X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=compiler%2Ftypecheck%2FTcSMonad.lhs;h=5f555c5b3290fc6efd41814d3c53021a4db0cdc1;hb=8657bb00544468adc7ad63e962af71674c3b4500;hp=93c795d33cbc05595c2c8e55fdddb9fdf0d174a0;hpb=201145f80c2c797badceabd0287cc7f5e98302aa;p=ghc-hetmet.git diff --git a/compiler/typecheck/TcSMonad.lhs b/compiler/typecheck/TcSMonad.lhs index 93c795d..5f555c5 100644 --- a/compiler/typecheck/TcSMonad.lhs +++ b/compiler/typecheck/TcSMonad.lhs @@ -4,12 +4,14 @@ module TcSMonad ( -- Canonical constraints CanonicalCts, emptyCCan, andCCan, andCCans, - singleCCan, extendCCans, isEmptyCCan, - CanonicalCt(..), Xi, tyVarsOfCanonical, tyVarsOfCanonicals, + singleCCan, extendCCans, isEmptyCCan, isTyEqCCan, + CanonicalCt(..), Xi, tyVarsOfCanonical, tyVarsOfCanonicals, tyVarsOfCDicts, mkWantedConstraints, deCanonicaliseWanted, - makeGivens, makeSolved, + makeGivens, makeSolvedByInst, - CtFlavor (..), isWanted, isGiven, isDerived, canRewrite, + CtFlavor (..), isWanted, isGiven, isDerived, isDerivedSC, isDerivedByInst, + DerivedOrig (..), + canRewrite, canSolve, combineCtLoc, mkGivenFlavor, TcS, runTcS, failTcS, panicTcS, traceTcS, traceTcS0, -- Basic functionality @@ -43,6 +45,7 @@ module TcSMonad ( isGoodRecEv, isTouchableMetaTyVar, + isTouchableMetaTyVar_InRange, getDefaultInfo, getDynFlags, @@ -141,8 +144,8 @@ data CanonicalCt | CTyEqCan { -- tv ~ xi (recall xi means function free) -- Invariant: -- * tv not in tvs(xi) (occurs check) - -- * If tv is a MetaTyVar, then typeKind xi <: typeKind tv - -- a skolem, then typeKind xi = typeKind tv + -- * If constraint is given then typeKind xi == typeKind tv + -- See Note [Spontaneous solving and kind compatibility] cc_id :: EvVar, cc_flavor :: CtFlavor, cc_tyvar :: TcTyVar, @@ -153,7 +156,8 @@ data CanonicalCt -- Invariant: * isSynFamilyTyCon cc_fun -- * cc_rhs is not a touchable unification variable -- See Note [No touchables as FunEq RHS] - -- * typeKind (TyConApp cc_fun cc_tyargs) == typeKind cc_rhs + -- * If constraint is given then + -- typeKind (TyConApp cc_fun cc_tyargs) == typeKind cc_rhs cc_id :: EvVar, cc_flavor :: CtFlavor, cc_fun :: TyCon, -- A type function @@ -168,12 +172,12 @@ makeGivens = mapBag (\ct -> ct { cc_flavor = mkGivenFlavor (cc_flavor ct) UnkSko -- The UnkSkol doesn't matter because these givens are -- not contradictory (else we'd have rejected them already) -makeSolved :: CanonicalCt -> CanonicalCt +makeSolvedByInst :: CanonicalCt -> CanonicalCt -- Record that a constraint is now solved -- Wanted -> Derived -- Given, Derived -> no-op -makeSolved ct - | Wanted loc <- cc_flavor ct = ct { cc_flavor = Derived loc } +makeSolvedByInst ct + | Wanted loc <- cc_flavor ct = ct { cc_flavor = Derived loc DerInst } | otherwise = ct mkWantedConstraints :: CanonicalCts -> Bag Implication -> WantedConstraints @@ -192,6 +196,13 @@ tyVarsOfCanonical (CFunEqCan { cc_tyargs = tys, cc_rhs = xi }) = tyVarsOfTypes ( tyVarsOfCanonical (CDictCan { cc_tyargs = tys }) = tyVarsOfTypes tys tyVarsOfCanonical (CIPCan { cc_ip_ty = ty }) = tyVarsOfType ty +tyVarsOfCDict :: CanonicalCt -> TcTyVarSet +tyVarsOfCDict (CDictCan { cc_tyargs = tys }) = tyVarsOfTypes tys +tyVarsOfCDict _ct = emptyVarSet + +tyVarsOfCDicts :: CanonicalCts -> TcTyVarSet +tyVarsOfCDicts = foldrBag (unionVarSet . tyVarsOfCDict) emptyVarSet + tyVarsOfCanonicals :: CanonicalCts -> TcTyVarSet tyVarsOfCanonicals = foldrBag (unionVarSet . tyVarsOfCanonical) emptyVarSet @@ -253,6 +264,12 @@ emptyCCan = emptyBag isEmptyCCan :: CanonicalCts -> Bool isEmptyCCan = isEmptyBag + +isTyEqCCan :: CanonicalCt -> Bool +isTyEqCCan (CTyEqCan {}) = True +isTyEqCCan (CFunEqCan {}) = False +isTyEqCCan _ = False + \end{code} %************************************************************************ @@ -265,16 +282,21 @@ isEmptyCCan = isEmptyBag \begin{code} data CtFlavor = Given GivenLoc -- We have evidence for this constraint in TcEvBinds - | Derived WantedLoc -- We have evidence for this constraint in TcEvBinds; + | Derived WantedLoc DerivedOrig + -- We have evidence for this constraint in TcEvBinds; -- *however* this evidence can contain wanteds, so -- it's valid only provisionally to the solution of -- these wanteds | Wanted WantedLoc -- We have no evidence bindings for this constraint. +data DerivedOrig = DerSC | DerInst +-- Deriveds are either superclasses of other wanteds or deriveds, or partially +-- solved wanteds from instances. + instance Outputable CtFlavor where - ppr (Given _) = ptext (sLit "[Given]") - ppr (Wanted _) = ptext (sLit "[Wanted]") - ppr (Derived _) = ptext (sLit "[Derived]") + ppr (Given _) = ptext (sLit "[Given]") + ppr (Wanted _) = ptext (sLit "[Wanted]") + ppr (Derived {}) = ptext (sLit "[Derived]") isWanted :: CtFlavor -> Bool isWanted (Wanted {}) = True @@ -288,27 +310,46 @@ isDerived :: CtFlavor -> Bool isDerived (Derived {}) = True isDerived _ = False +isDerivedSC :: CtFlavor -> Bool +isDerivedSC (Derived _ DerSC) = True +isDerivedSC _ = False + +isDerivedByInst :: CtFlavor -> Bool +isDerivedByInst (Derived _ DerInst) = True +isDerivedByInst _ = False + +canSolve :: CtFlavor -> CtFlavor -> Bool +-- canSolve ctid1 ctid2 +-- The constraint ctid1 can be used to solve ctid2 +-- "to solve" means a reaction where the active parts of the two constraints match. +-- active(F xis ~ xi) = F xis +-- active(tv ~ xi) = tv +-- active(D xis) = D xis +-- active(IP nm ty) = nm +----------------------------------------- +canSolve (Given {}) _ = True +canSolve (Derived {}) (Wanted {}) = True +canSolve (Derived {}) (Derived {}) = True +canSolve (Wanted {}) (Wanted {}) = True +canSolve _ _ = False + canRewrite :: CtFlavor -> CtFlavor -> Bool -- canRewrite ctid1 ctid2 --- The constraint ctid1 can be used to rewrite ctid2 -canRewrite (Given {}) _ = True -canRewrite (Derived {}) (Wanted {}) = True -canRewrite (Derived {}) (Derived {}) = True -canRewrite (Wanted {}) (Wanted {}) = True -canRewrite _ _ = False +-- The *equality_constraint* ctid1 can be used to rewrite inside ctid2 +canRewrite = canSolve combineCtLoc :: CtFlavor -> CtFlavor -> WantedLoc -- Precondition: At least one of them should be wanted -combineCtLoc (Wanted loc) _ = loc -combineCtLoc _ (Wanted loc) = loc -combineCtLoc (Derived loc) _ = loc -combineCtLoc _ (Derived loc) = loc +combineCtLoc (Wanted loc) _ = loc +combineCtLoc _ (Wanted loc) = loc +combineCtLoc (Derived loc _) _ = loc +combineCtLoc _ (Derived loc _) = loc combineCtLoc _ _ = panic "combineCtLoc: both given" mkGivenFlavor :: CtFlavor -> SkolemInfo -> CtFlavor -mkGivenFlavor (Wanted loc) sk = Given (setCtLocOrigin loc sk) -mkGivenFlavor (Derived loc) sk = Given (setCtLocOrigin loc sk) -mkGivenFlavor (Given loc) sk = Given (setCtLocOrigin loc sk) +mkGivenFlavor (Wanted loc) sk = Given (setCtLocOrigin loc sk) +mkGivenFlavor (Derived loc _) sk = Given (setCtLocOrigin loc sk) +mkGivenFlavor (Given loc) sk = Given (setCtLocOrigin loc sk) \end{code} @@ -566,41 +607,90 @@ pprEq :: TcType -> TcType -> SDoc pprEq ty1 ty2 = pprPred $ mkEqPred (ty1,ty2) isTouchableMetaTyVar :: TcTyVar -> TcS Bool --- is touchable variable! isTouchableMetaTyVar tv - | isMetaTyVar tv = do { untch <- getUntouchables - ; return (inTouchableRange untch tv) } - | otherwise = return False + = do { untch <- getUntouchables + ; return $ isTouchableMetaTyVar_InRange untch tv } + +isTouchableMetaTyVar_InRange :: Untouchables -> TcTyVar -> Bool +isTouchableMetaTyVar_InRange untch tv + = case tcTyVarDetails tv of + MetaTv TcsTv _ -> True -- See Note [Touchable meta type variables] + MetaTv {} -> inTouchableRange untch tv + _ -> False + + +\end{code} + + +Note [Touchable meta type variables] +~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ +Meta type variables allocated *by the constraint solver itself* are always +touchable. Example: + instance C a b => D [a] where... +if we use this instance declaration we "make up" a fresh meta type +variable for 'b', which we must later guess. (Perhaps C has a +functional dependency.) But since we aren't in the constraint *generator* +we can't allocate a Unique in the touchable range for this implication +constraint. Instead, we mark it as a "TcsTv", which makes it always-touchable. +\begin{code} -- Flatten skolems -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ newFlattenSkolemTy :: TcType -> TcS TcType newFlattenSkolemTy ty = mkTyVarTy <$> newFlattenSkolemTyVar ty - where newFlattenSkolemTyVar :: TcType -> TcS TcTyVar - newFlattenSkolemTyVar ty - = wrapTcS $ do { uniq <- TcM.newUnique - ; let name = mkSysTvName uniq (fsLit "f") - ; return $ - mkTcTyVar name (typeKind ty) (FlatSkol ty) - } + +newFlattenSkolemTyVar :: TcType -> TcS TcTyVar +newFlattenSkolemTyVar ty + = wrapTcS $ do { uniq <- TcM.newUnique + ; let name = mkSysTvName uniq (fsLit "f") + ; return $ mkTcTyVar name (typeKind ty) (FlatSkol ty) } -- Instantiations -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ instDFunTypes :: [Either TyVar TcType] -> TcS [TcType] -instDFunTypes mb_inst_tys = - let inst_tv :: Either TyVar TcType -> TcS Type - inst_tv (Left tv) = wrapTcS $ TcM.tcInstTyVar tv >>= return . mkTyVarTy - inst_tv (Right ty) = return ty - in mapM inst_tv mb_inst_tys - +instDFunTypes mb_inst_tys + = mapM inst_tv mb_inst_tys + where + inst_tv :: Either TyVar TcType -> TcS Type + inst_tv (Left tv) = mkTyVarTy <$> newFlexiTcS tv + inst_tv (Right ty) = return ty instDFunConstraints :: TcThetaType -> TcS [EvVar] instDFunConstraints preds = wrapTcS $ TcM.newWantedEvVars preds +-- newFlexiTcS :: TyVar -> TcS TcTyVar +-- -- Make a TcsTv meta tyvar; it is always touchable, +-- -- but we are supposed to guess its instantiation +-- -- See Note [Touchable meta type variables] +-- newFlexiTcS tv = wrapTcS $ TcM.instMetaTyVar TcsTv tv + +newFlexiTcS :: TyVar -> TcS TcTyVar +-- Like TcM.instMetaTyVar but the variable that is created is always +-- touchable; we are supposed to guess its instantiation. +-- See Note [Touchable meta type variables] +newFlexiTcS tv = newFlexiTcSHelper (tyVarName tv) (tyVarKind tv) + +newKindConstraint :: TcTyVar -> Kind -> TcS (CoVar, Type) +-- Create new wanted CoVar that constrains the type to have the specified kind. +newKindConstraint tv knd + = do { tv_k <- newFlexiTcSHelper (tyVarName tv) knd + ; let ty_k = mkTyVarTy tv_k + ; co_var <- newWantedCoVar (mkTyVarTy tv) ty_k + ; return (co_var, ty_k) } + +newFlexiTcSHelper :: Name -> Kind -> TcS TcTyVar +newFlexiTcSHelper tvname tvkind + = wrapTcS $ + do { uniq <- TcM.newUnique + ; ref <- TcM.newMutVar Flexi + ; let name = setNameUnique tvname uniq + kind = tvkind + ; return (mkTcTyVar name kind (MetaTv TcsTv ref)) } + -- Superclasses and recursive dictionaries -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ @@ -623,8 +713,6 @@ newGivOrDerCoVar ty1 ty2 co newWantedCoVar :: TcType -> TcType -> TcS EvVar newWantedCoVar ty1 ty2 = wrapTcS $ TcM.newWantedCoVar ty1 ty2 -newKindConstraint :: TcType -> Kind -> TcS (CoVar, TcType) -newKindConstraint ty kind = wrapTcS $ TcM.newKindConstraint ty kind newCoVar :: TcType -> TcType -> TcS EvVar newCoVar ty1 ty2 = wrapTcS $ TcM.newCoVar ty1 ty2 @@ -800,11 +888,13 @@ mkWantedFunDepEqns loc eqns where to_work_item :: (Equation, (PredType,SDoc), (PredType,SDoc)) -> TcS [WantedEvVar] to_work_item ((qtvs, pairs), _, _) - = do { (_, _, tenv) <- wrapTcS $ TcM.tcInstTyVars (varSetElems qtvs) - ; mapM (do_one tenv) pairs } + = do { let tvs = varSetElems qtvs + ; tvs' <- mapM newFlexiTcS tvs + ; let subst = zipTopTvSubst tvs (mkTyVarTys tvs') + ; mapM (do_one subst) pairs } - do_one tenv (ty1, ty2) = do { let sty1 = substTy tenv ty1 - sty2 = substTy tenv ty2 + do_one subst (ty1, ty2) = do { let sty1 = substTy subst ty1 + sty2 = substTy subst ty2 ; ev <- newWantedCoVar sty1 sty2 ; return (WantedEvVar ev loc) }