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|
{-# LANGUAGE Safe #-}
-- | contains a prettyprinter for the
-- Template Haskell datatypes
module Language.Haskell.TH.Ppr where
-- All of the exports from this module should
-- be "public" functions. The main module TH
-- re-exports them all.
import Text.PrettyPrint (render)
import Language.Haskell.TH.PprLib
import Language.Haskell.TH.Syntax
import Data.Word ( Word8 )
import Data.Char ( toLower, chr)
import GHC.Show ( showMultiLineString )
import GHC.Lexeme( startsVarSym )
import Data.Ratio ( numerator, denominator )
import Prelude hiding ((<>))
nestDepth :: Int
nestDepth = 4
type Precedence = Int
appPrec, opPrec, unopPrec, sigPrec, noPrec :: Precedence
appPrec = 4 -- Argument of a function application
opPrec = 3 -- Argument of an infix operator
unopPrec = 2 -- Argument of an unresolved infix operator
sigPrec = 1 -- Argument of an explicit type signature
noPrec = 0 -- Others
parensIf :: Bool -> Doc -> Doc
parensIf True d = parens d
parensIf False d = d
------------------------------
pprint :: Ppr a => a -> String
pprint x = render $ to_HPJ_Doc $ ppr x
class Ppr a where
ppr :: a -> Doc
ppr_list :: [a] -> Doc
ppr_list = vcat . map ppr
instance Ppr a => Ppr [a] where
ppr x = ppr_list x
------------------------------
instance Ppr Name where
ppr v = pprName v
------------------------------
instance Ppr Info where
ppr (TyConI d) = ppr d
ppr (ClassI d is) = ppr d $$ vcat (map ppr is)
ppr (FamilyI d is) = ppr d $$ vcat (map ppr is)
ppr (PrimTyConI name arity is_unlifted)
= text "Primitive"
<+> (if is_unlifted then text "unlifted" else empty)
<+> text "type constructor" <+> quotes (ppr name)
<+> parens (text "arity" <+> int arity)
ppr (ClassOpI v ty cls)
= text "Class op from" <+> ppr cls <> colon <+> ppr_sig v ty
ppr (DataConI v ty tc)
= text "Constructor from" <+> ppr tc <> colon <+> ppr_sig v ty
ppr (PatSynI nm ty) = pprPatSynSig nm ty
ppr (TyVarI v ty)
= text "Type variable" <+> ppr v <+> equals <+> ppr ty
ppr (VarI v ty mb_d)
= vcat [ppr_sig v ty,
case mb_d of { Nothing -> empty; Just d -> ppr d }]
ppr_sig :: Name -> Type -> Doc
ppr_sig v ty = pprName' Applied v <+> dcolon <+> ppr ty
pprFixity :: Name -> Fixity -> Doc
pprFixity _ f | f == defaultFixity = empty
pprFixity v (Fixity i d) = ppr_fix d <+> int i <+> pprName' Infix v
where ppr_fix InfixR = text "infixr"
ppr_fix InfixL = text "infixl"
ppr_fix InfixN = text "infix"
-- | Pretty prints a pattern synonym type signature
pprPatSynSig :: Name -> PatSynType -> Doc
pprPatSynSig nm ty
= text "pattern" <+> pprPrefixOcc nm <+> dcolon <+> pprPatSynType ty
-- | Pretty prints a pattern synonym's type; follows the usual
-- conventions to print a pattern synonym type compactly, yet
-- unambiguously. See the note on 'PatSynType' and the section on
-- pattern synonyms in the GHC user's guide for more information.
pprPatSynType :: PatSynType -> Doc
pprPatSynType ty@(ForallT uniTys reqs ty'@(ForallT exTys provs ty''))
| null exTys, null provs = ppr (ForallT uniTys reqs ty'')
| null uniTys, null reqs = noreqs <+> ppr ty'
| null reqs = forall uniTys <+> noreqs <+> ppr ty'
| otherwise = ppr ty
where noreqs = text "() =>"
forall tvs = text "forall" <+> (hsep (map ppr tvs)) <+> text "."
pprPatSynType ty = ppr ty
------------------------------
instance Ppr Module where
ppr (Module pkg m) = text (pkgString pkg) <+> text (modString m)
instance Ppr ModuleInfo where
ppr (ModuleInfo imps) = text "Module" <+> vcat (map ppr imps)
------------------------------
instance Ppr Exp where
ppr = pprExp noPrec
pprPrefixOcc :: Name -> Doc
-- Print operators with parens around them
pprPrefixOcc n = parensIf (isSymOcc n) (ppr n)
isSymOcc :: Name -> Bool
isSymOcc n
= case nameBase n of
[] -> True -- Empty name; weird
(c:_) -> startsVarSym c
-- c.f. OccName.startsVarSym in GHC itself
pprInfixExp :: Exp -> Doc
pprInfixExp (VarE v) = pprName' Infix v
pprInfixExp (ConE v) = pprName' Infix v
pprInfixExp (UnboundVarE v) = pprName' Infix v
-- This case will only ever be reached in exceptional circumstances.
-- For example, when printing an error message in case of a malformed expression.
pprInfixExp e = text "`" <> ppr e <> text "`"
pprExp :: Precedence -> Exp -> Doc
pprExp _ (VarE v) = pprName' Applied v
pprExp _ (ConE c) = pprName' Applied c
pprExp i (LitE l) = pprLit i l
pprExp i (AppE e1 e2) = parensIf (i >= appPrec) $ pprExp opPrec e1
<+> pprExp appPrec e2
pprExp i (AppTypeE e t)
= parensIf (i >= appPrec) $ pprExp opPrec e <+> char '@' <> pprParendType t
pprExp _ (ParensE e) = parens (pprExp noPrec e)
pprExp i (UInfixE e1 op e2)
= parensIf (i > unopPrec) $ pprExp unopPrec e1
<+> pprInfixExp op
<+> pprExp unopPrec e2
pprExp i (InfixE (Just e1) op (Just e2))
= parensIf (i >= opPrec) $ pprExp opPrec e1
<+> pprInfixExp op
<+> pprExp opPrec e2
pprExp _ (InfixE me1 op me2) = parens $ pprMaybeExp noPrec me1
<+> pprInfixExp op
<+> pprMaybeExp noPrec me2
pprExp i (LamE [] e) = pprExp i e -- #13856
pprExp i (LamE ps e) = parensIf (i > noPrec) $ char '\\' <> hsep (map (pprPat appPrec) ps)
<+> text "->" <+> ppr e
pprExp i (LamCaseE ms) = parensIf (i > noPrec)
$ text "\\case" $$ nest nestDepth (ppr ms)
pprExp i (TupE es)
| [Just e] <- es
= pprExp i (ConE (tupleDataName 1) `AppE` e)
| otherwise
= parens (commaSepWith (pprMaybeExp noPrec) es)
pprExp _ (UnboxedTupE es) = hashParens (commaSepWith (pprMaybeExp noPrec) es)
pprExp _ (UnboxedSumE e alt arity) = unboxedSumBars (ppr e) alt arity
-- Nesting in Cond is to avoid potential problems in do statements
pprExp i (CondE guard true false)
= parensIf (i > noPrec) $ sep [text "if" <+> ppr guard,
nest 1 $ text "then" <+> ppr true,
nest 1 $ text "else" <+> ppr false]
pprExp i (MultiIfE alts)
= parensIf (i > noPrec) $ vcat $
case alts of
[] -> [text "if {}"]
(alt : alts') -> text "if" <+> pprGuarded arrow alt
: map (nest 3 . pprGuarded arrow) alts'
pprExp i (LetE ds_ e) = parensIf (i > noPrec) $ text "let" <+> pprDecs ds_
$$ text " in" <+> ppr e
where
pprDecs [] = empty
pprDecs [d] = ppr d
pprDecs ds = braces (semiSep ds)
pprExp i (CaseE e ms)
= parensIf (i > noPrec) $ text "case" <+> ppr e <+> text "of"
$$ nest nestDepth (ppr ms)
pprExp i (DoE m ss_) = parensIf (i > noPrec) $
pprQualifier m <> text "do" <+> pprStms ss_
where
pprQualifier Nothing = empty
pprQualifier (Just modName) = text (modString modName) <> char '.'
pprStms [] = empty
pprStms [s] = ppr s
pprStms ss = braces (semiSep ss)
pprExp i (MDoE m ss_) = parensIf (i > noPrec) $
pprQualifier m <> text "mdo" <+> pprStms ss_
where
pprQualifier Nothing = empty
pprQualifier (Just modName) = text (modString modName) <> char '.'
pprStms [] = empty
pprStms [s] = ppr s
pprStms ss = braces (semiSep ss)
pprExp _ (CompE []) = text "<<Empty CompExp>>"
-- This will probably break with fixity declarations - would need a ';'
pprExp _ (CompE ss) =
if null ss'
-- If there are no statements in a list comprehension besides the last
-- one, we simply treat it like a normal list.
then text "[" <> ppr s <> text "]"
else text "[" <> ppr s
<+> bar
<+> commaSep ss'
<> text "]"
where s = last ss
ss' = init ss
pprExp _ (ArithSeqE d) = ppr d
pprExp _ (ListE es) = brackets (commaSep es)
pprExp i (SigE e t) = parensIf (i > noPrec) $ pprExp sigPrec e
<+> dcolon <+> ppr t
pprExp _ (RecConE nm fs) = pprName' Applied nm <> braces (pprFields fs)
pprExp _ (RecUpdE e fs) = pprExp appPrec e <> braces (pprFields fs)
pprExp i (StaticE e) = parensIf (i >= appPrec) $
text "static"<+> pprExp appPrec e
pprExp _ (UnboundVarE v) = pprName' Applied v
pprExp _ (LabelE s) = text "#" <> text s
pprExp _ (ImplicitParamVarE n) = text ('?' : n)
pprFields :: [(Name,Exp)] -> Doc
pprFields = sep . punctuate comma . map (\(s,e) -> pprName' Applied s <+> equals <+> ppr e)
pprMaybeExp :: Precedence -> Maybe Exp -> Doc
pprMaybeExp _ Nothing = empty
pprMaybeExp i (Just e) = pprExp i e
------------------------------
instance Ppr Stmt where
ppr (BindS p e) = ppr p <+> text "<-" <+> ppr e
ppr (LetS ds) = text "let" <+> (braces (semiSep ds))
ppr (NoBindS e) = ppr e
ppr (ParS sss) = sep $ punctuate bar
$ map commaSep sss
ppr (RecS ss) = text "rec" <+> (braces (semiSep ss))
------------------------------
instance Ppr Match where
ppr (Match p rhs ds) = pprMatchPat p <+> pprBody False rhs
$$ where_clause ds
pprMatchPat :: Pat -> Doc
-- Everything except pattern signatures bind more tightly than (->)
pprMatchPat p@(SigP {}) = parens (ppr p)
pprMatchPat p = ppr p
------------------------------
pprGuarded :: Doc -> (Guard, Exp) -> Doc
pprGuarded eqDoc (guard, expr) = case guard of
NormalG guardExpr -> bar <+> ppr guardExpr <+> eqDoc <+> ppr expr
PatG stmts -> bar <+> vcat (punctuate comma $ map ppr stmts) $$
nest nestDepth (eqDoc <+> ppr expr)
------------------------------
pprBody :: Bool -> Body -> Doc
pprBody eq body = case body of
GuardedB xs -> nest nestDepth $ vcat $ map (pprGuarded eqDoc) xs
NormalB e -> eqDoc <+> ppr e
where eqDoc | eq = equals
| otherwise = arrow
------------------------------
instance Ppr Lit where
ppr = pprLit noPrec
pprLit :: Precedence -> Lit -> Doc
pprLit i (IntPrimL x) = parensIf (i > noPrec && x < 0)
(integer x <> char '#')
pprLit _ (WordPrimL x) = integer x <> text "##"
pprLit i (FloatPrimL x) = parensIf (i > noPrec && x < 0)
(float (fromRational x) <> char '#')
pprLit i (DoublePrimL x) = parensIf (i > noPrec && x < 0)
(double (fromRational x) <> text "##")
pprLit i (IntegerL x) = parensIf (i > noPrec && x < 0) (integer x)
pprLit _ (CharL c) = text (show c)
pprLit _ (CharPrimL c) = text (show c) <> char '#'
pprLit _ (StringL s) = pprString s
pprLit _ (StringPrimL s) = pprString (bytesToString s) <> char '#'
pprLit _ (BytesPrimL {}) = pprString "<binary data>"
pprLit i (RationalL rat) = parensIf (i > noPrec) $
integer (numerator rat) <+> char '/'
<+> integer (denominator rat)
bytesToString :: [Word8] -> String
bytesToString = map (chr . fromIntegral)
pprString :: String -> Doc
-- Print newlines as newlines with Haskell string escape notation,
-- not as '\n'. For other non-printables use regular escape notation.
pprString s = vcat (map text (showMultiLineString s))
------------------------------
instance Ppr Pat where
ppr = pprPat noPrec
pprPat :: Precedence -> Pat -> Doc
pprPat i (LitP l) = pprLit i l
pprPat _ (VarP v) = pprName' Applied v
pprPat i (TupP ps)
| [_] <- ps
= pprPat i (ConP (tupleDataName 1) [] ps)
| otherwise
= parens (commaSep ps)
pprPat _ (UnboxedTupP ps) = hashParens (commaSep ps)
pprPat _ (UnboxedSumP p alt arity) = unboxedSumBars (ppr p) alt arity
pprPat i (ConP s ts ps) = parensIf (i >= appPrec) $
pprName' Applied s
<+> sep (map (\t -> char '@' <> pprParendType t) ts)
<+> sep (map (pprPat appPrec) ps)
pprPat _ (ParensP p) = parens $ pprPat noPrec p
pprPat i (UInfixP p1 n p2)
= parensIf (i > unopPrec) (pprPat unopPrec p1 <+>
pprName' Infix n <+>
pprPat unopPrec p2)
pprPat i (InfixP p1 n p2)
= parensIf (i >= opPrec) (pprPat opPrec p1 <+>
pprName' Infix n <+>
pprPat opPrec p2)
pprPat i (TildeP p) = parensIf (i > noPrec) $ char '~' <> pprPat appPrec p
pprPat i (BangP p) = parensIf (i > noPrec) $ char '!' <> pprPat appPrec p
pprPat i (AsP v p) = parensIf (i > noPrec) $ ppr v <> text "@"
<> pprPat appPrec p
pprPat _ WildP = text "_"
pprPat _ (RecP nm fs)
= parens $ pprName' Applied nm
<+> braces (sep $ punctuate comma $
map (\(s,p) -> pprName' Applied s <+> equals <+> ppr p) fs)
pprPat _ (ListP ps) = brackets (commaSep ps)
pprPat i (SigP p t) = parensIf (i > noPrec) $ ppr p <+> dcolon <+> ppr t
pprPat _ (ViewP e p) = parens $ pprExp noPrec e <+> text "->" <+> pprPat noPrec p
------------------------------
instance Ppr Dec where
ppr = ppr_dec True
ppr_dec :: Bool -- declaration on the toplevel?
-> Dec
-> Doc
ppr_dec _ (FunD f cs) = vcat $ map (\c -> pprPrefixOcc f <+> ppr c) cs
ppr_dec _ (ValD p r ds) = ppr p <+> pprBody True r
$$ where_clause ds
ppr_dec _ (TySynD t xs rhs)
= ppr_tySyn empty (Just t) (hsep (map ppr xs)) rhs
ppr_dec _ (DataD ctxt t xs ksig cs decs)
= ppr_data empty ctxt (Just t) (hsep (map ppr xs)) ksig cs decs
ppr_dec _ (NewtypeD ctxt t xs ksig c decs)
= ppr_newtype empty ctxt (Just t) (sep (map ppr xs)) ksig c decs
ppr_dec _ (ClassD ctxt c xs fds ds)
= text "class" <+> pprCxt ctxt <+> ppr c <+> hsep (map ppr xs) <+> ppr fds
$$ where_clause ds
ppr_dec _ (InstanceD o ctxt i ds) =
text "instance" <+> maybe empty ppr_overlap o <+> pprCxt ctxt <+> ppr i
$$ where_clause ds
ppr_dec _ (SigD f t) = pprPrefixOcc f <+> dcolon <+> ppr t
ppr_dec _ (KiSigD f k) = text "type" <+> pprPrefixOcc f <+> dcolon <+> ppr k
ppr_dec _ (ForeignD f) = ppr f
ppr_dec _ (InfixD fx n) = pprFixity n fx
ppr_dec _ (DefaultD tys) =
text "default" <+> parens (sep $ punctuate comma $ map ppr tys)
ppr_dec _ (PragmaD p) = ppr p
ppr_dec isTop (DataFamilyD tc tvs kind)
= text "data" <+> maybeFamily <+> ppr tc <+> hsep (map ppr tvs) <+> maybeKind
where
maybeFamily | isTop = text "family"
| otherwise = empty
maybeKind | (Just k') <- kind = dcolon <+> ppr k'
| otherwise = empty
ppr_dec isTop (DataInstD ctxt bndrs ty ksig cs decs)
= ppr_data (maybeInst <+> ppr_bndrs bndrs)
ctxt Nothing (ppr ty) ksig cs decs
where
maybeInst | isTop = text "instance"
| otherwise = empty
ppr_dec isTop (NewtypeInstD ctxt bndrs ty ksig c decs)
= ppr_newtype (maybeInst <+> ppr_bndrs bndrs)
ctxt Nothing (ppr ty) ksig c decs
where
maybeInst | isTop = text "instance"
| otherwise = empty
ppr_dec isTop (TySynInstD (TySynEqn mb_bndrs ty rhs))
= ppr_tySyn (maybeInst <+> ppr_bndrs mb_bndrs)
Nothing (ppr ty) rhs
where
maybeInst | isTop = text "instance"
| otherwise = empty
ppr_dec isTop (OpenTypeFamilyD tfhead)
= text "type" <+> maybeFamily <+> ppr_tf_head tfhead
where
maybeFamily | isTop = text "family"
| otherwise = empty
ppr_dec _ (ClosedTypeFamilyD tfhead eqns)
= hang (text "type family" <+> ppr_tf_head tfhead <+> text "where")
nestDepth (vcat (map ppr_eqn eqns))
where
ppr_eqn (TySynEqn mb_bndrs lhs rhs)
= ppr_bndrs mb_bndrs <+> ppr lhs <+> text "=" <+> ppr rhs
ppr_dec _ (RoleAnnotD name roles)
= hsep [ text "type role", ppr name ] <+> hsep (map ppr roles)
ppr_dec _ (StandaloneDerivD ds cxt ty)
= hsep [ text "deriving"
, maybe empty ppr_deriv_strategy ds
, text "instance"
, pprCxt cxt
, ppr ty ]
ppr_dec _ (DefaultSigD n ty)
= hsep [ text "default", pprPrefixOcc n, dcolon, ppr ty ]
ppr_dec _ (PatSynD name args dir pat)
= text "pattern" <+> pprNameArgs <+> ppr dir <+> pprPatRHS
where
pprNameArgs | InfixPatSyn a1 a2 <- args = ppr a1 <+> pprName' Infix name <+> ppr a2
| otherwise = pprName' Applied name <+> ppr args
pprPatRHS | ExplBidir cls <- dir = hang (ppr pat <+> text "where")
nestDepth (pprName' Applied name <+> ppr cls)
| otherwise = ppr pat
ppr_dec _ (PatSynSigD name ty)
= pprPatSynSig name ty
ppr_dec _ (ImplicitParamBindD n e)
= hsep [text ('?' : n), text "=", ppr e]
ppr_deriv_strategy :: DerivStrategy -> Doc
ppr_deriv_strategy ds =
case ds of
StockStrategy -> text "stock"
AnyclassStrategy -> text "anyclass"
NewtypeStrategy -> text "newtype"
ViaStrategy ty -> text "via" <+> pprParendType ty
ppr_overlap :: Overlap -> Doc
ppr_overlap o = text $
case o of
Overlaps -> "{-# OVERLAPS #-}"
Overlappable -> "{-# OVERLAPPABLE #-}"
Overlapping -> "{-# OVERLAPPING #-}"
Incoherent -> "{-# INCOHERENT #-}"
ppr_data :: Doc -> Cxt -> Maybe Name -> Doc -> Maybe Kind -> [Con] -> [DerivClause]
-> Doc
ppr_data maybeInst ctxt t argsDoc ksig cs decs
= sep [text "data" <+> maybeInst
<+> pprCxt ctxt
<+> case t of
Just n -> pprName' Applied n <+> argsDoc
Nothing -> argsDoc
<+> ksigDoc <+> maybeWhere,
nest nestDepth (sep (pref $ map ppr cs)),
if null decs
then empty
else nest nestDepth
$ vcat $ map ppr_deriv_clause decs]
where
pref :: [Doc] -> [Doc]
pref xs | isGadtDecl = xs
pref [] = [] -- No constructors; can't happen in H98
pref (d:ds) = (char '=' <+> d):map (bar <+>) ds
maybeWhere :: Doc
maybeWhere | isGadtDecl = text "where"
| otherwise = empty
isGadtDecl :: Bool
isGadtDecl = not (null cs) && all isGadtCon cs
where isGadtCon (GadtC _ _ _ ) = True
isGadtCon (RecGadtC _ _ _) = True
isGadtCon (ForallC _ _ x ) = isGadtCon x
isGadtCon _ = False
ksigDoc = case ksig of
Nothing -> empty
Just k -> dcolon <+> ppr k
ppr_newtype :: Doc -> Cxt -> Maybe Name -> Doc -> Maybe Kind -> Con -> [DerivClause]
-> Doc
ppr_newtype maybeInst ctxt t argsDoc ksig c decs
= sep [text "newtype" <+> maybeInst
<+> pprCxt ctxt
<+> case t of
Just n -> ppr n <+> argsDoc
Nothing -> argsDoc
<+> ksigDoc,
nest 2 (char '=' <+> ppr c),
if null decs
then empty
else nest nestDepth
$ vcat $ map ppr_deriv_clause decs]
where
ksigDoc = case ksig of
Nothing -> empty
Just k -> dcolon <+> ppr k
ppr_deriv_clause :: DerivClause -> Doc
ppr_deriv_clause (DerivClause ds ctxt)
= text "deriving" <+> pp_strat_before
<+> ppr_cxt_preds ctxt
<+> pp_strat_after
where
-- @via@ is unique in that in comes /after/ the class being derived,
-- so we must special-case it.
(pp_strat_before, pp_strat_after) =
case ds of
Just (via@ViaStrategy{}) -> (empty, ppr_deriv_strategy via)
_ -> (maybe empty ppr_deriv_strategy ds, empty)
ppr_tySyn :: Doc -> Maybe Name -> Doc -> Type -> Doc
ppr_tySyn maybeInst t argsDoc rhs
= text "type" <+> maybeInst
<+> case t of
Just n -> pprName' Applied n <+> argsDoc
Nothing -> argsDoc
<+> text "=" <+> ppr rhs
ppr_tf_head :: TypeFamilyHead -> Doc
ppr_tf_head (TypeFamilyHead tc tvs res inj)
= pprName' Applied tc <+> hsep (map ppr tvs) <+> ppr res <+> maybeInj
where
maybeInj | (Just inj') <- inj = ppr inj'
| otherwise = empty
ppr_bndrs :: PprFlag flag => Maybe [TyVarBndr flag] -> Doc
ppr_bndrs (Just bndrs) = text "forall" <+> sep (map ppr bndrs) <> text "."
ppr_bndrs Nothing = empty
------------------------------
instance Ppr FunDep where
ppr (FunDep xs ys) = hsep (map ppr xs) <+> text "->" <+> hsep (map ppr ys)
ppr_list [] = empty
ppr_list xs = bar <+> commaSep xs
------------------------------
instance Ppr FamilyResultSig where
ppr NoSig = empty
ppr (KindSig k) = dcolon <+> ppr k
ppr (TyVarSig bndr) = text "=" <+> ppr bndr
------------------------------
instance Ppr InjectivityAnn where
ppr (InjectivityAnn lhs rhs) =
bar <+> ppr lhs <+> text "->" <+> hsep (map ppr rhs)
------------------------------
instance Ppr Foreign where
ppr (ImportF callconv safety impent as typ)
= text "foreign import"
<+> showtextl callconv
<+> showtextl safety
<+> text (show impent)
<+> pprName' Applied as
<+> dcolon <+> ppr typ
ppr (ExportF callconv expent as typ)
= text "foreign export"
<+> showtextl callconv
<+> text (show expent)
<+> pprName' Applied as
<+> dcolon <+> ppr typ
------------------------------
instance Ppr Pragma where
ppr (InlineP n inline rm phases)
= text "{-#"
<+> ppr inline
<+> ppr rm
<+> ppr phases
<+> pprName' Applied n
<+> text "#-}"
ppr (SpecialiseP n ty inline phases)
= text "{-# SPECIALISE"
<+> maybe empty ppr inline
<+> ppr phases
<+> sep [ pprName' Applied n <+> dcolon
, nest 2 $ ppr ty ]
<+> text "#-}"
ppr (SpecialiseInstP inst)
= text "{-# SPECIALISE instance" <+> ppr inst <+> text "#-}"
ppr (RuleP n ty_bndrs tm_bndrs lhs rhs phases)
= sep [ text "{-# RULES" <+> pprString n <+> ppr phases
, nest 4 $ ppr_ty_forall ty_bndrs <+> ppr_tm_forall ty_bndrs
<+> ppr lhs
, nest 4 $ char '=' <+> ppr rhs <+> text "#-}" ]
where ppr_ty_forall Nothing = empty
ppr_ty_forall (Just bndrs) = text "forall"
<+> fsep (map ppr bndrs)
<+> char '.'
ppr_tm_forall Nothing | null tm_bndrs = empty
ppr_tm_forall _ = text "forall"
<+> fsep (map ppr tm_bndrs)
<+> char '.'
ppr (AnnP tgt expr)
= text "{-# ANN" <+> target1 tgt <+> ppr expr <+> text "#-}"
where target1 ModuleAnnotation = text "module"
target1 (TypeAnnotation t) = text "type" <+> pprName' Applied t
target1 (ValueAnnotation v) = pprName' Applied v
ppr (LineP line file)
= text "{-# LINE" <+> int line <+> text (show file) <+> text "#-}"
ppr (CompleteP cls mty)
= text "{-# COMPLETE" <+> (fsep $ punctuate comma $ map (pprName' Applied) cls)
<+> maybe empty (\ty -> dcolon <+> pprName' Applied ty) mty <+> text "#-}"
------------------------------
instance Ppr Inline where
ppr NoInline = text "NOINLINE"
ppr Inline = text "INLINE"
ppr Inlinable = text "INLINABLE"
------------------------------
instance Ppr RuleMatch where
ppr ConLike = text "CONLIKE"
ppr FunLike = empty
------------------------------
instance Ppr Phases where
ppr AllPhases = empty
ppr (FromPhase i) = brackets $ int i
ppr (BeforePhase i) = brackets $ char '~' <> int i
------------------------------
instance Ppr RuleBndr where
ppr (RuleVar n) = ppr n
ppr (TypedRuleVar n ty) = parens $ ppr n <+> dcolon <+> ppr ty
------------------------------
instance Ppr Clause where
ppr (Clause ps rhs ds) = hsep (map (pprPat appPrec) ps) <+> pprBody True rhs
$$ where_clause ds
------------------------------
instance Ppr Con where
ppr (NormalC c sts) = pprName' Applied c <+> sep (map pprBangType sts)
ppr (RecC c vsts)
= pprName' Applied c <+> braces (sep (punctuate comma $ map pprVarBangType vsts))
ppr (InfixC st1 c st2) = pprBangType st1
<+> pprName' Infix c
<+> pprBangType st2
ppr (ForallC ns ctxt (GadtC c sts ty))
= commaSepApplied c <+> dcolon <+> pprForall ns ctxt
<+> pprGadtRHS sts ty
ppr (ForallC ns ctxt (RecGadtC c vsts ty))
= commaSepApplied c <+> dcolon <+> pprForall ns ctxt
<+> pprRecFields vsts ty
ppr (ForallC ns ctxt con)
= pprForall ns ctxt <+> ppr con
ppr (GadtC c sts ty)
= commaSepApplied c <+> dcolon <+> pprGadtRHS sts ty
ppr (RecGadtC c vsts ty)
= commaSepApplied c <+> dcolon <+> pprRecFields vsts ty
instance Ppr PatSynDir where
ppr Unidir = text "<-"
ppr ImplBidir = text "="
ppr (ExplBidir _) = text "<-"
-- the ExplBidir's clauses are pretty printed together with the
-- entire pattern synonym; so only print the direction here.
instance Ppr PatSynArgs where
ppr (PrefixPatSyn args) = sep $ map ppr args
ppr (InfixPatSyn a1 a2) = ppr a1 <+> ppr a2
ppr (RecordPatSyn sels) = braces $ sep (punctuate comma (map (pprName' Applied) sels))
commaSepApplied :: [Name] -> Doc
commaSepApplied = commaSepWith (pprName' Applied)
pprForall :: [TyVarBndr Specificity] -> Cxt -> Doc
pprForall = pprForall' ForallInvis
pprForallVis :: [TyVarBndr ()] -> Cxt -> Doc
pprForallVis = pprForall' ForallVis
pprForall' :: PprFlag flag => ForallVisFlag -> [TyVarBndr flag] -> Cxt -> Doc
pprForall' fvf tvs cxt
-- even in the case without any tvs, there could be a non-empty
-- context cxt (e.g., in the case of pattern synonyms, where there
-- are multiple forall binders and contexts).
| [] <- tvs = pprCxt cxt
| otherwise = text "forall" <+> hsep (map ppr tvs)
<+> separator <+> pprCxt cxt
where
separator = case fvf of
ForallVis -> text "->"
ForallInvis -> char '.'
pprRecFields :: [(Name, Strict, Type)] -> Type -> Doc
pprRecFields vsts ty
= braces (sep (punctuate comma $ map pprVarBangType vsts))
<+> arrow <+> ppr ty
pprGadtRHS :: [(Strict, Type)] -> Type -> Doc
pprGadtRHS [] ty
= ppr ty
pprGadtRHS sts ty
= sep (punctuate (space <> arrow) (map pprBangType sts))
<+> arrow <+> ppr ty
------------------------------
pprVarBangType :: VarBangType -> Doc
-- Slight infelicity: with print non-atomic type with parens
pprVarBangType (v, bang, t) = pprName' Applied v <+> dcolon <+> pprBangType (bang, t)
------------------------------
pprBangType :: BangType -> Doc
-- Make sure we print
--
-- Con {-# UNPACK #-} a
--
-- rather than
--
-- Con {-# UNPACK #-}a
--
-- when there's no strictness annotation. If there is a strictness annotation,
-- it's okay to not put a space between it and the type.
pprBangType (bt@(Bang _ NoSourceStrictness), t) = ppr bt <+> pprParendType t
pprBangType (bt, t) = ppr bt <> pprParendType t
------------------------------
instance Ppr Bang where
ppr (Bang su ss) = ppr su <+> ppr ss
------------------------------
instance Ppr SourceUnpackedness where
ppr NoSourceUnpackedness = empty
ppr SourceNoUnpack = text "{-# NOUNPACK #-}"
ppr SourceUnpack = text "{-# UNPACK #-}"
------------------------------
instance Ppr SourceStrictness where
ppr NoSourceStrictness = empty
ppr SourceLazy = char '~'
ppr SourceStrict = char '!'
------------------------------
instance Ppr DecidedStrictness where
ppr DecidedLazy = empty
ppr DecidedStrict = char '!'
ppr DecidedUnpack = text "{-# UNPACK #-} !"
------------------------------
{-# DEPRECATED pprVarStrictType
"As of @template-haskell-2.11.0.0@, 'VarStrictType' has been replaced by 'VarBangType'. Please use 'pprVarBangType' instead." #-}
pprVarStrictType :: (Name, Strict, Type) -> Doc
pprVarStrictType = pprVarBangType
------------------------------
{-# DEPRECATED pprStrictType
"As of @template-haskell-2.11.0.0@, 'StrictType' has been replaced by 'BangType'. Please use 'pprBangType' instead." #-}
pprStrictType :: (Strict, Type) -> Doc
pprStrictType = pprBangType
------------------------------
pprParendType :: Type -> Doc
pprParendType (VarT v) = pprName' Applied v
-- `Applied` is used here instead of `ppr` because of infix names (#13887)
pprParendType (ConT c) = pprName' Applied c
pprParendType (TupleT 0) = text "()"
pprParendType (TupleT 1) = pprParendType (ConT (tupleTypeName 1))
pprParendType (TupleT n) = parens (hcat (replicate (n-1) comma))
pprParendType (UnboxedTupleT n) = hashParens $ hcat $ replicate (n-1) comma
pprParendType (UnboxedSumT arity) = hashParens $ hcat $ replicate (arity-1) bar
pprParendType ArrowT = parens (text "->")
pprParendType MulArrowT = text "FUN"
pprParendType ListT = text "[]"
pprParendType (LitT l) = pprTyLit l
pprParendType (PromotedT c) = text "'" <> pprName' Applied c
pprParendType (PromotedTupleT 0) = text "'()"
pprParendType (PromotedTupleT 1) = pprParendType (PromotedT (tupleDataName 1))
pprParendType (PromotedTupleT n) = quoteParens (hcat (replicate (n-1) comma))
pprParendType PromotedNilT = text "'[]"
pprParendType PromotedConsT = text "'(:)"
pprParendType StarT = char '*'
pprParendType ConstraintT = text "Constraint"
pprParendType (SigT ty k) = parens (ppr ty <+> text "::" <+> ppr k)
pprParendType WildCardT = char '_'
pprParendType (InfixT x n y) = parens (ppr x <+> pprName' Infix n <+> ppr y)
pprParendType t@(UInfixT {}) = parens (pprUInfixT t)
pprParendType (ParensT t) = ppr t
pprParendType tuple | (TupleT n, args) <- split tuple
, length args == n
= parens (commaSep args)
pprParendType (ImplicitParamT n t)= text ('?':n) <+> text "::" <+> ppr t
pprParendType EqualityT = text "(~)"
pprParendType t@(ForallT {}) = parens (ppr t)
pprParendType t@(ForallVisT {}) = parens (ppr t)
pprParendType t@(AppT {}) = parens (ppr t)
pprParendType t@(AppKindT {}) = parens (ppr t)
pprUInfixT :: Type -> Doc
pprUInfixT (UInfixT x n y) = pprUInfixT x <+> pprName' Infix n <+> pprUInfixT y
pprUInfixT t = ppr t
instance Ppr Type where
ppr (ForallT tvars ctxt ty) = sep [pprForall tvars ctxt, ppr ty]
ppr (ForallVisT tvars ty) = sep [pprForallVis tvars [], ppr ty]
ppr ty = pprTyApp (split ty)
-- Works, in a degenerate way, for SigT, and puts parens round (ty :: kind)
-- See Note [Pretty-printing kind signatures]
instance Ppr TypeArg where
ppr (TANormal ty) = parensIf (isStarT ty) (ppr ty)
ppr (TyArg ki) = char '@' <> parensIf (isStarT ki) (ppr ki)
pprParendTypeArg :: TypeArg -> Doc
pprParendTypeArg (TANormal ty) = parensIf (isStarT ty) (pprParendType ty)
pprParendTypeArg (TyArg ki) = char '@' <> parensIf (isStarT ki) (pprParendType ki)
isStarT :: Type -> Bool
isStarT StarT = True
isStarT _ = False
{- Note [Pretty-printing kind signatures]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
GHC's parser only recognises a kind signature in a type when there are
parens around it. E.g. the parens are required here:
f :: (Int :: *)
type instance F Int = (Bool :: *)
So we always print a SigT with parens (see #10050). -}
pprTyApp :: (Type, [TypeArg]) -> Doc
pprTyApp (MulArrowT, [TANormal (PromotedT c), TANormal arg1, TANormal arg2])
| c == oneName = sep [pprFunArgType arg1 <+> text "%1 ->", ppr arg2]
| c == manyName = sep [pprFunArgType arg1 <+> text "->", ppr arg2]
pprTyApp (MulArrowT, [TANormal argm, TANormal arg1, TANormal arg2]) =
sep [pprFunArgType arg1 <+> text "%" <> ppr argm <+> text "->", ppr arg2]
pprTyApp (ArrowT, [TANormal arg1, TANormal arg2]) = sep [pprFunArgType arg1 <+> text "->", ppr arg2]
pprTyApp (EqualityT, [TANormal arg1, TANormal arg2]) =
sep [pprFunArgType arg1 <+> text "~", ppr arg2]
pprTyApp (ListT, [TANormal arg]) = brackets (ppr arg)
pprTyApp (TupleT 1, args) = pprTyApp (ConT (tupleTypeName 1), args)
pprTyApp (PromotedTupleT 1, args) = pprTyApp (PromotedT (tupleDataName 1), args)
pprTyApp (TupleT n, args)
| length args == n, Just args' <- traverse fromTANormal args
= parens (commaSep args')
pprTyApp (PromotedTupleT n, args)
| length args == n, Just args' <- traverse fromTANormal args
= quoteParens (commaSep args')
pprTyApp (fun, args) = pprParendType fun <+> sep (map pprParendTypeArg args)
fromTANormal :: TypeArg -> Maybe Type
fromTANormal (TANormal arg) = Just arg
fromTANormal (TyArg _) = Nothing
pprFunArgType :: Type -> Doc -- Should really use a precedence argument
-- Everything except forall and (->) binds more tightly than (->)
pprFunArgType ty@(ForallT {}) = parens (ppr ty)
pprFunArgType ty@(ForallVisT {}) = parens (ppr ty)
pprFunArgType ty@(((MulArrowT `AppT` _) `AppT` _) `AppT` _) = parens (ppr ty)
pprFunArgType ty@((ArrowT `AppT` _) `AppT` _) = parens (ppr ty)
pprFunArgType ty@(SigT _ _) = parens (ppr ty)
pprFunArgType ty = ppr ty
data ForallVisFlag = ForallVis -- forall a -> {...}
| ForallInvis -- forall a. {...}
deriving Show
data TypeArg = TANormal Type
| TyArg Kind
split :: Type -> (Type, [TypeArg]) -- Split into function and args
split t = go t []
where go (AppT t1 t2) args = go t1 (TANormal t2:args)
go (AppKindT ty ki) args = go ty (TyArg ki:args)
go ty args = (ty, args)
pprTyLit :: TyLit -> Doc
pprTyLit (NumTyLit n) = integer n
pprTyLit (StrTyLit s) = text (show s)
pprTyLit (CharTyLit c) = text (show c)
instance Ppr TyLit where
ppr = pprTyLit
------------------------------
class PprFlag flag where
pprTyVarBndr :: (TyVarBndr flag) -> Doc
instance PprFlag () where
pprTyVarBndr (PlainTV nm ()) = ppr nm
pprTyVarBndr (KindedTV nm () k) = parens (ppr nm <+> dcolon <+> ppr k)
instance PprFlag Specificity where
pprTyVarBndr (PlainTV nm SpecifiedSpec) = ppr nm
pprTyVarBndr (PlainTV nm InferredSpec) = braces (ppr nm)
pprTyVarBndr (KindedTV nm SpecifiedSpec k) = parens (ppr nm <+> dcolon <+> ppr k)
pprTyVarBndr (KindedTV nm InferredSpec k) = braces (ppr nm <+> dcolon <+> ppr k)
instance PprFlag flag => Ppr (TyVarBndr flag) where
ppr bndr = pprTyVarBndr bndr
instance Ppr Role where
ppr NominalR = text "nominal"
ppr RepresentationalR = text "representational"
ppr PhantomR = text "phantom"
ppr InferR = text "_"
------------------------------
pprCxt :: Cxt -> Doc
pprCxt [] = empty
pprCxt ts = ppr_cxt_preds ts <+> text "=>"
ppr_cxt_preds :: Cxt -> Doc
ppr_cxt_preds [] = empty
ppr_cxt_preds [t@ImplicitParamT{}] = parens (ppr t)
ppr_cxt_preds [t@ForallT{}] = parens (ppr t)
ppr_cxt_preds [t] = ppr t
ppr_cxt_preds ts = parens (commaSep ts)
------------------------------
instance Ppr Range where
ppr = brackets . pprRange
where pprRange :: Range -> Doc
pprRange (FromR e) = ppr e <> text ".."
pprRange (FromThenR e1 e2) = ppr e1 <> text ","
<> ppr e2 <> text ".."
pprRange (FromToR e1 e2) = ppr e1 <> text ".." <> ppr e2
pprRange (FromThenToR e1 e2 e3) = ppr e1 <> text ","
<> ppr e2 <> text ".."
<> ppr e3
------------------------------
where_clause :: [Dec] -> Doc
where_clause [] = empty
where_clause ds = nest nestDepth $ text "where" <+> vcat (map (ppr_dec False) ds)
showtextl :: Show a => a -> Doc
showtextl = text . map toLower . show
hashParens :: Doc -> Doc
hashParens d = text "(# " <> d <> text " #)"
quoteParens :: Doc -> Doc
quoteParens d = text "'(" <> d <> text ")"
-----------------------------
instance Ppr Loc where
ppr (Loc { loc_module = md
, loc_package = pkg
, loc_start = (start_ln, start_col)
, loc_end = (end_ln, end_col) })
= hcat [ text pkg, colon, text md, colon
, parens $ int start_ln <> comma <> int start_col
, text "-"
, parens $ int end_ln <> comma <> int end_col ]
-- Takes a list of printable things and prints them separated by commas followed
-- by space.
commaSep :: Ppr a => [a] -> Doc
commaSep = commaSepWith ppr
-- Takes a list of things and prints them with the given pretty-printing
-- function, separated by commas followed by space.
commaSepWith :: (a -> Doc) -> [a] -> Doc
commaSepWith pprFun = sep . punctuate comma . map pprFun
-- Takes a list of printable things and prints them separated by semicolons
-- followed by space.
semiSep :: Ppr a => [a] -> Doc
semiSep = sep . punctuate semi . map ppr
-- Prints out the series of vertical bars that wraps an expression or pattern
-- used in an unboxed sum.
unboxedSumBars :: Doc -> SumAlt -> SumArity -> Doc
unboxedSumBars d alt arity = hashParens $
bars (alt-1) <> d <> bars (arity - alt)
where
bars i = hsep (replicate i bar)
-- Text containing the vertical bar character.
bar :: Doc
bar = char '|'
|