{-# LANGUAGE CPP #-}
{-# LANGUAGE GADTs #-}
{-# LANGUAGE NamedFieldPuns #-}
{-|
Module:      Text.Show.Deriving.Internal
Copyright:   (C) 2015-2017 Ryan Scott
License:     BSD-style (see the file LICENSE)
Maintainer:  Ryan Scott
Portability: Template Haskell

Exports functions to mechanically derive 'Show', 'Show1', and 'Show2' instances.

Note: this is an internal module, and as such, the API presented here is not
guaranteed to be stable, even between minor releases of this library.
-}
module Text.Show.Deriving.Internal (
      -- * 'Show'
      deriveShow
    , deriveShowOptions
    , makeShowsPrec
    , makeShowsPrecOptions
    , makeShow
    , makeShowOptions
    , makeShowList
    , makeShowListOptions
      -- * 'Show1'
    , deriveShow1
    , deriveShow1Options
#if defined(NEW_FUNCTOR_CLASSES)
    , makeLiftShowsPrec
    , makeLiftShowsPrecOptions
    , makeLiftShowList
    , makeLiftShowListOptions
#endif
    , makeShowsPrec1
    , makeShowsPrec1Options
#if defined(NEW_FUNCTOR_CLASSES)
      -- * 'Show2'
    , deriveShow2
    , deriveShow2Options
    , makeLiftShowsPrec2
    , makeLiftShowsPrec2Options
    , makeLiftShowList2
    , makeLiftShowList2Options
    , makeShowsPrec2
    , makeShowsPrec2Options
#endif
      -- * 'ShowOptions'
    , ShowOptions(..)
    , defaultShowOptions
    , legacyShowOptions
    ) where

import           Data.Deriving.Internal
import           Data.List
import qualified Data.Map as Map
import           Data.Map (Map)
import           Data.Maybe (fromMaybe)

import           GHC.Show (appPrec, appPrec1)

import           Language.Haskell.TH.Datatype
import           Language.Haskell.TH.Lib
import           Language.Haskell.TH.Syntax

-- | Options that further configure how the functions in "Text.Show.Deriving"
-- should behave.
data ShowOptions = ShowOptions
  { ghc8ShowBehavior :: Bool
    -- ^ If 'True', the derived 'Show', 'Show1', or 'Show2' instance will not
    --   surround the output of showing fields of unlifted types with parentheses,
    --   and the output will be suffixed with hash signs (@#@).
  , showEmptyCaseBehavior :: Bool
    -- ^ If 'True', derived instances for empty data types (i.e., ones with
    --   no data constructors) will use the @EmptyCase@ language extension.
    --   If 'False', derived instances will simply use 'seq' instead.
    --   (This has no effect on GHCs before 7.8, since @EmptyCase@ is only
    --   available in 7.8 or later.)
  } deriving (Eq, Ord, Read, Show)

-- | 'ShowOptions' that match the behavior of the most recent GHC release.
defaultShowOptions :: ShowOptions
defaultShowOptions =
  ShowOptions { ghc8ShowBehavior      = True
              , showEmptyCaseBehavior = False
              }

-- | 'ShowOptions' that match the behavior of the installed version of GHC.
legacyShowOptions :: ShowOptions
legacyShowOptions = ShowOptions
  { ghc8ShowBehavior =
#if __GLASGOW_HASKELL__ >= 711
                       True
#else
                       False
#endif
  , showEmptyCaseBehavior = False
  }

-- | Generates a 'Show' instance declaration for the given data type or data
-- family instance.
deriveShow :: Name -> Q [Dec]
deriveShow = deriveShowOptions defaultShowOptions

-- | Like 'deriveShow', but takes a 'ShowOptions' argument.
deriveShowOptions :: ShowOptions -> Name -> Q [Dec]
deriveShowOptions = deriveShowClass Show

-- | Generates a lambda expression which behaves like 'show' (without
-- requiring a 'Show' instance).
makeShow :: Name -> Q Exp
makeShow = makeShowOptions defaultShowOptions

-- | Like 'makeShow', but takes a 'ShowOptions' argument.
makeShowOptions :: ShowOptions -> Name -> Q Exp
makeShowOptions opts name = do
    x <- newName "x"
    lam1E (varP x) $ makeShowsPrecOptions opts name
                     `appE` integerE 0
                     `appE` varE x
                     `appE` stringE ""

-- | Generates a lambda expression which behaves like 'showsPrec' (without
-- requiring a 'Show' instance).
makeShowsPrec :: Name -> Q Exp
makeShowsPrec = makeShowsPrecOptions defaultShowOptions

-- | Like 'makeShowsPrec', but takes a 'ShowOptions' argument.
makeShowsPrecOptions :: ShowOptions -> Name -> Q Exp
makeShowsPrecOptions = makeShowsPrecClass Show

-- | Generates a lambda expression which behaves like 'showList' (without
-- requiring a 'Show' instance).
makeShowList :: Name -> Q Exp
makeShowList = makeShowListOptions defaultShowOptions

-- | Like 'makeShowList', but takes a 'ShowOptions' argument.
makeShowListOptions :: ShowOptions -> Name -> Q Exp
makeShowListOptions opts name =
    varE showListWithValName `appE` (makeShowsPrecOptions opts name `appE` integerE 0)

-- | Generates a 'Show1' instance declaration for the given data type or data
-- family instance.
deriveShow1 :: Name -> Q [Dec]
deriveShow1 = deriveShow1Options defaultShowOptions

-- | Like 'deriveShow1', but takes a 'ShowOptions' argument.
deriveShow1Options :: ShowOptions -> Name -> Q [Dec]
deriveShow1Options = deriveShowClass Show1

-- | Generates a lambda expression which behaves like 'showsPrec1' (without
-- requiring a 'Show1' instance).
makeShowsPrec1 :: Name -> Q Exp
makeShowsPrec1 = makeShowsPrec1Options defaultShowOptions

#if defined(NEW_FUNCTOR_CLASSES)
-- | Generates a lambda expression which behaves like 'liftShowsPrec' (without
-- requiring a 'Show1' instance).
--
-- This function is not available with @transformers-0.4@.
makeLiftShowsPrec :: Name -> Q Exp
makeLiftShowsPrec = makeLiftShowsPrecOptions defaultShowOptions

-- | Like 'makeLiftShowsPrec', but takes a 'ShowOptions' argument.
--
-- This function is not available with @transformers-0.4@.
makeLiftShowsPrecOptions :: ShowOptions -> Name -> Q Exp
makeLiftShowsPrecOptions = makeShowsPrecClass Show1

-- | Generates a lambda expression which behaves like 'liftShowList' (without
-- requiring a 'Show' instance).
--
-- This function is not available with @transformers-0.4@.
makeLiftShowList :: Name -> Q Exp
makeLiftShowList = makeLiftShowListOptions defaultShowOptions

-- | Like 'makeLiftShowList', but takes a 'ShowOptions' argument.
--
-- This function is not available with @transformers-0.4@.
makeLiftShowListOptions :: ShowOptions -> Name -> Q Exp
makeLiftShowListOptions opts name = do
    sp' <- newName "sp'"
    sl' <- newName "sl'"
    lamE [varP sp', varP sl'] $ varE showListWithValName `appE`
        (makeLiftShowsPrecOptions opts name `appE` varE sp' `appE` varE sl'
                                            `appE` integerE 0)

-- | Like 'makeShowsPrec1', but takes a 'ShowOptions' argument.
makeShowsPrec1Options :: ShowOptions -> Name -> Q Exp
makeShowsPrec1Options opts name = makeLiftShowsPrecOptions opts name
                           `appE` varE showsPrecValName
                           `appE` varE showListValName
#else
-- | Like 'makeShowsPrec1', but takes a 'ShowOptions' argument.
makeShowsPrec1Options :: ShowOptions -> Name -> Q Exp
makeShowsPrec1Options = makeShowsPrecClass Show1
#endif

#if defined(NEW_FUNCTOR_CLASSES)
-- | Generates a 'Show2' instance declaration for the given data type or data
-- family instance.
--
-- This function is not available with @transformers-0.4@.
deriveShow2 :: Name -> Q [Dec]
deriveShow2 = deriveShow2Options defaultShowOptions

-- | Like 'deriveShow2', but takes a 'ShowOptions' argument.
--
-- This function is not available with @transformers-0.4@.
deriveShow2Options :: ShowOptions -> Name -> Q [Dec]
deriveShow2Options = deriveShowClass Show2

-- | Generates a lambda expression which behaves like 'liftShowsPrec2' (without
-- requiring a 'Show2' instance).
--
-- This function is not available with @transformers-0.4@.
makeLiftShowsPrec2 :: Name -> Q Exp
makeLiftShowsPrec2 = makeLiftShowsPrec2Options defaultShowOptions

-- | Like 'makeLiftShowsPrec2', but takes a 'ShowOptions' argument.
--
-- This function is not available with @transformers-0.4@.
makeLiftShowsPrec2Options :: ShowOptions -> Name -> Q Exp
makeLiftShowsPrec2Options = makeShowsPrecClass Show2

-- | Generates a lambda expression which behaves like 'liftShowList2' (without
-- requiring a 'Show' instance).
--
-- This function is not available with @transformers-0.4@.
makeLiftShowList2 :: Name -> Q Exp
makeLiftShowList2 = makeLiftShowList2Options defaultShowOptions

-- | Like 'makeLiftShowList2', but takes a 'ShowOptions' argument.
--
-- This function is not available with @transformers-0.4@.
makeLiftShowList2Options :: ShowOptions -> Name -> Q Exp
makeLiftShowList2Options opts name = do
    sp1' <- newName "sp1'"
    sl1' <- newName "sl1'"
    sp2' <- newName "sp2'"
    sl2' <- newName "sl2'"
    lamE [varP sp1', varP sl1', varP sp2', varP sl2'] $
        varE showListWithValName `appE`
            (makeLiftShowsPrec2Options opts name `appE` varE sp1' `appE` varE sl1'
                                                 `appE` varE sp2' `appE` varE sl2'
                                                 `appE` integerE 0)

-- | Generates a lambda expression which behaves like 'showsPrec2' (without
-- requiring a 'Show2' instance).
--
-- This function is not available with @transformers-0.4@.
makeShowsPrec2 :: Name -> Q Exp
makeShowsPrec2 = makeShowsPrec2Options defaultShowOptions

-- | Like 'makeShowsPrec2', but takes a 'ShowOptions' argument.
--
-- This function is not available with @transformers-0.4@.
makeShowsPrec2Options :: ShowOptions -> Name -> Q Exp
makeShowsPrec2Options opts name = makeLiftShowsPrec2Options opts name
                           `appE` varE showsPrecValName
                           `appE` varE showListValName
                           `appE` varE showsPrecValName
                           `appE` varE showListValName
#endif

-------------------------------------------------------------------------------
-- Code generation
-------------------------------------------------------------------------------

-- | Derive a Show(1)(2) instance declaration (depending on the ShowClass
-- argument's value).
deriveShowClass :: ShowClass -> ShowOptions -> Name -> Q [Dec]
deriveShowClass sClass opts name = do
  info <- reifyDatatype name
  case info of
    DatatypeInfo { datatypeContext   = ctxt
                 , datatypeName      = parentName
                 , datatypeInstTypes = instTypes
                 , datatypeVariant   = variant
                 , datatypeCons      = cons
                 } -> do
      (instanceCxt, instanceType)
          <- buildTypeInstance sClass parentName ctxt instTypes variant
      (:[]) `fmap` instanceD (return instanceCxt)
                             (return instanceType)
                             (showsPrecDecs sClass opts instTypes cons)

-- | Generates a declaration defining the primary function corresponding to a
-- particular class (showsPrec for Show, liftShowsPrec for Show1, and
-- liftShowsPrec2 for Show2).
showsPrecDecs :: ShowClass -> ShowOptions -> [Type] -> [ConstructorInfo] -> [Q Dec]
showsPrecDecs sClass opts instTypes cons =
    [ funD (showsPrecName sClass)
           [ clause []
                    (normalB $ makeShowForCons sClass opts instTypes cons)
                    []
           ]
    ]

-- | Generates a lambda expression which behaves like showsPrec (for Show),
-- liftShowsPrec (for Show1), or liftShowsPrec2 (for Show2).
makeShowsPrecClass :: ShowClass -> ShowOptions -> Name -> Q Exp
makeShowsPrecClass sClass opts name = do
  info <- reifyDatatype name
  case info of
    DatatypeInfo { datatypeContext   = ctxt
                 , datatypeName      = parentName
                 , datatypeInstTypes = instTypes
                 , datatypeVariant   = variant
                 , datatypeCons      = cons
                 } -> do
      -- We force buildTypeInstance here since it performs some checks for whether
      -- or not the provided datatype can actually have showsPrec/liftShowsPrec/etc.
      -- implemented for it, and produces errors if it can't.
      buildTypeInstance sClass parentName ctxt instTypes variant
        >> makeShowForCons sClass opts instTypes cons

-- | Generates a lambda expression for showsPrec/liftShowsPrec/etc. for the
-- given constructors. All constructors must be from the same type.
makeShowForCons :: ShowClass -> ShowOptions -> [Type] -> [ConstructorInfo] -> Q Exp
makeShowForCons sClass opts instTypes cons = do
    p     <- newName "p"
    value <- newName "value"
    sps   <- newNameList "sp" $ arity sClass
    sls   <- newNameList "sl" $ arity sClass
    let spls       = zip sps sls
        _spsAndSls = interleave sps sls
        lastTyVars = map varTToName $ drop (length instTypes - fromEnum sClass) instTypes
        splMap     = Map.fromList $ zipWith (\x (y, z) -> (x, TwoNames y z)) lastTyVars spls

        makeFun
          | null cons && showEmptyCaseBehavior opts && ghc7'8OrLater
          = caseE (varE value) []

          | null cons
          = appE (varE seqValName) (varE value) `appE`
            appE (varE errorValName)
                 (stringE $ "Void " ++ nameBase (showsPrecName sClass))

          | otherwise
          = caseE (varE value)
                  (map (makeShowForCon p sClass opts splMap) cons)

    lamE (map varP $
#if defined(NEW_FUNCTOR_CLASSES)
                     _spsAndSls ++
#endif
                     [p, value])
        . appsE
        $ [ varE $ showsPrecConstName sClass
          , makeFun
          ]
#if defined(NEW_FUNCTOR_CLASSES)
            ++ map varE _spsAndSls
#endif
            ++ [varE p, varE value]

-- | Generates a lambda expression for showsPrec/liftShowsPrec/etc. for a
-- single constructor.
makeShowForCon :: Name
               -> ShowClass
               -> ShowOptions
               -> TyVarMap2
               -> ConstructorInfo
               -> Q Match
makeShowForCon _ _ _ _
  (ConstructorInfo { constructorName = conName, constructorFields = [] }) =
    match
      (conP conName [])
      (normalB $ varE showStringValName `appE` stringE (parenInfixConName conName ""))
      []
makeShowForCon p sClass opts tvMap
  (ConstructorInfo { constructorName    = conName
                   , constructorVariant = NormalConstructor
                   , constructorFields  = [argTy] }) = do
    argTy' <- resolveTypeSynonyms argTy
    arg <- newName "arg"

    let showArg  = makeShowForArg appPrec1 sClass opts conName tvMap argTy' arg
        namedArg = infixApp (varE showStringValName `appE` stringE (parenInfixConName conName " "))
                            (varE composeValName)
                            showArg

    match
      (conP conName [varP arg])
      (normalB $ varE showParenValName
                  `appE` infixApp (varE p) (varE gtValName) (integerE appPrec)
                  `appE` namedArg)
      []
makeShowForCon p sClass opts tvMap
  (ConstructorInfo { constructorName    = conName
                   , constructorVariant = NormalConstructor
                   , constructorFields  = argTys }) = do
    argTys' <- mapM resolveTypeSynonyms argTys
    args <- newNameList "arg" $ length argTys'

    if isNonUnitTuple conName
       then do
         let showArgs       = zipWith (makeShowForArg 0 sClass opts conName tvMap) argTys' args
             parenCommaArgs = (varE showCharValName `appE` charE '(')
                              : intersperse (varE showCharValName `appE` charE ',') showArgs
             mappendArgs    = foldr (`infixApp` varE composeValName)
                                    (varE showCharValName `appE` charE ')')
                                    parenCommaArgs

         match (conP conName $ map varP args)
               (normalB mappendArgs)
               []
       else do
         let showArgs    = zipWith (makeShowForArg appPrec1 sClass opts conName tvMap) argTys' args
             mappendArgs = foldr1 (\v q -> infixApp v (varE composeValName)
                                                    (infixApp (varE showSpaceValName)
                                                            (varE composeValName)
                                                            q)) showArgs
             namedArgs   = infixApp (varE showStringValName `appE` stringE (parenInfixConName conName " "))
                                    (varE composeValName)
                                    mappendArgs

         match (conP conName $ map varP args)
               (normalB $ varE showParenValName
                            `appE` infixApp (varE p) (varE gtValName) (integerE appPrec)
                            `appE` namedArgs)
               []
makeShowForCon p sClass opts tvMap
  (ConstructorInfo { constructorName    = conName
                   , constructorVariant = RecordConstructor argNames
                   , constructorFields  = argTys }) = do
    argTys' <- mapM resolveTypeSynonyms argTys
    args <- newNameList "arg" $ length argTys'

    let showArgs       = concatMap (\(argName, argTy, arg)
                                      -> let argNameBase = nameBase argName
                                             infixRec    = showParen (isSym argNameBase)
                                                                     (showString argNameBase) ""
                                         in [ varE showStringValName `appE` stringE (infixRec ++ " = ")
                                            , makeShowForArg 0 sClass opts conName tvMap argTy arg
                                            , varE showCommaSpaceValName
                                            ]
                                   )
                                   (zip3 argNames argTys' args)
        braceCommaArgs = (varE showCharValName `appE` charE '{') : take (length showArgs - 1) showArgs
        mappendArgs    = foldr (`infixApp` varE composeValName)
                               (varE showCharValName `appE` charE '}')
                               braceCommaArgs
        namedArgs      = infixApp (varE showStringValName `appE` stringE (parenInfixConName conName " "))
                                  (varE composeValName)
                                  mappendArgs

    match
      (conP conName $ map varP args)
      (normalB $ varE showParenValName
                   `appE` infixApp (varE p) (varE gtValName) (integerE appPrec)
                   `appE` namedArgs)
      []
makeShowForCon p sClass opts tvMap
  (ConstructorInfo { constructorName    = conName
                   , constructorVariant = InfixConstructor
                   , constructorFields  = argTys }) = do
    [alTy, arTy] <- mapM resolveTypeSynonyms argTys
    al   <- newName "argL"
    ar   <- newName "argR"
    fi <- fromMaybe defaultFixity `fmap` reifyFixityCompat conName
    let conPrec  = case fi of Fixity prec _ -> prec
        opName   = nameBase conName
        infixOpE = appE (varE showStringValName) . stringE $
                     if isInfixDataCon opName
                        then " "  ++ opName ++ " "
                        else " `" ++ opName ++ "` "

    match
      (infixP (varP al) conName (varP ar))
      (normalB $ (varE showParenValName `appE` infixApp (varE p) (varE gtValName) (integerE conPrec))
                   `appE` (infixApp (makeShowForArg (conPrec + 1) sClass opts conName tvMap alTy al)
                                    (varE composeValName)
                                    (infixApp infixOpE
                                              (varE composeValName)
                                              (makeShowForArg (conPrec + 1) sClass opts conName tvMap arTy ar)))
      )
      []

-- | Generates a lambda expression for showsPrec/liftShowsPrec/etc. for an
-- argument of a constructor.
makeShowForArg :: Int
               -> ShowClass
               -> ShowOptions
               -> Name
               -> TyVarMap2
               -> Type
               -> Name
               -> Q Exp
makeShowForArg p _ opts _ _ (ConT tyName) tyExpName =
    showE
  where
    tyVarE :: Q Exp
    tyVarE = varE tyExpName

    showE :: Q Exp
    showE =
      case Map.lookup tyName primShowTbl of
        Just ps -> showPrimE ps
        Nothing -> varE showsPrecValName `appE` integerE p `appE` tyVarE

    showPrimE :: PrimShow -> Q Exp
    showPrimE PrimShow{primShowBoxer, primShowPostfixMod, primShowConv}
        -- Starting with GHC 8.0, data types containing unlifted types with
        -- derived Show instances show hashed literals with actual hash signs,
        -- and negative hashed literals are not surrounded with parentheses.
      | ghc8ShowBehavior opts
      = primShowConv $ infixApp (primE 0) (varE composeValName) primShowPostfixMod
      | otherwise
      = primE p
      where
        primE :: Int -> Q Exp
        primE prec = varE showsPrecValName `appE` integerE prec
                                           `appE` primShowBoxer tyVarE
makeShowForArg p sClass _ conName tvMap ty tyExpName =
    makeShowForType sClass conName tvMap False ty `appE` integerE p `appE` varE tyExpName

-- | Generates a lambda expression for showsPrec/liftShowsPrec/etc. for a
-- specific type. The generated expression depends on the number of type variables.
--
-- 1. If the type is of kind * (T), apply showsPrec.
-- 2. If the type is of kind * -> * (T a), apply liftShowsPrec $(makeShowForType a)
-- 3. If the type is of kind * -> * -> * (T a b), apply
--    liftShowsPrec2 $(makeShowForType a) $(makeShowForType b)
makeShowForType :: ShowClass
                -> Name
                -> TyVarMap2
                -> Bool -- ^ True if we are using the function of type ([a] -> ShowS),
                        --   False if we are using the function of type (Int -> a -> ShowS).
                -> Type
                -> Q Exp
#if defined(NEW_FUNCTOR_CLASSES)
makeShowForType _ _ tvMap sl (VarT tyName) =
    varE $ case Map.lookup tyName tvMap of
      Just (TwoNames spExp slExp) -> if sl then slExp else spExp
      Nothing -> if sl then showListValName else showsPrecValName
#else
makeShowForType _ _ _ _ VarT{} = varE showsPrecValName
#endif
makeShowForType sClass conName tvMap sl (SigT ty _)      = makeShowForType sClass conName tvMap sl ty
makeShowForType sClass conName tvMap sl (ForallT _ _ ty) = makeShowForType sClass conName tvMap sl ty
#if defined(NEW_FUNCTOR_CLASSES)
makeShowForType sClass conName tvMap sl ty = do
    let tyCon :: Type
        tyArgs :: [Type]
        (tyCon, tyArgs) = unapplyTy ty

        numLastArgs :: Int
        numLastArgs = min (arity sClass) (length tyArgs)

        lhsArgs, rhsArgs :: [Type]
        (lhsArgs, rhsArgs) = splitAt (length tyArgs - numLastArgs) tyArgs

        tyVarNames :: [Name]
        tyVarNames = Map.keys tvMap

    itf <- isInTypeFamilyApp tyVarNames tyCon tyArgs
    if any (`mentionsName` tyVarNames) lhsArgs
          || itf && any (`mentionsName` tyVarNames) tyArgs
       then outOfPlaceTyVarError sClass conName
       else if any (`mentionsName` tyVarNames) rhsArgs
               then appsE $ [ varE . showsPrecOrListName sl $ toEnum numLastArgs]
                            ++ zipWith (makeShowForType sClass conName tvMap)
                                       (cycle [False,True])
                                       (interleave rhsArgs rhsArgs)
               else varE $ if sl then showListValName else showsPrecValName
#else
makeShowForType sClass conName tvMap _ ty = do
  let varNames = Map.keys tvMap

  p'     <- newName "p'"
  value' <- newName "value'"
  case varNames of
    [] -> varE showsPrecValName
    varName:_ ->
      if mentionsName ty varNames
         then lamE [varP p', varP value'] $ varE showsPrec1ValName
                `appE` varE p'
                `appE` (makeFmapApplyNeg sClass conName ty varName `appE` varE value')
         else varE showsPrecValName
#endif

-------------------------------------------------------------------------------
-- Class-specific constants
-------------------------------------------------------------------------------

-- | A representation of which @Show@ variant is being derived.
data ShowClass = Show
               | Show1
#if defined(NEW_FUNCTOR_CLASSES)
               | Show2
#endif
  deriving (Bounded, Enum)

instance ClassRep ShowClass where
    arity = fromEnum

    allowExQuant _ = True

    fullClassName Show  = showTypeName
    fullClassName Show1 = show1TypeName
#if defined(NEW_FUNCTOR_CLASSES)
    fullClassName Show2 = show2TypeName
#endif

    classConstraint sClass i
      | sMin <= i && i <= sMax = Just $ fullClassName (toEnum i :: ShowClass)
      | otherwise              = Nothing
      where
        sMin, sMax :: Int
        sMin = fromEnum (minBound :: ShowClass)
        sMax = fromEnum sClass

showsPrecConstName :: ShowClass -> Name
showsPrecConstName Show  = showsPrecConstValName
#if defined(NEW_FUNCTOR_CLASSES)
showsPrecConstName Show1 = liftShowsPrecConstValName
showsPrecConstName Show2 = liftShowsPrec2ConstValName
#else
showsPrecConstName Show1 = showsPrec1ConstValName
#endif

showsPrecName :: ShowClass -> Name
showsPrecName Show  = showsPrecValName
#if defined(NEW_FUNCTOR_CLASSES)
showsPrecName Show1 = liftShowsPrecValName
showsPrecName Show2 = liftShowsPrec2ValName
#else
showsPrecName Show1 = showsPrec1ValName
#endif

#if defined(NEW_FUNCTOR_CLASSES)
showListName :: ShowClass -> Name
showListName Show  = showListValName
showListName Show1 = liftShowListValName
showListName Show2 = liftShowList2ValName

showsPrecOrListName :: Bool -- ^ showListName if True, showsPrecName if False
                    -> ShowClass
                    -> Name
showsPrecOrListName False = showsPrecName
showsPrecOrListName True  = showListName
#endif

-------------------------------------------------------------------------------
-- Assorted utilities
-------------------------------------------------------------------------------

-- | Parenthesize an infix constructor name if it is being applied as a prefix
-- function (e.g., data Amp a = (:&) a a)
parenInfixConName :: Name -> ShowS
parenInfixConName conName =
    let conNameBase = nameBase conName
     in showParen (isInfixDataCon conNameBase) $ showString conNameBase

charE :: Char -> Q Exp
charE = litE . charL

data PrimShow = PrimShow
  { primShowBoxer      :: Q Exp -> Q Exp
  , primShowPostfixMod :: Q Exp
  , primShowConv       :: Q Exp -> Q Exp
  }

primShowTbl :: Map Name PrimShow
primShowTbl = Map.fromList
    [ (charHashTypeName,   PrimShow
                             { primShowBoxer      = appE (conE cHashDataName)
                             , primShowPostfixMod = oneHashE
                             , primShowConv       = id
                             })
    , (doubleHashTypeName, PrimShow
                             { primShowBoxer      = appE (conE dHashDataName)
                             , primShowPostfixMod = twoHashE
                             , primShowConv       = id
                             })
    , (floatHashTypeName,  PrimShow
                             { primShowBoxer      = appE (conE fHashDataName)
                             , primShowPostfixMod = oneHashE
                             , primShowConv       = id
                             })
    , (intHashTypeName,    PrimShow
                             { primShowBoxer      = appE (conE iHashDataName)
                             , primShowPostfixMod = oneHashE
                             , primShowConv       = id
                             })
    , (wordHashTypeName,   PrimShow
                             { primShowBoxer      = appE (conE wHashDataName)
                             , primShowPostfixMod = twoHashE
                             , primShowConv       = id
                             })
#if MIN_VERSION_base(4,13,0)
    , (int8HashTypeName,   PrimShow
                             { primShowBoxer      = appE (conE iHashDataName) . appE (varE extendInt8HashValName)
                             , primShowPostfixMod = oneHashE
                             , primShowConv       = mkNarrowE "narrowInt8#"
                             })
    , (int16HashTypeName,  PrimShow
                             { primShowBoxer      = appE (conE iHashDataName) . appE (varE extendInt16HashValName)
                             , primShowPostfixMod = oneHashE
                             , primShowConv       = mkNarrowE "narrowInt16#"
                             })
    , (word8HashTypeName,  PrimShow
                             { primShowBoxer      = appE (conE wHashDataName) . appE (varE extendWord8HashValName)
                             , primShowPostfixMod = twoHashE
                             , primShowConv       = mkNarrowE "narrowWord8#"
                             })
    , (word16HashTypeName, PrimShow
                             { primShowBoxer      = appE (conE wHashDataName) . appE (varE extendWord16HashValName)
                             , primShowPostfixMod = twoHashE
                             , primShowConv       = mkNarrowE "narrowWord16#"
                             })
#endif
    ]

#if MIN_VERSION_base(4,13,0)
mkNarrowE :: String -> Q Exp -> Q Exp
mkNarrowE narrowStr e =
  foldr (`infixApp` varE composeValName)
        (varE showCharValName `appE` charE ')')
        [ varE showStringValName `appE` stringE ('(':narrowStr ++ " ")
        , e
        ]
#endif

oneHashE, twoHashE :: Q Exp
oneHashE = varE showCharValName `appE` charE '#'
twoHashE = varE showStringValName `appE` stringE "##"