-%
+]%
% (c) The GRASP/AQUA Project, Glasgow University, 1992-1998
%
\section[HsTypes]{Abstract syntax: user-defined types}
\begin{code}
module HsTypes (
- HsType(..), HsTyVarBndr(..), HsTyOp(..),
- , HsContext, HsPred(..)
- , HsTupCon(..), hsTupParens, mkHsTupCon,
- , hsUsOnce, hsUsMany
-
- , mkHsForAllTy, mkHsDictTy, mkHsIParamTy
- , hsTyVarName, hsTyVarNames, replaceTyVarName
- , getHsInstHead
+ HsType(..), LHsType,
+ HsTyVarBndr(..), LHsTyVarBndr,
+ HsExplicitForAll(..),
+ HsContext, LHsContext,
+ HsPred(..), LHsPred,
+
+ mkExplicitHsForAllTy, mkImplicitHsForAllTy,
+ hsTyVarName, hsTyVarNames, replaceTyVarName,
+ hsLTyVarName, hsLTyVarNames, hsLTyVarLocName, hsLTyVarLocNames,
+ splitHsInstDeclTy,
-- Type place holder
- , PostTcType, placeHolderType,
+ PostTcType, placeHolderType,
-- Name place holder
- , SyntaxName, placeHolderName,
+ SyntaxName, placeHolderName,
-- Printing
- , pprParendHsType, pprHsForAll, pprHsContext, ppr_hs_context, pprHsTyVarBndr
-
- -- Equality over Hs things
- , EqHsEnv, emptyEqHsEnv, extendEqHsEnv,
- , eqWithHsTyVars, eq_hsVar, eq_hsVars, eq_hsTyVars, eq_hsType, eq_hsContext, eqListBy
-
- -- Converting from Type to HsType
- , toHsType, toHsTyVar, toHsTyVars, toHsContext, toHsFDs
+ pprParendHsType, pprHsForAll, pprHsContext, ppr_hs_context, pprHsTyVarBndr
) where
#include "HsVersions.h"
-import Class ( FunDep )
-import TcType ( Type, Kind, ThetaType, SourceType(..),
- tcSplitSigmaTy, liftedTypeKind, eqKind, tcEqType
- )
-import TypeRep ( Type(..), TyNote(..) ) -- toHsType sees the representation
-import TyCon ( isTupleTyCon, tupleTyConBoxity, tyConArity, isNewTyCon, getSynTyConDefn )
-import RdrName ( RdrName, mkUnqual )
-import Name ( Name, getName, mkInternalName )
-import OccName ( NameSpace, mkVarOcc, tvName )
-import Var ( TyVar, tyVarKind )
-import Subst ( substTyWith )
-import PprType ( {- instance Outputable Kind -}, pprParendKind, pprKind )
-import BasicTypes ( Boxity(..), Arity, IPName, tupleParens )
-import PrelNames ( mkTupConRdrName, listTyConKey, parrTyConKey,
- usOnceTyConKey, usManyTyConKey, hasKey, unboundKey,
- usOnceTyConName, usManyTyConName )
-import SrcLoc ( builtinSrcLoc )
-import Util ( eqListBy, lengthIs )
-import FiniteMap
+import TcType ( Type, Kind, liftedTypeKind, eqKind )
+import Type ( {- instance Outputable Kind -}, pprParendKind, pprKind )
+import Name ( Name, mkInternalName )
+import OccName ( mkVarOcc )
+import BasicTypes ( IPName, Boxity, tupleParens )
+import PrelNames ( unboundKey )
+import SrcLoc ( noSrcLoc, Located(..), unLoc, noSrcSpan )
+import CmdLineOpts ( opt_PprStyle_Debug )
import Outputable
\end{code}
placeHolderName :: SyntaxName
placeHolderName = mkInternalName unboundKey
(mkVarOcc FSLIT("syntaxPlaceHolder"))
- builtinSrcLoc
+ noSrcLoc
\end{code}
This is the syntax for types as seen in type signatures.
\begin{code}
-type HsContext name = [HsPred name]
+type LHsContext name = Located (HsContext name)
+
+type HsContext name = [LHsPred name]
-data HsPred name = HsClassP name [HsType name]
- | HsIParam (IPName name) (HsType name)
+type LHsPred name = Located (HsPred name)
+
+data HsPred name = HsClassP name [LHsType name]
+ | HsIParam (IPName name) (LHsType name)
+
+type LHsType name = Located (HsType name)
data HsType name
- = HsForAllTy (Maybe [HsTyVarBndr name]) -- Nothing for implicitly quantified signatures
- (HsContext name)
- (HsType name)
+ = HsForAllTy HsExplicitForAll -- Renamer leaves this flag unchanged, to record the way
+ -- the user wrote it originally, so that the printer can
+ -- print it as the user wrote it
+ [LHsTyVarBndr name] -- With ImplicitForAll, this is the empty list
+ -- until the renamer fills in the variables
+ (LHsContext name)
+ (LHsType name)
| HsTyVar name -- Type variable or type constructor
- | HsAppTy (HsType name)
- (HsType name)
+ | HsAppTy (LHsType name)
+ (LHsType name)
- | HsFunTy (HsType name) -- function type
- (HsType name)
+ | HsFunTy (LHsType name) -- function type
+ (LHsType name)
- | HsListTy (HsType name) -- Element type
+ | HsListTy (LHsType name) -- Element type
- | HsPArrTy (HsType name) -- Elem. type of parallel array: [:t:]
+ | HsPArrTy (LHsType name) -- Elem. type of parallel array: [:t:]
- | HsTupleTy (HsTupCon name)
- [HsType name] -- Element types (length gives arity)
+ | HsTupleTy Boxity
+ [LHsType name] -- Element types (length gives arity)
- | HsOpTy (HsType name) (HsTyOp name) (HsType name)
+ | HsOpTy (LHsType name) (Located name) (LHsType name)
- | HsParTy (HsType name)
+ | HsParTy (LHsType name)
-- Parenthesis preserved for the precedence re-arrangement in RnTypes
-- It's important that a * (b + c) doesn't get rearranged to (a*b) + c!
--
| HsNumTy Integer -- Generics only
- -- these next two are only used in interfaces
- | HsPredTy (HsPred name)
+ | HsPredTy (LHsPred name) -- Only used in the type of an instance
+ -- declaration, eg. Eq [a] -> Eq a
+ -- ^^^^
+ -- HsPredTy
- | HsKindSig (HsType name) -- (ty :: kind)
+ | HsKindSig (LHsType name) -- (ty :: kind)
Kind -- A type with a kind signature
-
-data HsTyOp name = HsArrow | HsTyOp name
- -- Function arrows from *source* get read in as HsOpTy t1 HsArrow t2
- -- But when we generate or parse interface files, we use HsFunTy.
- -- This keeps interfaces a bit smaller, because there are a lot of arrows
-
------------------------
-hsUsOnce, hsUsMany :: HsType RdrName
-hsUsOnce = HsTyVar (mkUnqual tvName FSLIT(".")) -- deep magic
-hsUsMany = HsTyVar (mkUnqual tvName FSLIT("!")) -- deep magic
-
-hsUsOnce_Name, hsUsMany_Name :: HsType Name
-hsUsOnce_Name = HsTyVar usOnceTyConName
-hsUsMany_Name = HsTyVar usManyTyConName
-
------------------------
-data HsTupCon name = HsTupCon name Boxity Arity
-
-instance Eq name => Eq (HsTupCon name) where
- (HsTupCon _ b1 a1) == (HsTupCon _ b2 a2) = b1==b2 && a1==a2
-
-mkHsTupCon :: NameSpace -> Boxity -> [a] -> HsTupCon RdrName
-mkHsTupCon space boxity args = HsTupCon (mkTupConRdrName space boxity arity) boxity arity
- where
- arity = length args
-
-hsTupParens :: HsTupCon name -> SDoc -> SDoc
-hsTupParens (HsTupCon _ b _) p = tupleParens b p
+data HsExplicitForAll = Explicit | Implicit
-----------------------
-- Combine adjacent for-alls.
--
-- A valid type must have one for-all at the top of the type, or of the fn arg types
-mkHsForAllTy mtvs [] ty = mk_forall_ty mtvs ty
-mkHsForAllTy mtvs ctxt ty = HsForAllTy mtvs ctxt ty
+mkImplicitHsForAllTy ctxt ty = mkHsForAllTy Implicit [] ctxt ty
+mkExplicitHsForAllTy tvs ctxt ty = mkHsForAllTy Explicit tvs ctxt ty
+
+mkHsForAllTy :: HsExplicitForAll -> [LHsTyVarBndr name] -> LHsContext name -> LHsType name -> HsType name
+-- Smart constructor for HsForAllTy
+mkHsForAllTy exp tvs (L _ []) ty = mk_forall_ty exp tvs ty
+mkHsForAllTy exp tvs ctxt ty = HsForAllTy exp tvs ctxt ty
-- mk_forall_ty makes a pure for-all type (no context)
-mk_forall_ty (Just []) ty = ty -- Explicit for-all with no tyvars
-mk_forall_ty mtvs1 (HsParTy ty) = mk_forall_ty mtvs1 ty
-mk_forall_ty mtvs1 (HsForAllTy mtvs2 ctxt ty) = mkHsForAllTy (mtvs1 `plus` mtvs2) ctxt ty
-mk_forall_ty mtvs1 ty = HsForAllTy mtvs1 [] ty
+mk_forall_ty Explicit [] ty = unLoc ty -- Explicit for-all with no tyvars
+mk_forall_ty exp tvs (L _ (HsParTy ty)) = mk_forall_ty exp tvs ty
+mk_forall_ty exp1 tvs1 (L _ (HsForAllTy exp2 tvs2 ctxt ty)) = mkHsForAllTy (exp1 `plus` exp2) (tvs1 ++ tvs2) ctxt ty
+mk_forall_ty exp tvs ty = HsForAllTy exp tvs (L noSrcSpan []) ty
-mtvs1 `plus` Nothing = mtvs1
-Nothing `plus` mtvs2 = mtvs2
-(Just tvs1) `plus` (Just tvs2) = Just (tvs1 ++ tvs2)
+Implicit `plus` Implicit = Implicit
+exp1 `plus` exp2 = Explicit
-mkHsDictTy cls tys = HsPredTy (HsClassP cls tys)
-mkHsIParamTy v ty = HsPredTy (HsIParam v ty)
+type LHsTyVarBndr name = Located (HsTyVarBndr name)
data HsTyVarBndr name
= UserTyVar name
- | IfaceTyVar name Kind
+ | KindedTyVar name Kind
-- *** NOTA BENE *** A "monotype" in a pragma can have
-- for-alls in it, (mostly to do with dictionaries). These
-- must be explicitly Kinded.
-hsTyVarName (UserTyVar n) = n
-hsTyVarName (IfaceTyVar n _) = n
+hsTyVarName :: HsTyVarBndr name -> name
+hsTyVarName (UserTyVar n) = n
+hsTyVarName (KindedTyVar n _) = n
+
+hsLTyVarName :: LHsTyVarBndr name -> name
+hsLTyVarName = hsTyVarName . unLoc
+hsTyVarNames :: [HsTyVarBndr name] -> [name]
hsTyVarNames tvs = map hsTyVarName tvs
+hsLTyVarNames :: [LHsTyVarBndr name] -> [name]
+hsLTyVarNames = map hsLTyVarName
+
+hsLTyVarLocName :: LHsTyVarBndr name -> Located name
+hsLTyVarLocName = fmap hsTyVarName
+
+hsLTyVarLocNames :: [LHsTyVarBndr name] -> [Located name]
+hsLTyVarLocNames = map hsLTyVarLocName
+
replaceTyVarName :: HsTyVarBndr name1 -> name2 -> HsTyVarBndr name2
-replaceTyVarName (UserTyVar n) n' = UserTyVar n'
-replaceTyVarName (IfaceTyVar n k) n' = IfaceTyVar n' k
+replaceTyVarName (UserTyVar n) n' = UserTyVar n'
+replaceTyVarName (KindedTyVar n k) n' = KindedTyVar n' k
\end{code}
\begin{code}
-getHsInstHead :: HsType name -> ([HsTyVarBndr name], (name, [HsType name]))
- -- Split up an instance decl type, returning the 'head' part
-
--- In interface fiels, the type of the decl is held like this:
--- forall a. Foo a -> Baz (T a)
--- so we have to strip off function argument types,
--- as well as the bit before the '=>' (which is always
--- empty in interface files)
---
--- The parser ensures the type will have the right shape.
+splitHsInstDeclTy
+ :: Outputable name
+ => HsType name
+ -> ([LHsTyVarBndr name], HsContext name, name, [LHsType name])
+ -- Split up an instance decl type, returning the pieces
+
+-- In interface files, the instance declaration head is created
+-- by HsTypes.toHsType, which does not guarantee to produce a
+-- HsForAllTy. For example, if we had the weird decl
+-- instance Foo T => Foo [T]
+-- then we'd get the instance type
+-- Foo T -> Foo [T]
+-- So when colleting the instance context, to be on the safe side
+-- we gather predicate arguments
+--
+-- For source code, the parser ensures the type will have the right shape.
-- (e.g. see ParseUtil.checkInstType)
-getHsInstHead (HsForAllTy (Just tvs) _ tau) = (tvs, get_head1 tau)
-getHsInstHead tau = ([], get_head1 tau)
+splitHsInstDeclTy inst_ty
+ = case inst_ty of
+ HsForAllTy _ tvs cxt1 tau -- The type vars should have been
+ -- computed by now, even if they were implicit
+ -> (tvs, unLoc cxt1 ++ cxt2, cls, tys)
+ where
+ (cxt2, cls, tys) = split_tau (unLoc tau)
+
+ other -> ([], cxt2, cls, tys)
+ where
+ (cxt2, cls, tys) = split_tau inst_ty
-get_head1 (HsFunTy _ ty) = get_head1 ty
-get_head1 (HsPredTy (HsClassP cls tys)) = (cls,tys)
+ where
+ split_tau (HsFunTy (L _ (HsPredTy p)) ty) = (p:ps, cls, tys)
+ where
+ (ps, cls, tys) = split_tau (unLoc ty)
+ split_tau (HsPredTy (L _ (HsClassP cls tys))) = ([], cls, tys)
+ split_tau other = pprPanic "splitHsInstDeclTy" (ppr inst_ty)
\end{code}
instance (Outputable name) => Outputable (HsType name) where
ppr ty = pprHsType ty
-instance (Outputable name) => Outputable (HsTyOp name) where
- ppr HsArrow = ftext FSLIT("->")
- ppr (HsTyOp n) = ppr n
-
instance (Outputable name) => Outputable (HsTyVarBndr name) where
- ppr (UserTyVar name) = ppr name
- ppr (IfaceTyVar name kind) = pprHsTyVarBndr name kind
+ ppr (UserTyVar name) = ppr name
+ ppr (KindedTyVar name kind) = pprHsTyVarBndr name kind
instance Outputable name => Outputable (HsPred name) where
- ppr (HsClassP clas tys) = ppr clas <+> hsep (map pprParendHsType tys)
+ ppr (HsClassP clas tys) = ppr clas <+> hsep (map (pprParendHsType.unLoc) tys)
ppr (HsIParam n ty) = hsep [ppr n, dcolon, ppr ty]
pprHsTyVarBndr :: Outputable name => name -> Kind -> SDoc
pprHsTyVarBndr name kind | kind `eqKind` liftedTypeKind = ppr name
| otherwise = hsep [ppr name, dcolon, pprParendKind kind]
-pprHsForAll [] [] = empty
-pprHsForAll tvs cxt
- -- This printer is used for both interface files and
- -- printing user types in error messages; and alas the
- -- two use slightly different syntax. Ah well.
- = getPprStyle $ \ sty ->
- if userStyle sty then
- ptext SLIT("forall") <+> interppSP tvs <> dot <+>
- -- **! ToDo: want to hide uvars from user, but not enough info
- -- in a HsTyVarBndr name (see PprType). KSW 2000-10.
- pprHsContext cxt
- else -- Used in interfaces
- ptext SLIT("__forall") <+> interppSP tvs <+>
- ppr_hs_context cxt <+> ptext SLIT("=>")
+pprHsForAll exp tvs cxt
+ | show_forall = forall_part <+> pprHsContext (unLoc cxt)
+ | otherwise = pprHsContext (unLoc cxt)
+ where
+ show_forall = opt_PprStyle_Debug
+ || (not (null tvs) && is_explicit)
+ is_explicit = case exp of {Explicit -> True; Implicit -> False}
+ forall_part = ptext SLIT("forall") <+> interppSP tvs <> dot
pprHsContext :: (Outputable name) => HsContext name -> SDoc
pprHsContext [] = empty
pprHsType, pprParendHsType :: (Outputable name) => HsType name -> SDoc
-pprHsType ty = ppr_mono_ty pREC_TOP ty
+pprHsType ty = getPprStyle $ \sty -> ppr_mono_ty pREC_TOP (prepare sty ty)
pprParendHsType ty = ppr_mono_ty pREC_CON ty
-ppr_mono_ty ctxt_prec (HsForAllTy maybe_tvs ctxt ty)
+-- Before printing a type
+-- (a) Remove outermost HsParTy parens
+-- (b) Drop top-level for-all type variables in user style
+-- since they are implicit in Haskell
+prepare sty (HsParTy ty) = prepare sty (unLoc ty)
+prepare sty ty = ty
+
+ppr_mono_lty ctxt_prec ty = ppr_mono_ty ctxt_prec (unLoc ty)
+
+ppr_mono_ty ctxt_prec (HsForAllTy exp tvs ctxt ty)
= maybeParen ctxt_prec pREC_FUN $
- sep [pp_header, pprHsType ty]
- where
- pp_header = case maybe_tvs of
- Just tvs -> pprHsForAll tvs ctxt
- Nothing -> pprHsContext ctxt
+ sep [pprHsForAll exp tvs ctxt, ppr_mono_lty pREC_TOP ty]
ppr_mono_ty ctxt_prec (HsTyVar name) = ppr name
ppr_mono_ty ctxt_prec (HsFunTy ty1 ty2) = ppr_fun_ty ctxt_prec ty1 ty2
-ppr_mono_ty ctxt_prec (HsTupleTy con tys) = hsTupParens con (interpp'SP tys)
-ppr_mono_ty ctxt_prec (HsKindSig ty kind) = parens (ppr_mono_ty pREC_TOP ty <+> dcolon <+> pprKind kind)
-ppr_mono_ty ctxt_prec (HsListTy ty) = brackets (ppr_mono_ty pREC_TOP ty)
-ppr_mono_ty ctxt_prec (HsPArrTy ty) = pabrackets (ppr_mono_ty pREC_TOP ty)
+ppr_mono_ty ctxt_prec (HsTupleTy con tys) = tupleParens con (interpp'SP tys)
+ppr_mono_ty ctxt_prec (HsKindSig ty kind) = parens (ppr_mono_lty pREC_TOP ty <+> dcolon <+> pprKind kind)
+ppr_mono_ty ctxt_prec (HsListTy ty) = brackets (ppr_mono_lty pREC_TOP ty)
+ppr_mono_ty ctxt_prec (HsPArrTy ty) = pabrackets (ppr_mono_lty pREC_TOP ty)
ppr_mono_ty ctxt_prec (HsPredTy pred) = braces (ppr pred)
ppr_mono_ty ctxt_prec (HsNumTy n) = integer n -- generics only
ppr_mono_ty ctxt_prec (HsAppTy fun_ty arg_ty)
= maybeParen ctxt_prec pREC_CON $
- hsep [ppr_mono_ty pREC_FUN fun_ty, ppr_mono_ty pREC_CON arg_ty]
-
-ppr_mono_ty ctxt_prec (HsOpTy ty1 HsArrow ty2)
- = ppr_fun_ty ctxt_prec ty1 ty2
+ hsep [ppr_mono_lty pREC_FUN fun_ty, ppr_mono_lty pREC_CON arg_ty]
ppr_mono_ty ctxt_prec (HsOpTy ty1 op ty2)
= maybeParen ctxt_prec pREC_OP $
- ppr_mono_ty pREC_OP ty1 <+> ppr op <+> ppr_mono_ty pREC_OP ty2
+ ppr_mono_lty pREC_OP ty1 <+> ppr op <+> ppr_mono_lty pREC_OP ty2
ppr_mono_ty ctxt_prec (HsParTy ty)
- = parens (ppr_mono_ty pREC_TOP ty)
+ = parens (ppr_mono_lty pREC_TOP ty)
-- Put the parens in where the user did
-- But we still use the precedence stuff to add parens because
-- toHsType doesn't put in any HsParTys, so we may still need them
--------------------------
ppr_fun_ty ctxt_prec ty1 ty2
- = let p1 = ppr_mono_ty pREC_FUN ty1
- p2 = ppr_mono_ty pREC_TOP ty2
+ = let p1 = ppr_mono_lty pREC_FUN ty1
+ p2 = ppr_mono_lty pREC_TOP ty2
in
maybeParen ctxt_prec pREC_FUN $
sep [p1, ptext SLIT("->") <+> p2]
\end{code}
-%************************************************************************
-%* *
-\subsection{Converting from Type to HsType}
-%* *
-%************************************************************************
-
-@toHsType@ converts from a Type to a HsType, making the latter look as
-user-friendly as possible. Notably, it uses synonyms where possible, and
-expresses overloaded functions using the '=>' context part of a HsForAllTy.
-
-\begin{code}
-toHsTyVar :: TyVar -> HsTyVarBndr Name
-toHsTyVar tv = IfaceTyVar (getName tv) (tyVarKind tv)
-
-toHsTyVars tvs = map toHsTyVar tvs
-
-toHsType :: Type -> HsType Name
--- This function knows the representation of types
-toHsType (TyVarTy tv) = HsTyVar (getName tv)
-toHsType (FunTy arg res) = HsFunTy (toHsType arg) (toHsType res)
-toHsType (AppTy fun arg) = HsAppTy (toHsType fun) (toHsType arg)
-
-toHsType (NoteTy (SynNote ty@(TyConApp tycon tyargs)) real_ty)
- | isNewTyCon tycon = toHsType ty
- | syn_matches = toHsType ty -- Use synonyms if possible!!
- | otherwise =
-#ifdef DEBUG
- pprTrace "WARNING: synonym info lost in .hi file for " (ppr syn_ty) $
-#endif
- toHsType real_ty -- but drop it if not.
- where
- syn_matches = ty_from_syn `tcEqType` real_ty
- (tyvars,syn_ty) = getSynTyConDefn tycon
- ty_from_syn = substTyWith tyvars tyargs syn_ty
-
- -- We only use the type synonym in the file if this doesn't cause
- -- us to lose important information. This matters for usage
- -- annotations. It's an issue if some of the args to the synonym
- -- have arrows in them, or if the synonym's RHS has an arrow; for
- -- example, with nofib/real/ebnf2ps/ in Parsers.using.
-
- -- **! It would be nice if when this test fails we could still
- -- write the synonym in as a Note, so we don't lose the info for
- -- error messages, but it's too much work for right now.
- -- KSW 2000-07.
-
-toHsType (NoteTy _ ty) = toHsType ty
-
-toHsType (SourceTy (NType tc tys)) = foldl HsAppTy (HsTyVar (getName tc)) (map toHsType tys)
-toHsType (SourceTy pred) = HsPredTy (toHsPred pred)
-
-toHsType ty@(TyConApp tc tys) -- Must be saturated because toHsType's arg is of kind *
- | not saturated = generic_case
- | isTupleTyCon tc = HsTupleTy (HsTupCon (getName tc) (tupleTyConBoxity tc) (tyConArity tc)) tys'
- | tc `hasKey` listTyConKey = HsListTy (head tys')
- | tc `hasKey` parrTyConKey = HsPArrTy (head tys')
- | tc `hasKey` usOnceTyConKey = hsUsOnce_Name -- must print !, . unqualified
- | tc `hasKey` usManyTyConKey = hsUsMany_Name -- must print !, . unqualified
- | otherwise = generic_case
- where
- generic_case = foldl HsAppTy (HsTyVar (getName tc)) tys'
- tys' = map toHsType tys
- saturated = tys `lengthIs` tyConArity tc
-
-toHsType ty@(ForAllTy _ _) = case tcSplitSigmaTy ty of
- (tvs, preds, tau) -> HsForAllTy (Just (map toHsTyVar tvs))
- (map toHsPred preds)
- (toHsType tau)
-
-toHsPred (ClassP cls tys) = HsClassP (getName cls) (map toHsType tys)
-toHsPred (IParam n ty) = HsIParam n (toHsType ty)
-
-toHsContext :: ThetaType -> HsContext Name
-toHsContext theta = map toHsPred theta
-
-toHsFDs :: [FunDep TyVar] -> [FunDep Name]
-toHsFDs fds = [(map getName ns, map getName ms) | (ns,ms) <- fds]
-\end{code}
-
-
-%************************************************************************
-%* *
-\subsection{Comparison}
-%* *
-%************************************************************************
-
-\begin{code}
-instance Ord a => Eq (HsType a) where
- -- The Ord is needed because we keep a
- -- finite map of variables to variables
- (==) a b = eq_hsType emptyEqHsEnv a b
-
-instance Ord a => Eq (HsPred a) where
- (==) a b = eq_hsPred emptyEqHsEnv a b
-
-eqWithHsTyVars :: Ord name =>
- [HsTyVarBndr name] -> [HsTyVarBndr name]
- -> (EqHsEnv name -> Bool) -> Bool
-eqWithHsTyVars = eq_hsTyVars emptyEqHsEnv
-\end{code}
-
-\begin{code}
-type EqHsEnv n = FiniteMap n n
--- Tracks the mapping from L-variables to R-variables
-
-eq_hsVar :: Ord n => EqHsEnv n -> n -> n -> Bool
-eq_hsVar env n1 n2 = case lookupFM env n1 of
- Just n1 -> n1 == n2
- Nothing -> n1 == n2
-
-extendEqHsEnv env n1 n2
- | n1 == n2 = env
- | otherwise = addToFM env n1 n2
-
-emptyEqHsEnv :: EqHsEnv n
-emptyEqHsEnv = emptyFM
-\end{code}
-
-We do define a specialised equality for these \tr{*Type} types; used
-in checking interfaces.
-
-\begin{code}
--------------------
-eq_hsTyVars env [] [] k = k env
-eq_hsTyVars env (tv1:tvs1) (tv2:tvs2) k = eq_hsTyVar env tv1 tv2 $ \ env ->
- eq_hsTyVars env tvs1 tvs2 k
-eq_hsTyVars env _ _ _ = False
-
-eq_hsTyVar env (UserTyVar v1) (UserTyVar v2) k = k (extendEqHsEnv env v1 v2)
-eq_hsTyVar env (IfaceTyVar v1 k1) (IfaceTyVar v2 k2) k = k1 `eqKind` k2 && k (extendEqHsEnv env v1 v2)
-eq_hsTyVar env _ _ _ = False
-
-eq_hsVars env [] [] k = k env
-eq_hsVars env (v1:bs1) (v2:bs2) k = eq_hsVars (extendEqHsEnv env v1 v2) bs1 bs2 k
-eq_hsVars env _ _ _ = False
-\end{code}
-
-\begin{code}
--------------------
-eq_hsTypes env = eqListBy (eq_hsType env)
-
--------------------
-eq_hsType env (HsForAllTy tvs1 c1 t1) (HsForAllTy tvs2 c2 t2)
- = eq_tvs tvs1 tvs2 $ \env ->
- eq_hsContext env c1 c2 &&
- eq_hsType env t1 t2
- where
- eq_tvs Nothing (Just _) k = False
- eq_tvs Nothing Nothing k = k env
- eq_tvs (Just _) Nothing k = False
- eq_tvs (Just tvs1) (Just tvs2) k = eq_hsTyVars env tvs1 tvs2 k
-
-eq_hsType env (HsTyVar n1) (HsTyVar n2)
- = eq_hsVar env n1 n2
-
-eq_hsType env (HsTupleTy c1 tys1) (HsTupleTy c2 tys2)
- = (c1 == c2) && eq_hsTypes env tys1 tys2
-
-eq_hsType env (HsListTy ty1) (HsListTy ty2)
- = eq_hsType env ty1 ty2
-
-eq_hsType env (HsKindSig ty1 k1) (HsKindSig ty2 k2)
- = eq_hsType env ty1 ty2 && k1 `eqKind` k2
-
-eq_hsType env (HsPArrTy ty1) (HsPArrTy ty2)
- = eq_hsType env ty1 ty2
-
-eq_hsType env (HsAppTy fun_ty1 arg_ty1) (HsAppTy fun_ty2 arg_ty2)
- = eq_hsType env fun_ty1 fun_ty2 && eq_hsType env arg_ty1 arg_ty2
-
-eq_hsType env (HsFunTy a1 b1) (HsFunTy a2 b2)
- = eq_hsType env a1 a2 && eq_hsType env b1 b2
-
-eq_hsType env (HsPredTy p1) (HsPredTy p2)
- = eq_hsPred env p1 p2
-
-eq_hsType env (HsOpTy lty1 op1 rty1) (HsOpTy lty2 op2 rty2)
- = eq_hsOp env op1 op2 && eq_hsType env lty1 lty2 && eq_hsType env rty1 rty2
-
-eq_hsType env ty1 ty2 = False
-
-
-eq_hsOp env (HsTyOp n1) (HsTyOp n2) = eq_hsVar env n1 n2
-eq_hsOp env HsArrow HsArrow = True
-eq_hsOp env op1 op2 = False
-
--------------------
-eq_hsContext env a b = eqListBy (eq_hsPred env) a b
-
--------------------
-eq_hsPred env (HsClassP c1 tys1) (HsClassP c2 tys2)
- = c1 == c2 && eq_hsTypes env tys1 tys2
-eq_hsPred env (HsIParam n1 ty1) (HsIParam n2 ty2)
- = n1 == n2 && eq_hsType env ty1 ty2
-eq_hsPred env _ _ = False
-\end{code}