{-# LANGUAGE CPP #-}
#ifndef HASKELL98
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE EmptyDataDecls #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE KindSignatures #-}
{-# LANGUAGE StandaloneDeriving #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE TypeOperators #-}
# if __GLASGOW_HASKELL__ >= 702
{-# LANGUAGE Trustworthy #-}
# endif
# if __GLASGOW_HASKELL__ >= 706
{-# LANGUAGE PolyKinds #-}
# endif
# if __GLASGOW_HASKELL__ >= 708
{-# LANGUAGE DataKinds #-}
# endif
#endif
{-# OPTIONS_GHC -fno-warn-deprecations #-}
module Control.Monad.Trans.Instances () where
#ifndef MIN_VERSION_base
#define MIN_VERSION_base(a,b,c) 1
#endif
#ifndef MIN_VERSION_transformers
#define MIN_VERSION_transformers(a,b,c) 1
#endif
import Control.Applicative.Backwards (Backwards(..))
import Control.Applicative.Lift (Lift(..))
import Control.Monad.IO.Class (MonadIO)
import Control.Monad.Trans.Class (MonadTrans)
import Control.Monad.Trans.Cont (ContT(..))
import Control.Monad.Trans.Error (ErrorT(..))
import Control.Monad.Trans.Except ()
import Control.Monad.Trans.Identity (IdentityT(..))
import Control.Monad.Trans.List (ListT(..))
import Control.Monad.Trans.Maybe (MaybeT(..))
import qualified Control.Monad.Trans.RWS.Lazy as Lazy (RWST(..))
import qualified Control.Monad.Trans.RWS.Strict as Strict (RWST(..))
import Control.Monad.Trans.Reader (ReaderT(..))
import qualified Control.Monad.Trans.State.Lazy as Lazy (StateT(..))
import qualified Control.Monad.Trans.State.Strict as Strict (StateT(..))
import qualified Control.Monad.Trans.Writer.Lazy as Lazy (WriterT(..))
import qualified Control.Monad.Trans.Writer.Strict as Strict (WriterT(..))
import Data.Functor.Classes
import Data.Functor.Compose (Compose(..))
import Data.Functor.Constant (Constant(..))
import Data.Functor.Identity (Identity(..))
import Data.Functor.Product (Product(..))
import Data.Functor.Reverse (Reverse(..))
import Data.Functor.Sum (Sum(..))
import Control.Applicative
import Control.Arrow (Arrow((***)))
import Control.Monad (MonadPlus(..))
import Control.Monad.Fix (MonadFix(..))
import Data.Bits
import Data.Foldable (Foldable(..))
import Data.Ix (Ix(..))
import Data.Maybe (fromMaybe)
import Data.Monoid (Monoid(..))
import Data.String (IsString(fromString))
import Data.Traversable (Traversable(..))
import Foreign (Storable(..), castPtr)
#if MIN_VERSION_base(4,4,0)
import Control.Monad.Zip (MonadZip(..))
#endif
#if MIN_VERSION_base(4,7,0)
import Data.Proxy (Proxy(..))
#endif
#if MIN_VERSION_base(4,8,0)
import Data.Bifunctor (Bifunctor(..))
#endif
#if MIN_VERSION_base(4,9,0)
import qualified Control.Monad.Fail as Fail (MonadFail(..))
import qualified Data.Semigroup as Semigroup (Semigroup(..))
#endif
#if MIN_VERSION_base(4,10,0)
import Data.Bifoldable (Bifoldable(..))
import Data.Bitraversable (Bitraversable(..))
#endif
#ifndef HASKELL98
import Data.Data (Data)
import Data.Typeable
# ifdef GENERIC_DERIVING
import Generics.Deriving.Base
# elif __GLASGOW_HASKELL__ >= 702
import GHC.Generics
# endif
#endif
#if !(MIN_VERSION_transformers(0,3,0))
instance (Foldable f) => Foldable (ErrorT e f) where
foldMap f (ErrorT a) = foldMap (either (const mempty) f) a
instance (Traversable f) => Traversable (ErrorT e f) where
traverse f (ErrorT a) =
ErrorT <$> traverse (either (pure . Left) (fmap Right . f)) a
instance (Foldable f) => Foldable (IdentityT f) where
foldMap f (IdentityT a) = foldMap f a
instance (Traversable f) => Traversable (IdentityT f) where
traverse f (IdentityT a) = IdentityT <$> traverse f a
instance (Foldable f) => Foldable (ListT f) where
foldMap f (ListT a) = foldMap (foldMap f) a
instance (Traversable f) => Traversable (ListT f) where
traverse f (ListT a) = ListT <$> traverse (traverse f) a
instance (Foldable f) => Foldable (MaybeT f) where
foldMap f (MaybeT a) = foldMap (foldMap f) a
instance (Traversable f) => Traversable (MaybeT f) where
traverse f (MaybeT a) = MaybeT <$> traverse (traverse f) a
instance (Foldable f) => Foldable (Lazy.WriterT w f) where
foldMap f = foldMap (f . fst) . Lazy.runWriterT
instance (Traversable f) => Traversable (Lazy.WriterT w f) where
traverse f = fmap Lazy.WriterT . traverse f' . Lazy.runWriterT where
f' (a, b) = fmap (\ c -> (c, b)) (f a)
instance (Foldable f) => Foldable (Strict.WriterT w f) where
foldMap f = foldMap (f . fst) . Strict.runWriterT
instance (Traversable f) => Traversable (Strict.WriterT w f) where
traverse f = fmap Strict.WriterT . traverse f' . Strict.runWriterT where
f' (a, b) = fmap (\ c -> (c, b)) (f a)
instance (MonadFix m) => MonadFix (IdentityT m) where
mfix f = IdentityT (mfix (runIdentityT . f))
instance (MonadFix m) => MonadFix (MaybeT m) where
mfix f = MaybeT (mfix (runMaybeT . f . fromMaybe bomb))
where bomb = error "mfix (MaybeT): inner computation returned Nothing"
# if !(MIN_VERSION_base(4,9,0))
instance (Monad f, Monad g) => Monad (Product f g) where
return x = Pair (return x) (return x)
Pair m n >>= f = Pair (m >>= fstP . f) (n >>= sndP . f)
where
fstP (Pair a _) = a
sndP (Pair _ b) = b
instance (MonadPlus f, MonadPlus g) => MonadPlus (Product f g) where
mzero = Pair mzero mzero
Pair x1 y1 `mplus` Pair x2 y2 = Pair (x1 `mplus` x2) (y1 `mplus` y2)
instance (MonadFix f, MonadFix g) => MonadFix (Product f g) where
mfix f = Pair (mfix (fstP . f)) (mfix (sndP . f))
where
fstP (Pair a _) = a
sndP (Pair _ b) = b
# endif
#endif
#if !(MIN_VERSION_transformers(0,4,0))
# if !(MIN_VERSION_base(4,9,0))
instance Alternative IO where
empty = mzero
(<|>) = mplus
# endif
#endif
#if MIN_VERSION_transformers(0,4,0) && !(MIN_VERSION_transformers(0,4,3))
instance (Eq a) => Eq1 (Const a) where
eq1 (Const x) (Const y) = x == y
instance (Ord a) => Ord1 (Const a) where
compare1 (Const x) (Const y) = compare x y
instance (Read a) => Read1 (Const a) where
readsPrec1 = readsData $ readsUnary "Const" Const
instance (Show a) => Show1 (Const a) where
showsPrec1 d (Const x) = showsUnary "Const" d x
#endif
#if !(MIN_VERSION_transformers(0,5,0))
instance (Monoid a) => Monoid (Constant a b) where
mempty = Constant mempty
Constant x `mappend` Constant y = Constant (x `mappend` y)
# if MIN_VERSION_base(4,4,0)
instance (MonadZip m) => MonadZip (IdentityT m) where
mzipWith f (IdentityT a) (IdentityT b) = IdentityT (mzipWith f a b)
instance (MonadZip m) => MonadZip (ListT m) where
mzipWith f (ListT a) (ListT b) = ListT $ mzipWith (zipWith f) a b
instance (MonadZip m) => MonadZip (MaybeT m) where
mzipWith f (MaybeT a) (MaybeT b) = MaybeT $ mzipWith (liftA2 f) a b
instance (MonadZip m) => MonadZip (ReaderT r m) where
mzipWith f (ReaderT m) (ReaderT n) = ReaderT $ \ a ->
mzipWith f (m a) (n a)
instance (Monoid w, MonadZip m) => MonadZip (Lazy.WriterT w m) where
mzipWith f (Lazy.WriterT x) (Lazy.WriterT y) = Lazy.WriterT $
mzipWith (\ ~(a, w) ~(b, w') -> (f a b, w `mappend` w')) x y
instance (Monoid w, MonadZip m) => MonadZip (Strict.WriterT w m) where
mzipWith f (Strict.WriterT x) (Strict.WriterT y) = Strict.WriterT $
mzipWith (\ (a, w) (b, w') -> (f a b, w `mappend` w')) x y
# if !(MIN_VERSION_base(4,8,0))
instance MonadZip Identity where
mzipWith f (Identity x) (Identity y) = Identity (f x y)
munzip (Identity (a, b)) = (Identity a, Identity b)
# endif
# if !(MIN_VERSION_base(4,9,0))
instance (MonadZip f, MonadZip g) => MonadZip (Product f g) where
mzipWith f (Pair x1 y1) (Pair x2 y2) = Pair (mzipWith f x1 x2) (mzipWith f y1 y2)
# endif
# endif
# if MIN_VERSION_base(4,8,0)
instance Bifunctor Constant where
first f (Constant x) = Constant (f x)
second _ (Constant x) = Constant x
# else
instance (Monoid a) => Monoid (Identity a) where
mempty = Identity mempty
mappend (Identity x) (Identity y) = Identity (mappend x y)
# endif
# ifndef HASKELL98
# if __GLASGOW_HASKELL__ >= 708 && __GLASGOW_HASKELL__ < 710
deriving instance Typeable Backwards
deriving instance Typeable Constant
deriving instance Typeable ContT
deriving instance Typeable ErrorT
deriving instance Typeable IdentityT
deriving instance Typeable Lift
deriving instance Typeable ListT
deriving instance Typeable MaybeT
deriving instance Typeable MonadTrans
deriving instance Typeable Lazy.RWST
deriving instance Typeable Strict.RWST
deriving instance Typeable ReaderT
deriving instance Typeable Reverse
deriving instance Typeable Lazy.StateT
deriving instance Typeable Strict.StateT
# if !(MIN_VERSION_base(4,9,0))
deriving instance Typeable Compose
deriving instance Typeable MonadIO
deriving instance Typeable Product
# endif
# endif
# if !(MIN_VERSION_base(4,8,0))
deriving instance Typeable1 Identity
deriving instance Data a => Data (Identity a)
# if __GLASGOW_HASKELL__ >= 708
deriving instance Typeable 'Identity
# endif
# endif
# if !(MIN_VERSION_base(4,9,0))
# if __GLASGOW_HASKELL__ >= 708
deriving instance (Data (f (g a)), Typeable f, Typeable g, Typeable a)
=> Data (Compose (f :: * -> *) (g :: * -> *) (a :: *))
deriving instance (Data (f a), Data (g a), Typeable f, Typeable g, Typeable a)
=> Data (Product (f :: * -> *) (g :: * -> *) (a :: *))
# if MIN_VERSION_transformers(0,4,0)
deriving instance Typeable Sum
deriving instance (Data (f a), Data (g a), Typeable f, Typeable g, Typeable a)
=> Data (Sum (f :: * -> *) (g :: * -> *) (a :: *))
# endif
# endif
# endif
# endif
#endif
#if !(MIN_VERSION_transformers(0,5,1))
# if !(MIN_VERSION_base(4,8,0))
instance (Bounded a) => Bounded (Identity a) where
minBound = Identity minBound
maxBound = Identity maxBound
instance (Enum a) => Enum (Identity a) where
succ (Identity x) = Identity (succ x)
pred (Identity x) = Identity (pred x)
toEnum i = Identity (toEnum i)
fromEnum (Identity x) = fromEnum x
enumFrom (Identity x) = map Identity (enumFrom x)
enumFromThen (Identity x) (Identity y) = map Identity (enumFromThen x y)
enumFromTo (Identity x) (Identity y) = map Identity (enumFromTo x y)
enumFromThenTo (Identity x) (Identity y) (Identity z) =
map Identity (enumFromThenTo x y z)
instance (Ix a) => Ix (Identity a) where
range (Identity x, Identity y) = map Identity (range (x, y))
index (Identity x, Identity y) (Identity i) = index (x, y) i
inRange (Identity x, Identity y) (Identity e) = inRange (x, y) e
rangeSize (Identity x, Identity y) = rangeSize (x, y)
instance (Storable a) => Storable (Identity a) where
sizeOf (Identity x) = sizeOf x
alignment (Identity x) = alignment x
peekElemOff p i = fmap Identity (peekElemOff (castPtr p) i)
pokeElemOff p i (Identity x) = pokeElemOff (castPtr p) i x
peekByteOff p i = fmap Identity (peekByteOff p i)
pokeByteOff p i (Identity x) = pokeByteOff p i x
peek p = fmap runIdentity (peek (castPtr p))
poke p (Identity x) = poke (castPtr p) x
# endif
#endif
#if !(MIN_VERSION_transformers(0,5,3))
# if !(MIN_VERSION_base(4,9,0))
# if MIN_VERSION_base(4,7,0)
# if defined(TRANSFORMERS_FOUR)
instance Eq1 Proxy where
eq1 _ _ = True
instance Ord1 Proxy where
compare1 _ _ = EQ
instance Show1 Proxy where
showsPrec1 _ _ = showString "Proxy"
instance Read1 Proxy where
readsPrec1 d =
readParen (d > 10) (\r -> [(Proxy, s) | ("Proxy",s) <- lex r ])
# elif MIN_VERSION_transformers(0,5,0)
instance Eq1 Proxy where
liftEq _ _ _ = True
instance Ord1 Proxy where
liftCompare _ _ _ = EQ
instance Show1 Proxy where
liftShowsPrec _ _ _ _ = showString "Proxy"
instance Read1 Proxy where
liftReadsPrec _ _ d =
readParen (d > 10) (\r -> [(Proxy, s) | ("Proxy",s) <- lex r ])
# endif
# endif
# endif
# if !(MIN_VERSION_base(4,8,0))
instance (Bits a) => Bits (Identity a) where
Identity x .&. Identity y = Identity (x .&. y)
Identity x .|. Identity y = Identity (x .|. y)
xor (Identity x) (Identity y) = Identity (xor x y)
complement (Identity x) = Identity (complement x)
shift (Identity x) i = Identity (shift x i)
rotate (Identity x) i = Identity (rotate x i)
setBit (Identity x) i = Identity (setBit x i)
clearBit (Identity x) i = Identity (clearBit x i)
shiftL (Identity x) i = Identity (shiftL x i)
shiftR (Identity x) i = Identity (shiftR x i)
rotateL (Identity x) i = Identity (rotateL x i)
rotateR (Identity x) i = Identity (rotateR x i)
testBit (Identity x) i = testBit x i
bitSize (Identity x) = bitSize x
isSigned (Identity x) = isSigned x
bit i = Identity (bit i)
# if MIN_VERSION_base(4,5,0)
unsafeShiftL (Identity x) i = Identity (unsafeShiftL x i)
unsafeShiftR (Identity x) i = Identity (unsafeShiftR x i)
popCount (Identity x) = popCount x
# endif
# if MIN_VERSION_base(4,7,0)
zeroBits = Identity zeroBits
bitSizeMaybe (Identity x) = bitSizeMaybe x
# endif
# if MIN_VERSION_base(4,7,0)
instance (FiniteBits a) => FiniteBits (Identity a) where
finiteBitSize (Identity x) = finiteBitSize x
# endif
instance (Floating a) => Floating (Identity a) where
pi = Identity pi
exp (Identity x) = Identity (exp x)
log (Identity x) = Identity (log x)
sqrt (Identity x) = Identity (sqrt x)
sin (Identity x) = Identity (sin x)
cos (Identity x) = Identity (cos x)
tan (Identity x) = Identity (tan x)
asin (Identity x) = Identity (asin x)
acos (Identity x) = Identity (acos x)
atan (Identity x) = Identity (atan x)
sinh (Identity x) = Identity (sinh x)
cosh (Identity x) = Identity (cosh x)
tanh (Identity x) = Identity (tanh x)
asinh (Identity x) = Identity (asinh x)
acosh (Identity x) = Identity (acosh x)
atanh (Identity x) = Identity (atanh x)
Identity x ** Identity y = Identity (x ** y)
logBase (Identity x) (Identity y) = Identity (logBase x y)
instance (Fractional a) => Fractional (Identity a) where
Identity x / Identity y = Identity (x / y)
recip (Identity x) = Identity (recip x)
fromRational r = Identity (fromRational r)
instance (IsString a) => IsString (Identity a) where
fromString s = Identity (fromString s)
instance (Integral a) => Integral (Identity a) where
quot (Identity x) (Identity y) = Identity (quot x y)
rem (Identity x) (Identity y) = Identity (rem x y)
div (Identity x) (Identity y) = Identity (div x y)
mod (Identity x) (Identity y) = Identity (mod x y)
quotRem (Identity x) (Identity y) = (Identity *** Identity) (quotRem x y)
divMod (Identity x) (Identity y) = (Identity *** Identity) (divMod x y)
toInteger (Identity x) = toInteger x
instance (Num a) => Num (Identity a) where
Identity x + Identity y = Identity (x + y)
Identity x - Identity y = Identity (x - y)
Identity x * Identity y = Identity (x * y)
negate (Identity x) = Identity (negate x)
abs (Identity x) = Identity (abs x)
signum (Identity x) = Identity (signum x)
fromInteger n = Identity (fromInteger n)
instance (Real a) => Real (Identity a) where
toRational (Identity x) = toRational x
instance (RealFloat a) => RealFloat (Identity a) where
floatRadix (Identity x) = floatRadix x
floatDigits (Identity x) = floatDigits x
floatRange (Identity x) = floatRange x
decodeFloat (Identity x) = decodeFloat x
exponent (Identity x) = exponent x
isNaN (Identity x) = isNaN x
isInfinite (Identity x) = isInfinite x
isDenormalized (Identity x) = isDenormalized x
isNegativeZero (Identity x) = isNegativeZero x
isIEEE (Identity x) = isIEEE x
significand (Identity x) = significand (Identity x)
scaleFloat s (Identity x) = Identity (scaleFloat s x)
encodeFloat m n = Identity (encodeFloat m n)
atan2 (Identity x) (Identity y) = Identity (atan2 x y)
instance (RealFrac a) => RealFrac (Identity a) where
properFraction (Identity x) = (id *** Identity) (properFraction x)
truncate (Identity x) = truncate x
round (Identity x) = round x
ceiling (Identity x) = ceiling x
floor (Identity x) = floor x
# endif
# if MIN_VERSION_transformers(0,3,0)
instance (Monad m) => Monad (Reverse m) where
return a = Reverse (return a)
{-# INLINE return #-}
m >>= f = Reverse (getReverse m >>= getReverse . f)
{-# INLINE (>>=) #-}
fail msg = Reverse (fail msg)
{-# INLINE fail #-}
# if MIN_VERSION_base(4,9,0)
instance (Fail.MonadFail m) => Fail.MonadFail (Reverse m) where
fail msg = Reverse (Fail.fail msg)
{-# INLINE fail #-}
# endif
instance (MonadPlus m) => MonadPlus (Reverse m) where
mzero = Reverse mzero
{-# INLINE mzero #-}
Reverse x `mplus` Reverse y = Reverse (x `mplus` y)
{-# INLINE mplus #-}
# endif
#endif
#if !(MIN_VERSION_transformers(0,5,4))
# if MIN_VERSION_base(4,10,0)
instance Bifoldable Constant where
bifoldMap f _ (Constant a) = f a
{-# INLINE bifoldMap #-}
instance Bitraversable Constant where
bitraverse f _ (Constant a) = Constant <$> f a
{-# INLINE bitraverse #-}
# endif
#endif
#if !(MIN_VERSION_transformers(0,5,5))
# if MIN_VERSION_base(4,9,0)
instance (Semigroup.Semigroup a) => Semigroup.Semigroup (Constant a b) where
Constant x <> Constant y = Constant (x Semigroup.<> y)
{-# INLINE (<>) #-}
# endif
#endif
#ifndef HASKELL98
# if (!(MIN_VERSION_transformers(0,5,0)) && (__GLASGOW_HASKELL__ >= 702 || defined(GENERIC_DERIVING))) \
|| (MIN_VERSION_transformers(0,5,0) && __GLASGOW_HASKELL__ < 702 && defined(GENERIC_DERIVING))
# if !(MIN_VERSION_base(4,8,0))
instance Generic (Identity a) where
type Rep (Identity a) = D1 MDIdentity (C1 MCIdentity (S1 MSIdentity (Rec0 a)))
from (Identity x) = M1 (M1 (M1 (K1 x)))
to (M1 (M1 (M1 (K1 x)))) = Identity x
instance Generic1 Identity where
type Rep1 Identity = D1 MDIdentity (C1 MCIdentity (S1 MSIdentity Par1))
from1 (Identity x) = M1 (M1 (M1 (Par1 x)))
to1 (M1 (M1 (M1 x))) = Identity (unPar1 x)
data MDIdentity
data MCIdentity
data MSIdentity
instance Datatype MDIdentity where
datatypeName _ = "Identity"
moduleName _ = "Data.Functor.Identity"
# if __GLASGOW_HASKELL__ >= 708
isNewtype _ = True
# endif
instance Constructor MCIdentity where
conName _ = "Identity"
conIsRecord _ = True
instance Selector MSIdentity where
selName _ = "runIdentity"
# endif
# if !(MIN_VERSION_base(4,9,0))
instance Generic (Compose f g a) where
type Rep (Compose f g a) =
D1 MDCompose
(C1 MCCompose
(S1 MSCompose (Rec0 (f (g a)))))
from (Compose x) = M1 (M1 (M1 (K1 x)))
to (M1 (M1 (M1 (K1 x)))) = Compose x
instance Functor f => Generic1 (Compose f g) where
type Rep1 (Compose f g) =
D1 MDCompose
(C1 MCCompose
(S1 MSCompose (f :.: Rec1 g)))
from1 (Compose x) = M1 (M1 (M1 (Comp1 (fmap Rec1 x))))
to1 (M1 (M1 (M1 x))) = Compose (fmap unRec1 (unComp1 x))
data MDCompose
data MCCompose
data MSCompose
instance Datatype MDCompose where
datatypeName _ = "Compose"
moduleName _ = "Data.Functor.Compose"
# if __GLASGOW_HASKELL__ >= 708
isNewtype _ = True
# endif
instance Constructor MCCompose where
conName _ = "Compose"
conIsRecord _ = True
instance Selector MSCompose where
selName _ = "getCompose"
instance Generic (Product f g a) where
type Rep (Product f g a) =
D1 MDProduct
(C1 MCPair
(S1 NoSelector (Rec0 (f a)) :*: S1 NoSelector (Rec0 (g a))))
from (Pair f g) = M1 (M1 (M1 (K1 f) :*: M1 (K1 g)))
to (M1 (M1 (M1 (K1 f) :*: M1 (K1 g)))) = Pair f g
instance Generic1 (Product f g) where
type Rep1 (Product f g) =
D1 MDProduct
(C1 MCPair
(S1 NoSelector (Rec1 f) :*: S1 NoSelector (Rec1 g)))
from1 (Pair f g) = M1 (M1 (M1 (Rec1 f) :*: M1 (Rec1 g)))
to1 (M1 (M1 (M1 f :*: M1 g))) = Pair (unRec1 f) (unRec1 g)
data MDProduct
data MCPair
instance Datatype MDProduct where
datatypeName _ = "Product"
moduleName _ = "Data.Functor.Product"
instance Constructor MCPair where
conName _ = "Pair"
# if MIN_VERSION_transformers(0,4,0)
instance Generic (Sum f g a) where
type Rep (Sum f g a) =
D1 MDSum (C1 MCInL (S1 NoSelector (Rec0 (f a)))
:+: C1 MCInR (S1 NoSelector (Rec0 (g a))))
from (InL f) = M1 (L1 (M1 (M1 (K1 f))))
from (InR g) = M1 (R1 (M1 (M1 (K1 g))))
to (M1 (L1 (M1 (M1 (K1 f))))) = InL f
to (M1 (R1 (M1 (M1 (K1 g))))) = InR g
instance Generic1 (Sum f g) where
type Rep1 (Sum f g) =
D1 MDSum (C1 MCInL (S1 NoSelector (Rec1 f))
:+: C1 MCInR (S1 NoSelector (Rec1 g)))
from1 (InL f) = M1 (L1 (M1 (M1 (Rec1 f))))
from1 (InR g) = M1 (R1 (M1 (M1 (Rec1 g))))
to1 (M1 (L1 (M1 (M1 f)))) = InL (unRec1 f)
to1 (M1 (R1 (M1 (M1 g)))) = InR (unRec1 g)
data MDSum
data MCInL
data MCInR
instance Datatype MDSum where
datatypeName _ = "Sum"
moduleName _ = "Data.Functor.Sum"
instance Constructor MCInL where
conName _ = "InL"
instance Constructor MCInR where
conName _ = "InR"
# endif
# endif
# endif
#endif