#include "HsVersions.h"
-import HsSyn ( Pat(..), LPat, HsConDetails(..), HsLit(..), HsOverLit(..),
- HsExpr(..), LHsBinds, emptyLHsBinds, isEmptyLHsBinds )
-import HsUtils
+import {-# SOURCE #-} TcExpr( tcSyntaxOp )
+import HsSyn ( Pat(..), LPat, HsConDetails(..),
+ LHsBinds, emptyLHsBinds, isEmptyLHsBinds )
import TcHsSyn ( TcId, hsLitType )
import TcRnMonad
-import Inst ( InstOrigin(..),
- newMethodFromName, newOverloadedLit, newDicts,
- instToId, tcInstStupidTheta, tcSyntaxName
+import Inst ( InstOrigin(..), tcOverloadedLit,
+ newDicts, instToId, tcInstStupidTheta
)
import Id ( Id, idType, mkLocalId )
+import Var ( tyVarName )
import Name ( Name )
import TcSimplify ( tcSimplifyCheck, bindInstsOfLocalFuns )
import TcEnv ( newLocalName, tcExtendIdEnv1, tcExtendTyVarEnv2,
tcLookupClass, tcLookupDataCon, tcLookupId )
import TcMType ( newTyFlexiVarTy, arityErr, tcSkolTyVars, readMetaTyVar )
import TcType ( TcType, TcTyVar, TcSigmaType, TcTauType, zipTopTvSubst,
- SkolemInfo(PatSkol), isSkolemTyVar, pprSkolemTyVar,
- TvSubst, mkTvSubst, substTyVar, substTy, MetaDetails(..),
- mkTyVarTys, mkClassPred, mkTyConApp, isOverloadedTy )
+ SkolemInfo(PatSkol), isMetaTyVar, pprTcTyVar,
+ TvSubst, mkOpenTvSubst, substTyVar, substTy, MetaDetails(..),
+ mkTyVarTys, mkClassPred, mkTyConApp, isOverloadedTy,
+ mkFunTy, mkFunTys )
import VarEnv ( mkVarEnv ) -- ugly
import Kind ( argTypeKind, liftedTypeKind )
import TcUnify ( tcSubPat, Expected(..), zapExpectedType,
zapExpectedTo, zapToListTy, zapToTyConApp )
import TcHsType ( UserTypeCtxt(..), TcSigInfo( sig_tau ), TcSigFun, tcHsPatSigType )
-import TysWiredIn ( stringTy, parrTyCon, tupleTyCon )
-import Unify ( MaybeErr(..), gadtRefineTys, gadtMatchTys )
+import TysWiredIn ( boolTy, parrTyCon, tupleTyCon )
+import Unify ( MaybeErr(..), gadtRefineTys, BindFlag(..) )
import Type ( substTys, substTheta )
-import CmdLineOpts ( opt_IrrefutableTuples )
+import StaticFlags ( opt_IrrefutableTuples )
import TyCon ( TyCon )
import DataCon ( DataCon, dataConTyCon, isVanillaDataCon, dataConInstOrigArgTys,
dataConFieldLabels, dataConSourceArity, dataConSig )
-import PrelNames ( eqStringName, eqName, geName, negateName, minusName,
- integralClassName )
+import PrelNames ( integralClassName )
import BasicTypes ( isBoxed )
import SrcLoc ( Located(..), SrcSpan, noLoc, unLoc )
import Maybes ( catMaybes )
%************************************************************************
\begin{code}
-data PatCtxt = LamPat Bool -- Used for lambda, case, do-notation etc
+data PatCtxt = LamPat -- Used for lambda, case, do-notation etc
| LetPat TcSigFun -- Used for let(rec) bindings
- -- True <=> we are checking the case expression,
- -- so can do full-blown refinement
- -- False <=> inferring, do no refinement
-------------------
tcPatBndr :: PatCtxt -> Name -> Expected TcSigmaType -> TcM TcId
-tcPatBndr (LamPat _) bndr_name pat_ty
+tcPatBndr LamPat bndr_name pat_ty
= do { pat_ty' <- zapExpectedType pat_ty argTypeKind
-- If pat_ty is Expected, this returns the appropriate
-- SigmaType. In Infer mode, we create a fresh type variable.
(sig_tvs, sig_ty) <- tcHsPatSigType PatSigCtxt sig
; tcSubPat sig_ty pat_ty
; subst <- refineTyVars sig_tvs -- See note [Type matching]
- ; let tv_binds = [(tv, substTyVar subst tv) | tv <- sig_tvs]
+ ; let tv_binds = [(tyVarName tv, substTyVar subst tv) | tv <- sig_tvs]
sig_ty' = substTy subst sig_ty
; (pat', tvs, res)
<- tcExtendTyVarEnv2 tv_binds $
; (pat', tvs, res) <- tcConPat ctxt con_span data_con tycon ty_args arg_pats thing_inside
; return (pat', tvs, res) }
-
------------------------
-- Literal patterns
-tc_pat ctxt pat@(LitPat lit@(HsString _)) pat_ty thing_inside
- = do { -- Strings are mapped to NPatOuts, which have a guard expression
- zapExpectedTo pat_ty stringTy
- ; eq_id <- tcLookupId eqStringName
- ; res <- thing_inside
- ; returnM (NPatOut lit stringTy (nlHsVar eq_id `HsApp` nlHsLit lit), [], res) }
-
tc_pat ctxt (LitPat simple_lit) pat_ty thing_inside
= do { -- All other simple lits
zapExpectedTo pat_ty (hsLitType simple_lit)
------------------------
-- Overloaded patterns: n, and n+k
-tc_pat ctxt pat@(NPatIn over_lit mb_neg) pat_ty thing_inside
+tc_pat ctxt pat@(NPat over_lit mb_neg eq _) pat_ty thing_inside
= do { pat_ty' <- zapExpectedType pat_ty liftedTypeKind
- ; let origin = LiteralOrigin over_lit
- ; pos_lit_expr <- newOverloadedLit origin over_lit pat_ty'
- ; eq <- newMethodFromName origin pat_ty' eqName
- ; lit_expr <- case mb_neg of
- Nothing -> returnM pos_lit_expr -- Positive literal
+ ; let orig = LiteralOrigin over_lit
+ ; lit' <- tcOverloadedLit orig over_lit pat_ty'
+ ; eq' <- tcSyntaxOp orig eq (mkFunTys [pat_ty', pat_ty'] boolTy)
+ ; mb_neg' <- case mb_neg of
+ Nothing -> return Nothing -- Positive literal
Just neg -> -- Negative literal
-- The 'negate' is re-mappable syntax
- do { (_, neg_expr) <- tcSyntaxName origin pat_ty'
- (negateName, HsVar neg)
- ; returnM (mkHsApp (noLoc neg_expr) pos_lit_expr) }
-
- ; let -- The literal in an NPatIn is always positive...
- -- But in NPatOut, the literal is used to find identical patterns
- -- so we must negate the literal when necessary!
- lit' = case (over_lit, mb_neg) of
- (HsIntegral i _, Nothing) -> HsInteger i pat_ty'
- (HsIntegral i _, Just _) -> HsInteger (-i) pat_ty'
- (HsFractional f _, Nothing) -> HsRat f pat_ty'
- (HsFractional f _, Just _) -> HsRat (-f) pat_ty'
-
+ do { neg' <- tcSyntaxOp orig neg (mkFunTy pat_ty' pat_ty')
+ ; return (Just neg') }
; res <- thing_inside
- ; returnM (NPatOut lit' pat_ty' (HsApp (nlHsVar eq) lit_expr), [], res) }
+ ; returnM (NPat lit' mb_neg' eq' pat_ty', [], res) }
-tc_pat ctxt pat@(NPlusKPatIn (L nm_loc name) lit@(HsIntegral i _) minus_name) pat_ty thing_inside
+tc_pat ctxt pat@(NPlusKPat (L nm_loc name) lit ge minus) pat_ty thing_inside
= do { bndr_id <- setSrcSpan nm_loc (tcPatBndr ctxt name pat_ty)
; let pat_ty' = idType bndr_id
- origin = LiteralOrigin lit
- ; over_lit_expr <- newOverloadedLit origin lit pat_ty'
- ; ge <- newMethodFromName origin pat_ty' geName
+ orig = LiteralOrigin lit
+ ; lit' <- tcOverloadedLit orig lit pat_ty'
- -- The '-' part is re-mappable syntax
- ; (_, minus_expr) <- tcSyntaxName origin pat_ty' (minusName, HsVar minus_name)
+ -- The '>=' and '-' parts are re-mappable syntax
+ ; ge' <- tcSyntaxOp orig ge (mkFunTys [pat_ty', pat_ty'] boolTy)
+ ; minus' <- tcSyntaxOp orig minus (mkFunTys [pat_ty', pat_ty'] pat_ty')
-- The Report says that n+k patterns must be in Integral
-- We may not want this when using re-mappable syntax, though (ToDo?)
; icls <- tcLookupClass integralClassName
- ; dicts <- newDicts origin [mkClassPred icls [pat_ty']]
+ ; dicts <- newDicts orig [mkClassPred icls [pat_ty']]
; extendLIEs dicts
; res <- tcExtendIdEnv1 name bndr_id thing_inside
- ; returnM (NPlusKPatOut (L nm_loc bndr_id) i
- (SectionR (nlHsVar ge) over_lit_expr)
- (SectionR (noLoc minus_expr) over_lit_expr),
- [], res) }
+ ; returnM (NPlusKPat (L nm_loc bndr_id) lit' ge' minus', [], res) }
\end{code}
-> TcM a -> TcM a
refineAlt ctxt con ex_tvs ctxt_tys pat_tys thing_inside
= do { old_subst <- getTypeRefinement
- ; let refiner | can_i_refine ctxt = gadtRefineTys
- | otherwise = gadtMatchTys
- ; case refiner ex_tvs old_subst pat_tys ctxt_tys of
+ ; case gadtRefineTys bind_fn old_subst pat_tys ctxt_tys of
Failed msg -> failWithTc (inaccessibleAlt msg)
Succeeded new_subst -> do {
traceTc (text "refineTypes:match" <+> ppr con <+> ppr new_subst)
; setTypeRefinement new_subst thing_inside } }
where
- can_i_refine (LamPat can_refine) = can_refine
- can_i_refine other_ctxt = False
+ bind_fn tv | isMetaTyVar tv = WildCard -- Wobbly types behave as wild cards
+ | otherwise = BindMe
\end{code}
Note [Type matching]
-- Just one level of de-wobblification though. What a hack!
refineTyVars tvs
= do { mb_prs <- mapM mk_pr tvs
- ; return (mkTvSubst (mkVarEnv (catMaybes mb_prs))) }
+ ; return (mkOpenTvSubst (mkVarEnv (catMaybes mb_prs))) }
where
mk_pr tv = do { details <- readMetaTyVar tv
; case details of
lazyPatErr pat tvs
= failWithTc $
hang (ptext SLIT("A lazy (~) pattern connot bind existential type variables"))
- 2 (vcat (map get tvs))
- where
- get tv = ASSERT( isSkolemTyVar tv ) pprSkolemTyVar tv
+ 2 (vcat (map pprTcTyVar tvs))
inaccessibleAlt msg
= hang (ptext SLIT("Inaccessible case alternative:")) 2 msg