim ( Addr#, Char#, Double#, Float#, Int#, Word# ) import GHC.Ptr ( Ptr ) import GHC.Types -- Needed for instances import GHC.Ix ( Ix ) import GHC.Base ( Alternative(..), Applicative(..), Functor(..) , Monad(..), MonadPlus(..), NonEmpty(..), String, coerce , Semigroup(..), Monoid(..) ) import GHC.Classes ( Eq(..), Ord(..) ) import GHC.Enum ( Bounded, Enum ) import GHC.Read ( Read(..) ) import GHC.Show ( Show(..), showString ) -- Needed for metadata import Data.Proxy ( Proxy(..) ) import GHC.TypeLits ( KnownSymbol, KnownNat, symbolVal, natVal ) -------------------------------------------------------------------------------- -- Representation types -------------------------------------------------------------------------------- -- | Void: used for datatypes without constructors data V1 (p :: k) deriving ( Eq -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Read -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.12.0.0 instance Semigroup (V1 p) where V1 p v <> :: V1 p -> V1 p -> V1 p <> V1 p _ = V1 p v -- | Unit: used for constructors without arguments data U1 (p :: k) = U1 deriving ( Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.9.0.0 instance Eq (U1 p) where U1 p _ == :: U1 p -> U1 p -> Bool == U1 p _ = Bool True -- | @since 4.7.0.0 instance Ord (U1 p) where compare :: U1 p -> U1 p -> Ordering compare U1 p _ U1 p _ = Ordering EQ -- | @since 4.9.0.0 deriving instance Read (U1 p) -- | @since 4.9.0.0 instance Show (U1 p) where showsPrec :: Int -> U1 p -> ShowS showsPrec Int _ U1 p _ = String -> ShowS showString String "U1" -- | @since 4.9.0.0 instance Functor U1 where fmap :: (a -> b) -> U1 a -> U1 b fmap a -> b _ U1 a _ = U1 b forall k (p :: k). U1 p U1 -- | @since 4.9.0.0 instance Applicative U1 where pure :: a -> U1 a pure a _ = U1 a forall k (p :: k). U1 p U1 U1 (a -> b) _ <*> :: U1 (a -> b) -> U1 a -> U1 b <*> U1 a _ = U1 b forall k (p :: k). U1 p U1 liftA2 :: (a -> b -> c) -> U1 a -> U1 b -> U1 c liftA2 a -> b -> c _ U1 a _ U1 b _ = U1 c forall k (p :: k). U1 p U1 -- | @since 4.9.0.0 instance Alternative U1 where empty :: U1 a empty = U1 a forall k (p :: k). U1 p U1 U1 a _ <|> :: U1 a -> U1 a -> U1 a <|> U1 a _ = U1 a forall k (p :: k). U1 p U1 -- | @since 4.9.0.0 instance Monad U1 where U1 a _ >>= :: U1 a -> (a -> U1 b) -> U1 b >>= a -> U1 b _ = U1 b forall k (p :: k). U1 p U1 -- | @since 4.9.0.0 instance MonadPlus U1 -- | @since 4.12.0.0 instance Semigroup (U1 p) where U1 p _ <> :: U1 p -> U1 p -> U1 p <> U1 p _ = U1 p forall k (p :: k). U1 p U1 -- | @since 4.12.0.0 instance Monoid (U1 p) where mempty :: U1 p mempty = U1 p forall k (p :: k). U1 p U1 -- | Used for marking occurrences of the parameter newtype Par1 p = Par1 { Par1 p -> p unPar1 :: p } deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.9.0.0 instance Applicative Par1 where pure :: a -> Par1 a pure = a -> Par1 a forall a. a -> Par1 a Par1 <*> :: Par1 (a -> b) -> Par1 a -> Par1 b (<*>) = Par1 (a -> b) -> Par1 a -> Par1 b coerce liftA2 :: (a -> b -> c) -> Par1 a -> Par1 b -> Par1 c liftA2 = (a -> b -> c) -> Par1 a -> Par1 b -> Par1 c coerce -- | @since 4.9.0.0 instance Monad Par1 where Par1 a x >>= :: Par1 a -> (a -> Par1 b) -> Par1 b >>= a -> Par1 b f = a -> Par1 b f a x -- | @since 4.12.0.0 deriving instance Semigroup p => Semigroup (Par1 p) -- | @since 4.12.0.0 deriving instance Monoid p => Monoid (Par1 p) -- | Recursive calls of kind @* -> *@ (or kind @k -> *@, when @PolyKinds@ -- is enabled) newtype Rec1 (f :: k -> Type) (p :: k) = Rec1 { Rec1 f p -> f p unRec1 :: f p } deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.9.0.0 deriving instance Applicative f => Applicative (Rec1 f) -- | @since 4.9.0.0 deriving instance Alternative f => Alternative (Rec1 f) -- | @since 4.9.0.0 instance Monad f => Monad (Rec1 f) where Rec1 f a x >>= :: Rec1 f a -> (a -> Rec1 f b) -> Rec1 f b >>= a -> Rec1 f b f = f b -> Rec1 f b forall k (f :: k -> *) (p :: k). f p -> Rec1 f p Rec1 (f a x f a -> (a -> f b) -> f b forall (m :: * -> *) a b. Monad m => m a -> (a -> m b) -> m b >>= \a a -> Rec1 f b -> f b forall k (f :: k -> *) (p :: k). Rec1 f p -> f p unRec1 (a -> Rec1 f b f a a)) -- | @since 4.9.0.0 deriving instance MonadPlus f => MonadPlus (Rec1 f) -- | @since 4.12.0.0 deriving instance Semigroup (f p) => Semigroup (Rec1 f p) -- | @since 4.12.0.0 deriving instance Monoid (f p) => Monoid (Rec1 f p) -- | Constants, additional parameters and recursion of kind @*@ newtype K1 (i :: Type) c (p :: k) = K1 { K1 i c p -> c unK1 :: c } deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.12.0.0 instance Monoid c => Applicative (K1 i c) where pure :: a -> K1 i c a pure a _ = c -> K1 i c a forall k i c (p :: k). c -> K1 i c p K1 c forall a. Monoid a => a mempty liftA2 :: (a -> b -> c) -> K1 i c a -> K1 i c b -> K1 i c c liftA2 = \a -> b -> c _ -> (c -> c -> c) -> K1 i c a -> K1 i c b -> K1 i c c coerce (c -> c -> c forall a. Monoid a => a -> a -> a mappend :: c -> c -> c) <*> :: K1 i c (a -> b) -> K1 i c a -> K1 i c b (<*>) = (c -> c -> c) -> K1 i c (a -> b) -> K1 i c a -> K1 i c b coerce (c -> c -> c forall a. Monoid a => a -> a -> a mappend :: c -> c -> c) -- | @since 4.12.0.0 deriving instance Semigroup c => Semigroup (K1 i c p) -- | @since 4.12.0.0 deriving instance Monoid c => Monoid (K1 i c p) -- | @since 4.9.0.0 deriving instance Applicative f => Applicative (M1 i c f) -- | @since 4.9.0.0 deriving instance Alternative f => Alternative (M1 i c f) -- | @since 4.9.0.0 deriving instance Monad f => Monad (M1 i c f) -- | @since 4.9.0.0 deriving instance MonadPlus f => MonadPlus (M1 i c f) -- | @since 4.12.0.0 deriving instance Semigroup (f p) => Semigroup (M1 i c f p) -- | @since 4.12.0.0 deriving instance Monoid (f p) => Monoid (M1 i c f p) -- | Meta-information (constructor names, etc.) newtype M1 (i :: Type) (c :: Meta) (f :: k -> Type) (p :: k) = M1 { M1 i c f p -> f p unM1 :: f p } deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Sums: encode choice between constructors infixr 5 :+: data (:+:) (f :: k -> Type) (g :: k -> Type) (p :: k) = L1 (f p) | R1 (g p) deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Products: encode multiple arguments to constructors infixr 6 :*: data (:*:) (f :: k -> Type) (g :: k -> Type) (p :: k) = f p :*: g p deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.9.0.0 instance (Applicative f, Applicative g) => Applicative (f :*: g) where pure :: a -> (:*:) f g a pure a a = a -> f a forall (f :: * -> *) a. Applicative f => a -> f a pure a a f a -> g a -> (:*:) f g a forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: a -> g a forall (f :: * -> *) a. Applicative f => a -> f a pure a a (f (a -> b) f :*: g (a -> b) g) <*> :: (:*:) f g (a -> b) -> (:*:) f g a -> (:*:) f g b <*> (f a x :*: g a y) = (f (a -> b) f f (a -> b) -> f a -> f b forall (f :: * -> *) a b. Applicative f => f (a -> b) -> f a -> f b <*> f a x) f b -> g b -> (:*:) f g b forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: (g (a -> b) g g (a -> b) -> g a -> g b forall (f :: * -> *) a b. Applicative f => f (a -> b) -> f a -> f b <*> g a y) liftA2 :: (a -> b -> c) -> (:*:) f g a -> (:*:) f g b -> (:*:) f g c liftA2 a -> b -> c f (f a a :*: g a b) (f b x :*: g b y) = (a -> b -> c) -> f a -> f b -> f c forall (f :: * -> *) a b c. Applicative f => (a -> b -> c) -> f a -> f b -> f c liftA2 a -> b -> c f f a a f b x f c -> g c -> (:*:) f g c forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: (a -> b -> c) -> g a -> g b -> g c forall (f :: * -> *) a b c. Applicative f => (a -> b -> c) -> f a -> f b -> f c liftA2 a -> b -> c f g a b g b y -- | @since 4.9.0.0 instance (Alternative f, Alternative g) => Alternative (f :*: g) where empty :: (:*:) f g a empty = f a forall (f :: * -> *) a. Alternative f => f a empty f a -> g a -> (:*:) f g a forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: g a forall (f :: * -> *) a. Alternative f => f a empty (f a x1 :*: g a y1) <|> :: (:*:) f g a -> (:*:) f g a -> (:*:) f g a <|> (f a x2 :*: g a y2) = (f a x1 f a -> f a -> f a forall (f :: * -> *) a. Alternative f => f a -> f a -> f a <|> f a x2) f a -> g a -> (:*:) f g a forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: (g a y1 g a -> g a -> g a forall (f :: * -> *) a. Alternative f => f a -> f a -> f a <|> g a y2) -- | @since 4.9.0.0 instance (Monad f, Monad g) => Monad (f :*: g) where (f a m :*: g a n) >>= :: (:*:) f g a -> (a -> (:*:) f g b) -> (:*:) f g b >>= a -> (:*:) f g b f = (f a m f a -> (a -> f b) -> f b forall (m :: * -> *) a b. Monad m => m a -> (a -> m b) -> m b >>= \a a -> (:*:) f g b -> f b forall k (f :: k -> *) (g :: k -> *) (p :: k). (:*:) f g p -> f p fstP (a -> (:*:) f g b f a a)) f b -> g b -> (:*:) f g b forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: (g a n g a -> (a -> g b) -> g b forall (m :: * -> *) a b. Monad m => m a -> (a -> m b) -> m b >>= \a a -> (:*:) f g b -> g b forall k (f :: k -> *) (g :: k -> *) (p :: k). (:*:) f g p -> g p sndP (a -> (:*:) f g b f a a)) where fstP :: (:*:) f g p -> f p fstP (f p a :*: g p _) = f p a sndP :: (:*:) f g p -> g p sndP (f p _ :*: g p b) = g p b -- | @since 4.9.0.0 instance (MonadPlus f, MonadPlus g) => MonadPlus (f :*: g) -- | @since 4.12.0.0 instance (Semigroup (f p), Semigroup (g p)) => Semigroup ((f :*: g) p) where (f p x1 :*: g p y1) <> :: (:*:) f g p -> (:*:) f g p -> (:*:) f g p <> (f p x2 :*: g p y2) = (f p x1 f p -> f p -> f p forall a. Semigroup a => a -> a -> a <> f p x2) f p -> g p -> (:*:) f g p forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: (g p y1 g p -> g p -> g p forall a. Semigroup a => a -> a -> a <> g p y2) -- | @since 4.12.0.0 instance (Monoid (f p), Monoid (g p)) => Monoid ((f :*: g) p) where mempty :: (:*:) f g p mempty = f p forall a. Monoid a => a mempty f p -> g p -> (:*:) f g p forall k (f :: k -> *) (g :: k -> *) (p :: k). f p -> g p -> (:*:) f g p :*: g p forall a. Monoid a => a mempty -- | Composition of functors infixr 7 :.: newtype (:.:) (f :: k2 -> Type) (g :: k1 -> k2) (p :: k1) = Comp1 { (:.:) f g p -> f (g p) unComp1 :: f (g p) } deriving ( Eq -- ^ @since 4.7.0.0 , Ord -- ^ @since 4.7.0.0 , Read -- ^ @since 4.7.0.0 , Show -- ^ @since 4.7.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | @since 4.9.0.0 instance (Applicative f, Applicative g) => Applicative (f :.: g) where pure :: a -> (:.:) f g a pure a x = f (g a) -> (:.:) f g a forall k2 k1 (f :: k2 -> *) (g :: k1 -> k2) (p :: k1). f (g p) -> (:.:) f g p Comp1 (g a -> f (g a) forall (f :: * -> *) a. Applicative f => a -> f a pure (a -> g a forall (f :: * -> *) a. Applicative f => a -> f a pure a x)) Comp1 f (g (a -> b)) f <*> :: (:.:) f g (a -> b) -> (:.:) f g a -> (:.:) f g b <*> Comp1 f (g a) x = f (g b) -> (:.:) f g b forall k2 k1 (f :: k2 -> *) (g :: k1 -> k2) (p :: k1). f (g p) -> (:.:) f g p Comp1 ((g (a -> b) -> g a -> g b) -> f (g (a -> b)) -> f (g a) -> f (g b) forall (f :: * -> *) a b c. Applicative f => (a -> b -> c) -> f a -> f b -> f c liftA2 g (a -> b) -> g a -> g b forall (f :: * -> *) a b. Applicative f => f (a -> b) -> f a -> f b (<*>) f (g (a -> b)) f f (g a) x) liftA2 :: (a -> b -> c) -> (:.:) f g a -> (:.:) f g b -> (:.:) f g c liftA2 a -> b -> c f (Comp1 f (g a) x) (Comp1 f (g b) y) = f (g c) -> (:.:) f g c forall k2 k1 (f :: k2 -> *) (g :: k1 -> k2) (p :: k1). f (g p) -> (:.:) f g p Comp1 ((g a -> g b -> g c) -> f (g a) -> f (g b) -> f (g c) forall (f :: * -> *) a b c. Applicative f => (a -> b -> c) -> f a -> f b -> f c liftA2 ((a -> b -> c) -> g a -> g b -> g c forall (f :: * -> *) a b c. Applicative f => (a -> b -> c) -> f a -> f b -> f c liftA2 a -> b -> c f) f (g a) x f (g b) y) -- | @since 4.9.0.0 instance (Alternative f, Applicative g) => Alternative (f :.: g) where empty :: (:.:) f g a empty = f (g a) -> (:.:) f g a forall k2 k1 (f :: k2 -> *) (g :: k1 -> k2) (p :: k1). f (g p) -> (:.:) f g p Comp1 f (g a) forall (f :: * -> *) a. Alternative f => f a empty <|> :: (:.:) f g a -> (:.:) f g a -> (:.:) f g a (<|>) = (f (g a) -> f (g a) -> f (g a)) -> (:.:) f g a -> (:.:) f g a -> (:.:) f g a coerce (f (g a) -> f (g a) -> f (g a) forall (f :: * -> *) a. Alternative f => f a -> f a -> f a (<|>) :: f (g a) -> f (g a) -> f (g a)) :: forall a . (f :.: g) a -> (f :.: g) a -> (f :.: g) a -- | @since 4.12.0.0 deriving instance Semigroup (f (g p)) => Semigroup ((f :.: g) p) -- | @since 4.12.0.0 deriving instance Monoid (f (g p)) => Monoid ((f :.: g) p) -- | Constants of unlifted kinds -- -- @since 4.9.0.0 data family URec (a :: Type) (p :: k) -- | Used for marking occurrences of 'Addr#' -- -- @since 4.9.0.0 data instance URec (Ptr ()) (p :: k) = UAddr { URec (Ptr ()) p -> Addr# uAddr# :: Addr# } deriving ( Eq -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Used for marking occurrences of 'Char#' -- -- @since 4.9.0.0 data instance URec Char (p :: k) = UChar { URec Char p -> Char# uChar# :: Char# } deriving ( Eq -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Used for marking occurrences of 'Double#' -- -- @since 4.9.0.0 data instance URec Double (p :: k) = UDouble { URec Double p -> Double# uDouble# :: Double# } deriving ( Eq -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Used for marking occurrences of 'Float#' -- -- @since 4.9.0.0 data instance URec Float (p :: k) = UFloat { URec Float p -> Float# uFloat# :: Float# } deriving ( URec Float p -> URec Float p -> Bool (URec Float p -> URec Float p -> Bool) -> (URec Float p -> URec Float p -> Bool) -> Eq (URec Float p) forall a. (a -> a -> Bool) -> (a -> a -> Bool) -> Eq a forall k (p :: k). URec Float p -> URec Float p -> Bool /= :: URec Float p -> URec Float p -> Bool $c/= :: forall k (p :: k). URec Float p -> URec Float p -> Bool == :: URec Float p -> URec Float p -> Bool $c== :: forall k (p :: k). URec Float p -> URec Float p -> Bool Eq, Eq (URec Float p) Eq (URec Float p) -> (URec Float p -> URec Float p -> Ordering) -> (URec Float p -> URec Float p -> Bool) -> (URec Float p -> URec Float p -> Bool) -> (URec Float p -> URec Float p -> Bool) -> (URec Float p -> URec Float p -> Bool) -> (URec Float p -> URec Float p -> URec Float p) -> (URec Float p -> URec Float p -> URec Float p) -> Ord (URec Float p) URec Float p -> URec Float p -> Bool URec Float p -> URec Float p -> Ordering URec Float p -> URec Float p -> URec Float p forall a. Eq a -> (a -> a -> Ordering) -> (a -> a -> Bool) -> (a -> a -> Bool) -> (a -> a -> Bool) -> (a -> a -> Bool) -> (a -> a -> a) -> (a -> a -> a) -> Ord a forall k (p :: k). Eq (URec Float p) forall k (p :: k). URec Float p -> URec Float p -> Bool forall k (p :: k). URec Float p -> URec Float p -> Ordering forall k (p :: k). URec Float p -> URec Float p -> URec Float p min :: URec Float p -> URec Float p -> URec Float p $cmin :: forall k (p :: k). URec Float p -> URec Float p -> URec Float p max :: URec Float p -> URec Float p -> URec Float p $cmax :: forall k (p :: k). URec Float p -> URec Float p -> URec Float p >= :: URec Float p -> URec Float p -> Bool $c>= :: forall k (p :: k). URec Float p -> URec Float p -> Bool > :: URec Float p -> URec Float p -> Bool $c> :: forall k (p :: k). URec Float p -> URec Float p -> Bool <= :: URec Float p -> URec Float p -> Bool $c<= :: forall k (p :: k). URec Float p -> URec Float p -> Bool < :: URec Float p -> URec Float p -> Bool $c< :: forall k (p :: k). URec Float p -> URec Float p -> Bool compare :: URec Float p -> URec Float p -> Ordering $ccompare :: forall k (p :: k). URec Float p -> URec Float p -> Ordering $cp1Ord :: forall k (p :: k). Eq (URec Float p) Ord, Int -> URec Float p -> ShowS [URec Float p] -> ShowS URec Float p -> String (Int -> URec Float p -> ShowS) -> (URec Float p -> String) -> ([URec Float p] -> ShowS) -> Show (URec Float p) forall a. (Int -> a -> ShowS) -> (a -> String) -> ([a] -> ShowS) -> Show a forall k (p :: k). Int -> URec Float p -> ShowS forall k (p :: k). [URec Float p] -> ShowS forall k (p :: k). URec Float p -> String showList :: [URec Float p] -> ShowS $cshowList :: forall k (p :: k). [URec Float p] -> ShowS show :: URec Float p -> String $cshow :: forall k (p :: k). URec Float p -> String showsPrec :: Int -> URec Float p -> ShowS $cshowsPrec :: forall k (p :: k). Int -> URec Float p -> ShowS Show , Functor -- ^ @since 4.9.0.0 , (forall x. URec Float p -> Rep (URec Float p) x) -> (forall x. Rep (URec Float p) x -> URec Float p) -> Generic (URec Float p) forall x. Rep (URec Float p) x -> URec Float p forall x. URec Float p -> Rep (URec Float p) x forall a. (forall x. a -> Rep a x) -> (forall x. Rep a x -> a) -> Generic a forall k (p :: k) x. Rep (URec Float p) x -> URec Float p forall k (p :: k) x. URec Float p -> Rep (URec Float p) x $cto :: forall k (p :: k) x. Rep (URec Float p) x -> URec Float p $cfrom :: forall k (p :: k) x. URec Float p -> Rep (URec Float p) x Generic , Generic1 -- ^ @since 4.9.0.0 ) -- | Used for marking occurrences of 'Int#' -- -- @since 4.9.0.0 data instance URec Int (p :: k) = UInt { URec Int p -> Int# uInt# :: Int# } deriving ( Eq -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Used for marking occurrences of 'Word#' -- -- @since 4.9.0.0 data instance URec Word (p :: k) = UWord { URec Word p -> Word# uWord# :: Word# } deriving ( Eq -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Functor -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 , Generic1 -- ^ @since 4.9.0.0 ) -- | Type synonym for @'URec' 'Addr#'@ -- -- @since 4.9.0.0 type UAddr = URec (Ptr ()) -- | Type synonym for @'URec' 'Char#'@ -- -- @since 4.9.0.0 type UChar = URec Char -- | Type synonym for @'URec' 'Double#'@ -- -- @since 4.9.0.0 type UDouble = URec Double -- | Type synonym for @'URec' 'Float#'@ -- -- @since 4.9.0.0 type UFloat = URec Float -- | Type synonym for @'URec' 'Int#'@ -- -- @since 4.9.0.0 type UInt = URec Int -- | Type synonym for @'URec' 'Word#'@ -- -- @since 4.9.0.0 type UWord = URec Word -- | Tag for K1: recursion (of kind @Type@) data R -- | Type synonym for encoding recursion (of kind @Type@) type Rec0 = K1 R -- | Tag for M1: datatype data D -- | Tag for M1: constructor data C -- | Tag for M1: record selector data S -- | Type synonym for encoding meta-information for datatypes type D1 = M1 D -- | Type synonym for encoding meta-information for constructors type C1 = M1 C -- | Type synonym for encoding meta-information for record selectors type S1 = M1 S -- | Class for datatypes that represent datatypes class Datatype d where -- | The name of the datatype (unqualified) datatypeName :: t d (f :: k -> Type) (a :: k) -> [Char] -- | The fully-qualified name of the module where the type is declared moduleName :: t d (f :: k -> Type) (a :: k) -> [Char] -- | The package name of the module where the type is declared -- -- @since 4.9.0.0 packageName :: t d (f :: k -> Type) (a :: k) -> [Char] -- | Marks if the datatype is actually a newtype -- -- @since 4.7.0.0 isNewtype :: t d (f :: k -> Type) (a :: k) -> Bool isNewtype t d f a _ = Bool False -- | @since 4.9.0.0 instance (KnownSymbol n, KnownSymbol m, KnownSymbol p, SingI nt) => Datatype ('MetaData n m p nt) where datatypeName :: t ('MetaData n m p nt) f a -> String datatypeName t ('MetaData n m p nt) f a _ = Proxy n -> String forall (n :: Symbol) (proxy :: Symbol -> *). KnownSymbol n => proxy n -> String symbolVal (Proxy n forall k (t :: k). Proxy t Proxy :: Proxy n) moduleName :: t ('MetaData n m p nt) f a -> String moduleName t ('MetaData n m p nt) f a _ = Proxy m -> String forall (n :: Symbol) (proxy :: Symbol -> *). KnownSymbol n => proxy n -> String symbolVal (Proxy m forall k (t :: k). Proxy t Proxy :: Proxy m) packageName :: t ('MetaData n m p nt) f a -> String packageName t ('MetaData n m p nt) f a _ = Proxy p -> String forall (n :: Symbol) (proxy :: Symbol -> *). KnownSymbol n => proxy n -> String symbolVal (Proxy p forall k (t :: k). Proxy t Proxy :: Proxy p) isNewtype :: t ('MetaData n m p nt) f a -> Bool isNewtype t ('MetaData n m p nt) f a _ = Sing nt -> DemoteRep Bool forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing nt forall k (a :: k). SingI a => Sing a sing :: Sing nt) -- | Class for datatypes that represent data constructors class Constructor c where -- | The name of the constructor conName :: t c (f :: k -> Type) (a :: k) -> [Char] -- | The fixity of the constructor conFixity :: t c (f :: k -> Type) (a :: k) -> Fixity conFixity t c f a _ = Fixity Prefix -- | Marks if this constructor is a record conIsRecord :: t c (f :: k -> Type) (a :: k) -> Bool conIsRecord t c f a _ = Bool False -- | @since 4.9.0.0 instance (KnownSymbol n, SingI f, SingI r) => Constructor ('MetaCons n f r) where conName :: t ('MetaCons n f r) f a -> String conName t ('MetaCons n f r) f a _ = Proxy n -> String forall (n :: Symbol) (proxy :: Symbol -> *). KnownSymbol n => proxy n -> String symbolVal (Proxy n forall k (t :: k). Proxy t Proxy :: Proxy n) conFixity :: t ('MetaCons n f r) f a -> Fixity conFixity t ('MetaCons n f r) f a _ = Sing f -> DemoteRep FixityI forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing f forall k (a :: k). SingI a => Sing a sing :: Sing f) conIsRecord :: t ('MetaCons n f r) f a -> Bool conIsRecord t ('MetaCons n f r) f a _ = Sing r -> DemoteRep Bool forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing r forall k (a :: k). SingI a => Sing a sing :: Sing r) -- | Datatype to represent the fixity of a constructor. An infix -- | declaration directly corresponds to an application of 'Infix'. data Fixity = Prefix | Infix Associativity Int deriving ( Eq -- ^ @since 4.6.0.0 , Show -- ^ @since 4.6.0.0 , Ord -- ^ @since 4.6.0.0 , Read -- ^ @since 4.6.0.0 , Generic -- ^ @since 4.7.0.0 ) -- | This variant of 'Fixity' appears at the type level. -- -- @since 4.9.0.0 data FixityI = PrefixI | InfixI Associativity Nat -- | Get the precedence of a fixity value. prec :: Fixity -> Int prec :: Fixity -> Int prec Fixity Prefix = Int 10 prec (Infix Associativity _ Int n) = Int n -- | Datatype to represent the associativity of a constructor data Associativity = LeftAssociative | RightAssociative | NotAssociative deriving ( Eq -- ^ @since 4.6.0.0 , Show -- ^ @since 4.6.0.0 , Ord -- ^ @since 4.6.0.0 , Read -- ^ @since 4.6.0.0 , Enum -- ^ @since 4.9.0.0 , Bounded -- ^ @since 4.9.0.0 , Ix -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.7.0.0 ) -- | The unpackedness of a field as the user wrote it in the source code. For -- example, in the following data type: -- -- @ -- data E = ExampleConstructor Int -- {\-\# NOUNPACK \#-\} Int -- {\-\# UNPACK \#-\} Int -- @ -- -- The fields of @ExampleConstructor@ have 'NoSourceUnpackedness', -- 'SourceNoUnpack', and 'SourceUnpack', respectively. -- -- @since 4.9.0.0 data SourceUnpackedness = NoSourceUnpackedness | SourceNoUnpack | SourceUnpack deriving ( Eq -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Read -- ^ @since 4.9.0.0 , Enum -- ^ @since 4.9.0.0 , Bounded -- ^ @since 4.9.0.0 , Ix -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 ) -- | The strictness of a field as the user wrote it in the source code. For -- example, in the following data type: -- -- @ -- data E = ExampleConstructor Int ~Int !Int -- @ -- -- The fields of @ExampleConstructor@ have 'NoSourceStrictness', -- 'SourceLazy', and 'SourceStrict', respectively. -- -- @since 4.9.0.0 data SourceStrictness = NoSourceStrictness | SourceLazy | SourceStrict deriving ( Eq -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Read -- ^ @since 4.9.0.0 , Enum -- ^ @since 4.9.0.0 , Bounded -- ^ @since 4.9.0.0 , Ix -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 ) -- | The strictness that GHC infers for a field during compilation. Whereas -- there are nine different combinations of 'SourceUnpackedness' and -- 'SourceStrictness', the strictness that GHC decides will ultimately be one -- of lazy, strict, or unpacked. What GHC decides is affected both by what the -- user writes in the source code and by GHC flags. As an example, consider -- this data type: -- -- @ -- data E = ExampleConstructor {\-\# UNPACK \#-\} !Int !Int Int -- @ -- -- * If compiled without optimization or other language extensions, then the -- fields of @ExampleConstructor@ will have 'DecidedStrict', 'DecidedStrict', -- and 'DecidedLazy', respectively. -- -- * If compiled with @-XStrictData@ enabled, then the fields will have -- 'DecidedStrict', 'DecidedStrict', and 'DecidedStrict', respectively. -- -- * If compiled with @-O2@ enabled, then the fields will have 'DecidedUnpack', -- 'DecidedStrict', and 'DecidedLazy', respectively. -- -- @since 4.9.0.0 data DecidedStrictness = DecidedLazy | DecidedStrict | DecidedUnpack deriving ( Eq -- ^ @since 4.9.0.0 , Show -- ^ @since 4.9.0.0 , Ord -- ^ @since 4.9.0.0 , Read -- ^ @since 4.9.0.0 , Enum -- ^ @since 4.9.0.0 , Bounded -- ^ @since 4.9.0.0 , Ix -- ^ @since 4.9.0.0 , Generic -- ^ @since 4.9.0.0 ) -- | Class for datatypes that represent records class Selector s where -- | The name of the selector selName :: t s (f :: k -> Type) (a :: k) -> [Char] -- | The selector's unpackedness annotation (if any) -- -- @since 4.9.0.0 selSourceUnpackedness :: t s (f :: k -> Type) (a :: k) -> SourceUnpackedness -- | The selector's strictness annotation (if any) -- -- @since 4.9.0.0 selSourceStrictness :: t s (f :: k -> Type) (a :: k) -> SourceStrictness -- | The strictness that the compiler inferred for the selector -- -- @since 4.9.0.0 selDecidedStrictness :: t s (f :: k -> Type) (a :: k) -> DecidedStrictness -- | @since 4.9.0.0 instance (SingI mn, SingI su, SingI ss, SingI ds) => Selector ('MetaSel mn su ss ds) where selName :: t ('MetaSel mn su ss ds) f a -> String selName t ('MetaSel mn su ss ds) f a _ = String -> Maybe String -> String forall a. a -> Maybe a -> a fromMaybe String "" (Sing mn -> DemoteRep (Maybe Symbol) forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing mn forall k (a :: k). SingI a => Sing a sing :: Sing mn)) selSourceUnpackedness :: t ('MetaSel mn su ss ds) f a -> SourceUnpackedness selSourceUnpackedness t ('MetaSel mn su ss ds) f a _ = Sing su -> DemoteRep SourceUnpackedness forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing su forall k (a :: k). SingI a => Sing a sing :: Sing su) selSourceStrictness :: t ('MetaSel mn su ss ds) f a -> SourceStrictness selSourceStrictness t ('MetaSel mn su ss ds) f a _ = Sing ss -> DemoteRep SourceStrictness forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing ss forall k (a :: k). SingI a => Sing a sing :: Sing ss) selDecidedStrictness :: t ('MetaSel mn su ss ds) f a -> DecidedStrictness selDecidedStrictness t ('MetaSel mn su ss ds) f a _ = Sing ds -> DemoteRep DecidedStrictness forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing (Sing ds forall k (a :: k). SingI a => Sing a sing :: Sing ds) -- | Representable types of kind @*@. -- This class is derivable in GHC with the @DeriveGeneric@ flag on. -- -- A 'Generic' instance must satisfy the following laws: -- -- @ -- 'from' . 'to' ≡ 'Prelude.id' -- 'to' . 'from' ≡ 'Prelude.id' -- @ class Generic a where -- | Generic representation type type Rep a :: Type -> Type -- | Convert from the datatype to its representation from :: a -> (Rep a) x -- | Convert from the representation to the datatype to :: (Rep a) x -> a -- | Representable types of kind @* -> *@ (or kind @k -> *@, when @PolyKinds@ -- is enabled). -- This class is derivable in GHC with the @DeriveGeneric@ flag on. -- -- A 'Generic1' instance must satisfy the following laws: -- -- @ -- 'from1' . 'to1' ≡ 'Prelude.id' -- 'to1' . 'from1' ≡ 'Prelude.id' -- @ class Generic1 (f :: k -> Type) where -- | Generic representation type type Rep1 f :: k -> Type -- | Convert from the datatype to its representation from1 :: f a -> (Rep1 f) a -- | Convert from the representation to the datatype to1 :: (Rep1 f) a -> f a -------------------------------------------------------------------------------- -- Meta-data -------------------------------------------------------------------------------- -- | Datatype to represent metadata associated with a datatype (@MetaData@), -- constructor (@MetaCons@), or field selector (@MetaSel@). -- -- * In @MetaData n m p nt@, @n@ is the datatype's name, @m@ is the module in -- which the datatype is defined, @p@ is the package in which the datatype -- is defined, and @nt@ is @'True@ if the datatype is a @newtype@. -- -- * In @MetaCons n f s@, @n@ is the constructor's name, @f@ is its fixity, -- and @s@ is @'True@ if the constructor contains record selectors. -- -- * In @MetaSel mn su ss ds@, if the field uses record syntax, then @mn@ is -- 'Just' the record name. Otherwise, @mn@ is 'Nothing'. @su@ and @ss@ are -- the field's unpackedness and strictness annotations, and @ds@ is the -- strictness that GHC infers for the field. -- -- @since 4.9.0.0 data Meta = MetaData Symbol Symbol Symbol Bool | MetaCons Symbol FixityI Bool | MetaSel (Maybe Symbol) SourceUnpackedness SourceStrictness DecidedStrictness -------------------------------------------------------------------------------- -- Derived instances -------------------------------------------------------------------------------- -- | @since 4.6.0.0 deriving instance Generic [a] -- | @since 4.6.0.0 deriving instance Generic (NonEmpty a) -- | @since 4.6.0.0 deriving instance Generic (Maybe a) -- | @since 4.6.0.0 deriving instance Generic (Either a b) -- | @since 4.6.0.0 deriving instance Generic Bool -- | @since 4.6.0.0 deriving instance Generic Ordering -- | @since 4.6.0.0 deriving instance Generic (Proxy t) -- | @since 4.6.0.0 deriving instance Generic () -- | @since 4.6.0.0 deriving instance Generic ((,) a b) -- | @since 4.6.0.0 deriving instance Generic ((,,) a b c) -- | @since 4.6.0.0 deriving instance Generic ((,,,) a b c d) -- | @since 4.6.0.0 deriving instance Generic ((,,,,) a b c d e) -- | @since 4.6.0.0 deriving instance Generic ((,,,,,) a b c d e f) -- | @since 4.6.0.0 deriving instance Generic ((,,,,,,) a b c d e f g) -- | @since 4.12.0.0 deriving instance Generic (Down a) -- | @since 4.6.0.0 deriving instance Generic1 [] -- | @since 4.6.0.0 deriving instance Generic1 NonEmpty -- | @since 4.6.0.0 deriving instance Generic1 Maybe -- | @since 4.6.0.0 deriving instance Generic1 (Either a) -- | @since 4.6.0.0 deriving instance Generic1 Proxy -- | @since 4.6.0.0 deriving instance Generic1 ((,) a) -- | @since 4.6.0.0 deriving instance Generic1 ((,,) a b) -- | @since 4.6.0.0 deriving instance Generic1 ((,,,) a b c) -- | @since 4.6.0.0 deriving instance Generic1 ((,,,,) a b c d) -- | @since 4.6.0.0 deriving instance Generic1 ((,,,,,) a b c d e) -- | @since 4.6.0.0 deriving instance Generic1 ((,,,,,,) a b c d e f) -- | @since 4.12.0.0 deriving instance Generic1 Down -------------------------------------------------------------------------------- -- Copied from the singletons package -------------------------------------------------------------------------------- -- | The singleton kind-indexed data family. data family Sing (a :: k) -- | A 'SingI' constraint is essentially an implicitly-passed singleton. class SingI (a :: k) where -- | Produce the singleton explicitly. You will likely need the @ScopedTypeVariables@ -- extension to use this method the way you want. sing :: Sing a -- | The 'SingKind' class is essentially a /kind/ class. It classifies all kinds -- for which singletons are defined. The class supports converting between a singleton -- type and the base (unrefined) type which it is built from. class SingKind k where -- | Get a base type from a proxy for the promoted kind. For example, -- @DemoteRep Bool@ will be the type @Bool@. type DemoteRep k :: Type -- | Convert a singleton to its unrefined version. fromSing :: Sing (a :: k) -> DemoteRep k -- Singleton symbols data instance Sing (s :: Symbol) where SSym :: KnownSymbol s => Sing s -- | @since 4.9.0.0 instance KnownSymbol a => SingI a where sing :: Sing a sing = Sing a forall (a :: Symbol). KnownSymbol a => Sing a SSym -- | @since 4.9.0.0 instance SingKind Symbol where type DemoteRep Symbol = String fromSing :: Sing a -> DemoteRep Symbol fromSing (Sing a SSym :: Sing s) = Proxy a -> String forall (n :: Symbol) (proxy :: Symbol -> *). KnownSymbol n => proxy n -> String symbolVal (Proxy a forall k (t :: k). Proxy t Proxy :: Proxy s) -- Singleton booleans data instance Sing (a :: Bool) where STrue :: Sing 'True SFalse :: Sing 'False -- | @since 4.9.0.0 instance SingI 'True where sing :: Sing 'True sing = Sing 'True STrue -- | @since 4.9.0.0 instance SingI 'False where sing :: Sing 'False sing = Sing 'False SFalse -- | @since 4.9.0.0 instance SingKind Bool where type DemoteRep Bool = Bool fromSing :: Sing a -> DemoteRep Bool fromSing Sing a STrue = Bool DemoteRep Bool True fromSing Sing a SFalse = Bool DemoteRep Bool False -- Singleton Maybe data instance Sing (b :: Maybe a) where SNothing :: Sing 'Nothing SJust :: Sing a -> Sing ('Just a) -- | @since 4.9.0.0 instance SingI 'Nothing where sing :: Sing 'Nothing sing = Sing 'Nothing forall a. Sing 'Nothing SNothing -- | @since 4.9.0.0 instance SingI a => SingI ('Just a) where sing :: Sing ('Just a) sing = Sing a -> Sing ('Just a) forall a (a :: a). Sing a -> Sing ('Just a) SJust Sing a forall k (a :: k). SingI a => Sing a sing -- | @since 4.9.0.0 instance SingKind a => SingKind (Maybe a) where type DemoteRep (Maybe a) = Maybe (DemoteRep a) fromSing :: Sing a -> DemoteRep (Maybe a) fromSing Sing a SNothing = DemoteRep (Maybe a) forall a. Maybe a Nothing fromSing (SJust a) = DemoteRep a -> Maybe (DemoteRep a) forall a. a -> Maybe a Just (Sing a -> DemoteRep a forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing Sing a a) -- Singleton Fixity data instance Sing (a :: FixityI) where SPrefix :: Sing 'PrefixI SInfix :: Sing a -> Integer -> Sing ('InfixI a n) -- | @since 4.9.0.0 instance SingI 'PrefixI where sing :: Sing 'PrefixI sing = Sing 'PrefixI SPrefix -- | @since 4.9.0.0 instance (SingI a, KnownNat n) => SingI ('InfixI a n) where sing :: Sing ('InfixI a n) sing = Sing a -> Integer -> Sing ('InfixI a n) forall (a :: Associativity) (n :: Nat). Sing a -> Integer -> Sing ('InfixI a n) SInfix (Sing a forall k (a :: k). SingI a => Sing a sing :: Sing a) (Proxy n -> Integer forall (n :: Nat) (proxy :: Nat -> *). KnownNat n => proxy n -> Integer natVal (Proxy n forall k (t :: k). Proxy t Proxy :: Proxy n)) -- | @since 4.9.0.0 instance SingKind FixityI where type DemoteRep FixityI = Fixity fromSing :: Sing a -> DemoteRep FixityI fromSing Sing a SPrefix = DemoteRep FixityI Fixity Prefix fromSing (SInfix a n) = Associativity -> Int -> Fixity Infix (Sing a -> DemoteRep Associativity forall k (a :: k). SingKind k => Sing a -> DemoteRep k fromSing Sing a a) (Int# -> Int I# (Integer -> Int# integerToInt Integer n)) -- Singleton Associativity data instance Sing (a :: Associativity) where SLeftAssociative :: Sing 'LeftAssociative SRightAssociative :: Sing 'RightAssociative SNotAssociative :: Sing 'NotAssociative -- | @since 4.9.0.0 instance SingI 'LeftAssociative where sing :: Sing 'LeftAssociative sing = Sing 'LeftAssociative SLeftAssociative -- | @since 4.9.0.0 instance SingI 'RightAssociative where sing :: Sing 'RightAssociative sing = Sing 'RightAssociative SRightAssociative -- | @since 4.9.0.0 instance SingI 'NotAssociative where sing :: Sing 'NotAssociative sing = Sing 'NotAssociative SNotAssociative -- | @since 4.0.0.0 instance SingKind Associativity where type DemoteRep Associativity = Associativity fromSing :: Sing a -> DemoteRep Associativity fromSing Sing a SLeftAssociative = DemoteRep Associativity Associativity LeftAssociative fromSing Sing a SRightAssociative = DemoteRep Associativity Associativity RightAssociative fromSing Sing a SNotAssociative = DemoteRep Associativity Associativity NotAssociative -- Singleton SourceUnpackedness data instance Sing (a :: SourceUnpackedness) where SNoSourceUnpackedness :: Sing 'NoSourceUnpackedness SSourceNoUnpack :: Sing 'SourceNoUnpack SSourceUnpack :: Sing 'SourceUnpack -- | @since 4.9.0.0 instance SingI 'NoSourceUnpackedness where sing :: Sing 'NoSourceUnpackedness sing = Sing 'NoSourceUnpackedness SNoSourceUnpackedness -- | @since 4.9.0.0 instance SingI 'SourceNoUnpack where sing :: Sing 'SourceNoUnpack sing = Sing 'SourceNoUnpack SSourceNoUnpack -- | @since 4.9.0.0 instance SingI 'SourceUnpack where sing :: Sing 'SourceUnpack sing = Sing 'SourceUnpack SSourceUnpack -- | @since 4.9.0.0 instance SingKind SourceUnpackedness where type DemoteRep SourceUnpackedness = SourceUnpackedness fromSing :: Sing a -> DemoteRep SourceUnpackedness fromSing Sing a SNoSourceUnpackedness = DemoteRep SourceUnpackedness SourceUnpackedness NoSourceUnpackedness fromSing Sing a SSourceNoUnpack = DemoteRep SourceUnpackedness SourceUnpackedness SourceNoUnpack fromSing Sing a SSourceUnpack = DemoteRep SourceUnpackedness SourceUnpackedness SourceUnpack -- Singleton SourceStrictness data instance Sing (a :: SourceStrictness) where SNoSourceStrictness :: Sing 'NoSourceStrictness SSourceLazy :: Sing 'SourceLazy SSourceStrict :: Sing 'SourceStrict -- | @since 4.9.0.0 instance SingI 'NoSourceStrictness where sing :: Sing 'NoSourceStrictness sing = Sing 'NoSourceStrictness SNoSourceStrictness -- | @since 4.9.0.0 instance SingI 'SourceLazy where sing :: Sing 'SourceLazy sing = Sing 'SourceLazy SSourceLazy -- | @since 4.9.0.0 instance SingI 'SourceStrict where sing :: Sing 'SourceStrict sing = Sing 'SourceStrict SSourceStrict -- | @since 4.9.0.0 instance SingKind SourceStrictness where type DemoteRep SourceStrictness = SourceStrictness fromSing :: Sing a -> DemoteRep SourceStrictness fromSing Sing a SNoSourceStrictness = DemoteRep SourceStrictness SourceStrictness NoSourceStrictness fromSing Sing a SSourceLazy = DemoteRep SourceStrictness SourceStrictness SourceLazy fromSing Sing a SSourceStrict = DemoteRep SourceStrictness SourceStrictness SourceStrict -- Singleton DecidedStrictness data instance Sing (a :: DecidedStrictness) where SDecidedLazy :: Sing 'DecidedLazy SDecidedStrict :: Sing 'DecidedStrict SDecidedUnpack :: Sing 'DecidedUnpack -- | @since 4.9.0.0 instance SingI 'DecidedLazy where sing :: Sing 'DecidedLazy sing = Sing 'DecidedLazy SDecidedLazy -- | @since 4.9.0.0 instance SingI 'DecidedStrict where sing :: Sing 'DecidedStrict sing = Sing 'DecidedStrict SDecidedStrict -- | @since 4.9.0.0 instance SingI 'DecidedUnpack where sing :: Sing 'DecidedUnpack sing = Sing 'DecidedUnpack SDecidedUnpack -- | @since 4.9.0.0 instance SingKind DecidedStrictness where type DemoteRep DecidedStrictness = DecidedStrictness fromSing :: Sing a -> DemoteRep DecidedStrictness fromSing Sing a SDecidedLazy = DemoteRep DecidedStrictness DecidedStrictness DecidedLazy fromSing Sing a SDecidedStrict = DemoteRep DecidedStrictness DecidedStrictness DecidedStrict fromSing Sing a SDecidedUnpack = DemoteRep DecidedStrictness DecidedStrictness DecidedUnpack