% % (c) The University of Glasgow 2006 % (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 % TcInstDecls: Typechecking instance declarations \begin{code} module TcInstDcls ( tcInstDecls1, tcInstDecls2 ) where import HsSyn import TcBinds import TcTyClsDecls import TcClassDcl import TcRnMonad import TcMType import TcType import Inst import InstEnv import FamInst import FamInstEnv import TcDeriv import TcEnv import RnSource ( addTcgDUs ) import TcHsType import TcUnify import TcSimplify import Type import Coercion import TyCon import DataCon import Class import Var import CoreUnfold ( mkDFunUnfolding ) import CoreSyn ( Expr(Var) ) import Id import MkId import Name import NameSet import DynFlags import SrcLoc import Util import Outputable import Bag import BasicTypes import HscTypes import FastString import Data.Maybe import Control.Monad import Data.List #include "HsVersions.h" \end{code} Typechecking instance declarations is done in two passes. The first pass, made by @tcInstDecls1@, collects information to be used in the second pass. This pre-processed info includes the as-yet-unprocessed bindings inside the instance declaration. These are type-checked in the second pass, when the class-instance envs and GVE contain all the info from all the instance and value decls. Indeed that's the reason we need two passes over the instance decls. Note [How instance declarations are translated] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Here is how we translation instance declarations into Core Running example: class C a where op1, op2 :: Ix b => a -> b -> b op2 = instance C a => C [a] {-# INLINE [2] op1 #-} op1 = ===> -- Method selectors op1,op2 :: forall a. C a => forall b. Ix b => a -> b -> b op1 = ... op2 = ... -- Default methods get the 'self' dictionary as argument -- so they can call other methods at the same type -- Default methods get the same type as their method selector $dmop2 :: forall a. C a => forall b. Ix b => a -> b -> b $dmop2 = /\a. \(d:C a). /\b. \(d2: Ix b). -- NB: type variables 'a' and 'b' are *both* in scope in -- Note [Tricky type variable scoping] -- A top-level definition for each instance method -- Here op1_i, op2_i are the "instance method Ids" -- The INLINE pragma comes from the user pragma {-# INLINE [2] op1_i #-} -- From the instance decl bindings op1_i, op2_i :: forall a. C a => forall b. Ix b => [a] -> b -> b op1_i = /\a. \(d:C a). let this :: C [a] this = df_i a d -- Note [Subtle interaction of recursion and overlap] local_op1 :: forall b. Ix b => [a] -> b -> b local_op1 = -- Source code; run the type checker on this -- NB: Type variable 'a' (but not 'b') is in scope in -- Note [Tricky type variable scoping] in local_op1 a d op2_i = /\a \d:C a. $dmop2 [a] (df_i a d) -- The dictionary function itself {-# NOINLINE CONLIKE df_i #-} -- Never inline dictionary functions df_i :: forall a. C a -> C [a] df_i = /\a. \d:C a. MkC (op1_i a d) (op2_i a d) -- But see Note [Default methods in instances] -- We can't apply the type checker to the default-method call -- Use a RULE to short-circuit applications of the class ops {-# RULE "op1@C[a]" forall a, d:C a. op1 [a] (df_i d) = op1_i a d #-} Note [Instances and loop breakers] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * Note that df_i may be mutually recursive with both op1_i and op2_i. It's crucial that df_i is not chosen as the loop breaker, even though op1_i has a (user-specified) INLINE pragma. * Instead the idea is to inline df_i into op1_i, which may then select methods from the MkC record, and thereby break the recursion with df_i, leaving a *self*-recurisve op1_i. (If op1_i doesn't call op at the same type, it won't mention df_i, so there won't be recursion in the first place.) * If op1_i is marked INLINE by the user there's a danger that we won't inline df_i in it, and that in turn means that (since it'll be a loop-breaker because df_i isn't), op1_i will ironically never be inlined. But this is OK: the recursion breaking happens by way of a RULE (the magic ClassOp rule above), and RULES work inside InlineRule unfoldings. See Note [RULEs enabled in SimplGently] in SimplUtils Note [ClassOp/DFun selection] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ One thing we see a lot is stuff like op2 (df d1 d2) where 'op2' is a ClassOp and 'df' is DFun. Now, we could inline *both* 'op2' and 'df' to get case (MkD ($cop1 d1 d2) ($cop2 d1 d2) ... of MkD _ op2 _ _ _ -> op2 And that will reduce to ($cop2 d1 d2) which is what we wanted. But it's tricky to make this work in practice, because it requires us to inline both 'op2' and 'df'. But neither is keen to inline without having seen the other's result; and it's very easy to get code bloat (from the big intermediate) if you inline a bit too much. Instead we use a cunning trick. * We arrange that 'df' and 'op2' NEVER inline. * We arrange that 'df' is ALWAYS defined in the sylised form df d1 d2 = MkD ($cop1 d1 d2) ($cop2 d1 d2) ... * We give 'df' a magical unfolding (DFunUnfolding [$cop1, $cop2, ..]) that lists its methods. * We make CoreUnfold.exprIsConApp_maybe spot a DFunUnfolding and return a suitable constructor application -- inlining df "on the fly" as it were. * We give the ClassOp 'op2' a BuiltinRule that extracts the right piece iff its argument satisfies exprIsConApp_maybe. This is done in MkId mkDictSelId * We make 'df' CONLIKE, so that shared uses stil match; eg let d = df d1 d2 in ...(op2 d)...(op1 d)... Note [Single-method classes] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If the class has just one method (or, more accurately, just one element of {superclasses + methods}), then we still use the *same* strategy class C a where op :: a -> a instance C a => C [a] where op = We translate the class decl into a newtype, which just gives a top-level axiom: axiom Co:C a :: C a ~ (a->a) op :: forall a. C a -> (a -> a) op a d = d |> (Co:C a) MkC :: forall a. (a->a) -> C a MkC = /\a.\op. op |> (sym Co:C a) df :: forall a. C a => C [a] {-# NOINLINE df DFun[ $cop_list ] #-} df = /\a. \d. MkC ($cop_list a d) $cop_list :: forall a. C a => [a] -> [a] $cop_list = The "constructor" MkC expands to a cast, as does the class-op selector. The RULE works just like for multi-field dictionaries: * (df a d) returns (Just (MkC,..,[$cop_list a d])) to exprIsConApp_Maybe * The RULE for op picks the right result This is a bit of a hack, because (df a d) isn't *really* a constructor application. But it works just fine in this case, exprIsConApp_maybe is otherwise used only when we hit a case expression which will have a real data constructor in it. The biggest reason for doing it this way, apart from uniformity, is that we want to be very careful when we have instance C a => C [a] where {-# INLINE op #-} op = ... then we'll get an INLINE pragma on $cop_list but it's important that $cop_list only inlines when it's applied to *two* arguments (the dictionary and the list argument The danger is that we'll get something like op_list :: C a => [a] -> [a] op_list = /\a.\d. $cop_list a d and then we'll eta expand, and then we'll inline TOO EARLY. This happened in Trac #3772 and I spent far too long fiddling around trying to fix it. Look at the test for Trac #3772. (Note: re-reading the above, I can't see how using the uniform story solves the problem.) Note [Subtle interaction of recursion and overlap] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this class C a where { op1,op2 :: a -> a } instance C a => C [a] where op1 x = op2 x ++ op2 x op2 x = ... intance C [Int] where ... When type-checking the C [a] instance, we need a C [a] dictionary (for the call of op2). If we look up in the instance environment, we find an overlap. And in *general* the right thing is to complain (see Note [Overlapping instances] in InstEnv). But in *this* case it's wrong to complain, because we just want to delegate to the op2 of this same instance. Why is this justified? Because we generate a (C [a]) constraint in a context in which 'a' cannot be instantiated to anything that matches other overlapping instances, or else we would not be excecuting this version of op1 in the first place. It might even be a bit disguised: nullFail :: C [a] => [a] -> [a] nullFail x = op2 x ++ op2 x instance C a => C [a] where op1 x = nullFail x Precisely this is used in package 'regex-base', module Context.hs. See the overlapping instances for RegexContext, and the fact that they call 'nullFail' just like the example above. The DoCon package also does the same thing; it shows up in module Fraction.hs Conclusion: when typechecking the methods in a C [a] instance, we want to have C [a] available. That is why we have the strange local definition for 'this' in the definition of op1_i in the example above. We can typecheck the defintion of local_op1, and when doing tcSimplifyCheck we supply 'this' as a given dictionary. Only needed, though, if there are some type variables involved; otherwise there can be no overlap and none of this arises. Note [Tricky type variable scoping] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In our example class C a where op1, op2 :: Ix b => a -> b -> b op2 = instance C a => C [a] {-# INLINE [2] op1 #-} op1 = note that 'a' and 'b' are *both* in scope in , but only 'a' is in scope in . In particular, we must make sure that 'b' is in scope when typechecking . This is achieved by subFunTys, which brings appropriate tyvars into scope. This happens for both and for , but that doesn't matter: the *renamer* will have complained if 'b' is mentioned in . %************************************************************************ %* * \subsection{Extracting instance decls} %* * %************************************************************************ Gather up the instance declarations from their various sources \begin{code} tcInstDecls1 -- Deal with both source-code and imported instance decls :: [LTyClDecl Name] -- For deriving stuff -> [LInstDecl Name] -- Source code instance decls -> [LDerivDecl Name] -- Source code stand-alone deriving decls -> TcM (TcGblEnv, -- The full inst env [InstInfo Name], -- Source-code instance decls to process; -- contains all dfuns for this module HsValBinds Name) -- Supporting bindings for derived instances tcInstDecls1 tycl_decls inst_decls deriv_decls = checkNoErrs $ do { -- Stop if addInstInfos etc discovers any errors -- (they recover, so that we get more than one error each -- round) -- (1) Do class and family instance declarations ; idx_tycons <- mapAndRecoverM (tcFamInstDecl TopLevel) $ filter (isFamInstDecl . unLoc) tycl_decls ; local_info_tycons <- mapAndRecoverM tcLocalInstDecl1 inst_decls ; let { (local_info, at_tycons_s) = unzip local_info_tycons ; at_idx_tycons = concat at_tycons_s ++ idx_tycons ; clas_decls = filter (isClassDecl.unLoc) tycl_decls ; implicit_things = concatMap implicitTyThings at_idx_tycons ; aux_binds = mkRecSelBinds at_idx_tycons } -- (2) Add the tycons of indexed types and their implicit -- tythings to the global environment ; tcExtendGlobalEnv (at_idx_tycons ++ implicit_things) $ do { -- (3) Instances from generic class declarations ; generic_inst_info <- getGenericInstances clas_decls -- Next, construct the instance environment so far, consisting -- of -- (a) local instance decls -- (b) generic instances -- (c) local family instance decls ; addInsts local_info $ addInsts generic_inst_info $ addFamInsts at_idx_tycons $ do { -- (4) Compute instances from "deriving" clauses; -- This stuff computes a context for the derived instance -- decl, so it needs to know about all the instances possible -- NB: class instance declarations can contain derivings as -- part of associated data type declarations failIfErrsM -- If the addInsts stuff gave any errors, don't -- try the deriving stuff, becuase that may give -- more errors still ; (deriv_inst_info, deriv_binds, deriv_dus) <- tcDeriving tycl_decls inst_decls deriv_decls ; gbl_env <- addInsts deriv_inst_info getGblEnv ; return ( addTcgDUs gbl_env deriv_dus, generic_inst_info ++ deriv_inst_info ++ local_info, aux_binds `plusHsValBinds` deriv_binds) }}} addInsts :: [InstInfo Name] -> TcM a -> TcM a addInsts infos thing_inside = tcExtendLocalInstEnv (map iSpec infos) thing_inside addFamInsts :: [TyThing] -> TcM a -> TcM a addFamInsts tycons thing_inside = tcExtendLocalFamInstEnv (map mkLocalFamInstTyThing tycons) thing_inside where mkLocalFamInstTyThing (ATyCon tycon) = mkLocalFamInst tycon mkLocalFamInstTyThing tything = pprPanic "TcInstDcls.addFamInsts" (ppr tything) \end{code} \begin{code} tcLocalInstDecl1 :: LInstDecl Name -> TcM (InstInfo Name, [TyThing]) -- A source-file instance declaration -- Type-check all the stuff before the "where" -- -- We check for respectable instance type, and context tcLocalInstDecl1 (L loc (InstDecl poly_ty binds uprags ats)) = setSrcSpan loc $ addErrCtxt (instDeclCtxt1 poly_ty) $ do { is_boot <- tcIsHsBoot ; checkTc (not is_boot || (isEmptyLHsBinds binds && null uprags)) badBootDeclErr ; (tyvars, theta, tau) <- tcHsInstHead poly_ty -- Now, check the validity of the instance. ; (clas, inst_tys) <- checkValidInstance poly_ty tyvars theta tau -- Next, process any associated types. ; idx_tycons <- recoverM (return []) $ do { idx_tycons <- checkNoErrs $ mapAndRecoverM (tcFamInstDecl NotTopLevel) ats ; checkValidAndMissingATs clas (tyvars, inst_tys) (zip ats idx_tycons) ; return idx_tycons } -- Finally, construct the Core representation of the instance. -- (This no longer includes the associated types.) ; dfun_name <- newDFunName clas inst_tys (getLoc poly_ty) -- Dfun location is that of instance *header* ; overlap_flag <- getOverlapFlag ; let (eq_theta,dict_theta) = partition isEqPred theta theta' = eq_theta ++ dict_theta dfun = mkDictFunId dfun_name tyvars theta' clas inst_tys ispec = mkLocalInstance dfun overlap_flag ; return (InstInfo { iSpec = ispec, iBinds = VanillaInst binds uprags False }, idx_tycons) } where -- We pass in the source form and the type checked form of the ATs. We -- really need the source form only to be able to produce more informative -- error messages. checkValidAndMissingATs :: Class -> ([TyVar], [TcType]) -- instance types -> [(LTyClDecl Name, -- source form of AT TyThing)] -- Core form of AT -> TcM () checkValidAndMissingATs clas inst_tys ats = do { -- Issue a warning for each class AT that is not defined in this -- instance. ; let class_ats = map tyConName (classATs clas) defined_ats = listToNameSet . map (tcdName.unLoc.fst) $ ats omitted = filterOut (`elemNameSet` defined_ats) class_ats ; warn <- doptM Opt_WarnMissingMethods ; mapM_ (warnTc warn . omittedATWarn) omitted -- Ensure that all AT indexes that correspond to class parameters -- coincide with the types in the instance head. All remaining -- AT arguments must be variables. Also raise an error for any -- type instances that are not associated with this class. ; mapM_ (checkIndexes clas inst_tys) ats } checkIndexes clas inst_tys (hsAT, ATyCon tycon) -- !!!TODO: check that this does the Right Thing for indexed synonyms, too! = checkIndexes' clas inst_tys hsAT (tyConTyVars tycon, snd . fromJust . tyConFamInst_maybe $ tycon) checkIndexes _ _ _ = panic "checkIndexes" checkIndexes' clas (instTvs, instTys) hsAT (atTvs, atTys) = let atName = tcdName . unLoc $ hsAT in setSrcSpan (getLoc hsAT) $ addErrCtxt (atInstCtxt atName) $ case find ((atName ==) . tyConName) (classATs clas) of Nothing -> addErrTc $ badATErr clas atName -- not in this class Just atycon -> case assocTyConArgPoss_maybe atycon of Nothing -> panic "checkIndexes': AT has no args poss?!?" Just poss -> -- The following is tricky! We need to deal with three -- complications: (1) The AT possibly only uses a subset of -- the class parameters as indexes and those it uses may be in -- a different order; (2) the AT may have extra arguments, -- which must be type variables; and (3) variables in AT and -- instance head will be different `Name's even if their -- source lexemes are identical. -- -- e.g. class C a b c where -- data D b a :: * -> * -- NB (1) b a, omits c -- instance C [x] Bool Char where -- data D Bool [x] v = MkD x [v] -- NB (2) v -- -- NB (3) the x in 'instance C...' have differnt -- -- Names to x's in 'data D...' -- -- Re (1), `poss' contains a permutation vector to extract the -- class parameters in the right order. -- -- Re (2), we wrap the (permuted) class parameters in a Maybe -- type and use Nothing for any extra AT arguments. (First -- equation of `checkIndex' below.) -- -- Re (3), we replace any type variable in the AT parameters -- that has the same source lexeme as some variable in the -- instance types with the instance type variable sharing its -- source lexeme. -- let relevantInstTys = map (instTys !!) poss instArgs = map Just relevantInstTys ++ repeat Nothing -- extra arguments renaming = substSameTyVar atTvs instTvs in zipWithM_ checkIndex (substTys renaming atTys) instArgs checkIndex ty Nothing | isTyVarTy ty = return () | otherwise = addErrTc $ mustBeVarArgErr ty checkIndex ty (Just instTy) | ty `tcEqType` instTy = return () | otherwise = addErrTc $ wrongATArgErr ty instTy listToNameSet = addListToNameSet emptyNameSet substSameTyVar [] _ = emptyTvSubst substSameTyVar (tv:tvs) replacingTvs = let replacement = case find (tv `sameLexeme`) replacingTvs of Nothing -> mkTyVarTy tv Just rtv -> mkTyVarTy rtv -- tv1 `sameLexeme` tv2 = nameOccName (tyVarName tv1) == nameOccName (tyVarName tv2) in extendTvSubst (substSameTyVar tvs replacingTvs) tv replacement \end{code} %************************************************************************ %* * Type-checking instance declarations, pass 2 %* * %************************************************************************ \begin{code} tcInstDecls2 :: [LTyClDecl Name] -> [InstInfo Name] -> TcM (LHsBinds Id) -- (a) From each class declaration, -- generate any default-method bindings -- (b) From each instance decl -- generate the dfun binding tcInstDecls2 tycl_decls inst_decls = do { -- (a) Default methods from class decls let class_decls = filter (isClassDecl . unLoc) tycl_decls ; dm_binds_s <- mapM tcClassDecl2 class_decls ; let dm_binds = unionManyBags dm_binds_s -- (b) instance declarations ; let dm_ids = collectHsBindsBinders dm_binds -- Add the default method Ids (again) -- See Note [Default methods and instances] ; inst_binds_s <- tcExtendIdEnv dm_ids $ mapM tcInstDecl2 inst_decls -- Done ; return (dm_binds `unionBags` unionManyBags inst_binds_s) } tcInstDecl2 :: InstInfo Name -> TcM (LHsBinds Id) tcInstDecl2 (InstInfo { iSpec = ispec, iBinds = ibinds }) = recoverM (return emptyLHsBinds) $ setSrcSpan loc $ addErrCtxt (instDeclCtxt2 (idType dfun_id)) $ tc_inst_decl2 dfun_id ibinds where dfun_id = instanceDFunId ispec loc = getSrcSpan dfun_id \end{code} See Note [Default methods and instances] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The default method Ids are already in the type environment (see Note [Default method Ids and Template Haskell] in TcTyClsDcls), BUT they don't have their InlinePragmas yet. Usually that would not matter, because the simplifier propagates information from binding site to use. But, unusually, when compiling instance decls we *copy* the INLINE pragma from the default method to the method for that particular operation (see Note [INLINE and default methods] below). So right here in tcInstDecl2 we must re-extend the type envt with the default method Ids replete with their INLINE pragmas. Urk. \begin{code} tc_inst_decl2 :: Id -> InstBindings Name -> TcM (LHsBinds Id) -- Returns a binding for the dfun ------------------------ -- Derived newtype instances; surprisingly tricky! -- -- class Show a => Foo a b where ... -- newtype N a = MkN (Tree [a]) deriving( Foo Int ) -- -- The newtype gives an FC axiom looking like -- axiom CoN a :: N a ~ Tree [a] -- (see Note [Newtype coercions] in TyCon for this unusual form of axiom) -- -- So all need is to generate a binding looking like: -- dfunFooT :: forall a. (Foo Int (Tree [a], Show (N a)) => Foo Int (N a) -- dfunFooT = /\a. \(ds:Show (N a)) (df:Foo (Tree [a])). -- case df `cast` (Foo Int (sym (CoN a))) of -- Foo _ op1 .. opn -> Foo ds op1 .. opn -- -- If there are no superclasses, matters are simpler, because we don't need the case -- see Note [Newtype deriving superclasses] in TcDeriv.lhs tc_inst_decl2 dfun_id (NewTypeDerived coi _) = do { let rigid_info = InstSkol origin = SigOrigin rigid_info inst_ty = idType dfun_id inst_tvs = fst (tcSplitForAllTys inst_ty) ; (inst_tvs', theta, inst_head_ty) <- tcSkolSigType rigid_info inst_ty -- inst_head_ty is a PredType ; let (cls, cls_inst_tys) = tcSplitDFunHead inst_head_ty (class_tyvars, sc_theta, _, _) = classBigSig cls cls_tycon = classTyCon cls sc_theta' = substTheta (zipOpenTvSubst class_tyvars cls_inst_tys) sc_theta Just (initial_cls_inst_tys, last_ty) = snocView cls_inst_tys (rep_ty, wrapper) = case coi of IdCo -> (last_ty, idHsWrapper) ACo co -> (snd (coercionKind co'), WpCast (mk_full_coercion co')) where co' = substTyWith inst_tvs (mkTyVarTys inst_tvs') co -- NB: the free variable of coi are bound by the -- universally quantified variables of the dfun_id -- This is weird, and maybe we should make NewTypeDerived -- carry a type-variable list too; but it works fine ----------------------- -- mk_full_coercion -- The inst_head looks like (C s1 .. sm (T a1 .. ak)) -- But we want the coercion (C s1 .. sm (sym (CoT a1 .. ak))) -- with kind (C s1 .. sm (T a1 .. ak) ~ C s1 .. sm ) -- where rep_ty is the (eta-reduced) type rep of T -- So we just replace T with CoT, and insert a 'sym' -- NB: we know that k will be >= arity of CoT, because the latter fully eta-reduced mk_full_coercion co = mkTyConApp cls_tycon (initial_cls_inst_tys ++ [mkSymCoercion co]) -- Full coercion : (Foo Int (Tree [a]) ~ Foo Int (N a) rep_pred = mkClassPred cls (initial_cls_inst_tys ++ [rep_ty]) -- In our example, rep_pred is (Foo Int (Tree [a])) ; sc_loc <- getInstLoc InstScOrigin ; sc_dicts <- newDictBndrs sc_loc sc_theta' ; inst_loc <- getInstLoc origin ; dfun_dicts <- newDictBndrs inst_loc theta ; rep_dict <- newDictBndr inst_loc rep_pred ; this_dict <- newDictBndr inst_loc (mkClassPred cls cls_inst_tys) -- Figure out bindings for the superclass context from dfun_dicts -- Don't include this_dict in the 'givens', else -- sc_dicts get bound by just selecting from this_dict!! ; sc_binds <- addErrCtxt superClassCtxt $ tcSimplifySuperClasses inst_loc this_dict dfun_dicts (rep_dict:sc_dicts) -- It's possible that the superclass stuff might unified something -- in the envt with one of the clas_tyvars ; checkSigTyVars inst_tvs' ; let coerced_rep_dict = wrapId wrapper (instToId rep_dict) ; body <- make_body cls_tycon cls_inst_tys sc_dicts coerced_rep_dict ; let dict_bind = mkVarBind (instToId this_dict) (noLoc body) ; return (unitBag $ noLoc $ AbsBinds inst_tvs' (map instToVar dfun_dicts) [(inst_tvs', dfun_id, instToId this_dict, noSpecPrags)] (dict_bind `consBag` sc_binds)) } where ----------------------- -- (make_body C tys scs coreced_rep_dict) -- returns -- (case coerced_rep_dict of { C _ ops -> C scs ops }) -- But if there are no superclasses, it returns just coerced_rep_dict -- See Note [Newtype deriving superclasses] in TcDeriv.lhs make_body cls_tycon cls_inst_tys sc_dicts coerced_rep_dict | null sc_dicts -- Case (a) = return coerced_rep_dict | otherwise -- Case (b) = do { op_ids <- newSysLocalIds (fsLit "op") op_tys ; dummy_sc_dict_ids <- newSysLocalIds (fsLit "sc") (map idType sc_dict_ids) ; let the_pat = ConPatOut { pat_con = noLoc cls_data_con, pat_tvs = [], pat_dicts = dummy_sc_dict_ids, pat_binds = emptyLHsBinds, pat_args = PrefixCon (map nlVarPat op_ids), pat_ty = pat_ty} the_match = mkSimpleMatch [noLoc the_pat] the_rhs the_rhs = mkHsConApp cls_data_con cls_inst_tys $ map HsVar (sc_dict_ids ++ op_ids) -- Warning: this HsCase scrutinises a value with a PredTy, which is -- never otherwise seen in Haskell source code. It'd be -- nicer to generate Core directly! ; return (HsCase (noLoc coerced_rep_dict) $ MatchGroup [the_match] (mkFunTy pat_ty pat_ty)) } where sc_dict_ids = map instToId sc_dicts pat_ty = mkTyConApp cls_tycon cls_inst_tys cls_data_con = head (tyConDataCons cls_tycon) cls_arg_tys = dataConInstArgTys cls_data_con cls_inst_tys op_tys = dropList sc_dict_ids cls_arg_tys ------------------------ -- Ordinary instances tc_inst_decl2 dfun_id (VanillaInst monobinds uprags standalone_deriv) = do { let rigid_info = InstSkol inst_ty = idType dfun_id loc = getSrcSpan dfun_id -- Instantiate the instance decl with skolem constants ; (inst_tyvars', dfun_theta', inst_head') <- tcSkolSigType rigid_info inst_ty -- These inst_tyvars' scope over the 'where' part -- Those tyvars are inside the dfun_id's type, which is a bit -- bizarre, but OK so long as you realise it! ; let (clas, inst_tys') = tcSplitDFunHead inst_head' (class_tyvars, sc_theta, sc_sels, op_items) = classBigSig clas -- Instantiate the super-class context with inst_tys sc_theta' = substTheta (zipOpenTvSubst class_tyvars inst_tys') sc_theta origin = SigOrigin rigid_info -- Create dictionary Ids from the specified instance contexts. ; inst_loc <- getInstLoc origin ; dfun_dicts <- newDictBndrs inst_loc dfun_theta' -- Includes equalities ; this_dict <- newDictBndr inst_loc (mkClassPred clas inst_tys') -- Default-method Ids may be mentioned in synthesised RHSs, -- but they'll already be in the environment. -- Cook up a binding for "this = df d1 .. dn", -- to use in each method binding -- Need to clone the dict in case it is floated out, and -- then clashes with its friends ; cloned_this <- cloneDict this_dict ; let cloned_this_bind = mkVarBind (instToId cloned_this) $ L loc $ wrapId app_wrapper dfun_id app_wrapper = mkWpApps dfun_lam_vars <.> mkWpTyApps (mkTyVarTys inst_tyvars') dfun_lam_vars = map instToVar dfun_dicts -- Includes equalities nested_this_pair | null inst_tyvars' && null dfun_theta' = (this_dict, emptyBag) | otherwise = (cloned_this, unitBag cloned_this_bind) -- Deal with 'SPECIALISE instance' pragmas -- See Note [SPECIALISE instance pragmas] ; let spec_inst_sigs = filter isSpecInstLSig uprags -- The filter removes the pragmas for methods ; spec_inst_prags <- mapM (wrapLocM (tcSpecInst dfun_id)) spec_inst_sigs -- Typecheck the methods ; let prag_fn = mkPragFun uprags monobinds tc_meth = tcInstanceMethod loc standalone_deriv clas inst_tyvars' dfun_dicts inst_tys' nested_this_pair prag_fn spec_inst_prags monobinds ; (meth_ids, meth_binds) <- tcExtendTyVarEnv inst_tyvars' $ mapAndUnzipM tc_meth op_items -- Figure out bindings for the superclass context ; sc_loc <- getInstLoc InstScOrigin ; sc_dicts <- newDictOccs sc_loc sc_theta' -- These are wanted ; let tc_sc = tcSuperClass inst_loc inst_tyvars' dfun_dicts nested_this_pair ; (sc_ids, sc_binds) <- mapAndUnzipM tc_sc (sc_sels `zip` sc_dicts) -- It's possible that the superclass stuff might unified -- something in the envt with one of the inst_tyvars' ; checkSigTyVars inst_tyvars' -- Create the result bindings ; let dict_constr = classDataCon clas this_dict_id = instToId this_dict dict_bind = mkVarBind this_dict_id dict_rhs dict_rhs = foldl mk_app inst_constr sc_meth_ids sc_meth_ids = sc_ids ++ meth_ids inst_constr = L loc $ wrapId (mkWpTyApps inst_tys') (dataConWrapId dict_constr) -- We don't produce a binding for the dict_constr; instead we -- rely on the simplifier to unfold this saturated application -- We do this rather than generate an HsCon directly, because -- it means that the special cases (e.g. dictionary with only one -- member) are dealt with by the common MkId.mkDataConWrapId code rather -- than needing to be repeated here. mk_app :: LHsExpr Id -> Id -> LHsExpr Id mk_app fun arg_id = L loc (HsApp fun (L loc (wrapId arg_wrapper arg_id))) arg_wrapper = mkWpApps dfun_lam_vars <.> mkWpTyApps (mkTyVarTys inst_tyvars') -- Do not inline the dfun; instead give it a magic DFunFunfolding -- See Note [ClassOp/DFun selection] -- See also note [Single-method classes] dfun_id_w_fun = dfun_id `setIdUnfolding` mkDFunUnfolding inst_ty (map Var sc_meth_ids) `setInlinePragma` dfunInlinePragma main_bind = AbsBinds inst_tyvars' dfun_lam_vars [(inst_tyvars', dfun_id_w_fun, this_dict_id, SpecPrags spec_inst_prags)] (unitBag dict_bind) ; showLIE (text "instance") ; return (unitBag (L loc main_bind) `unionBags` listToBag meth_binds `unionBags` listToBag sc_binds) } {- -- Create the result bindings ; let this_dict_id = instToId this_dict arg_ids = sc_ids ++ meth_ids arg_binds = listToBag meth_binds `unionBags` listToBag sc_binds ; showLIE (text "instance") ; case newTyConCo_maybe (classTyCon clas) of Nothing -- A multi-method class -> return (unitBag (L loc data_bind) `unionBags` arg_binds) where data_dfun_id = dfun_id -- Do not inline; instead give it a magic DFunFunfolding -- See Note [ClassOp/DFun selection] `setIdUnfolding` mkDFunUnfolding dict_constr arg_ids `setInlinePragma` dfunInlinePragma data_bind = AbsBinds inst_tyvars' dfun_lam_vars [(inst_tyvars', data_dfun_id, this_dict_id, spec_inst_prags)] (unitBag dict_bind) dict_bind = mkVarBind this_dict_id dict_rhs dict_rhs = foldl mk_app inst_constr arg_ids dict_constr = classDataCon clas inst_constr = L loc $ wrapId (mkWpTyApps inst_tys') (dataConWrapId dict_constr) -- We don't produce a binding for the dict_constr; instead we -- rely on the simplifier to unfold this saturated application -- We do this rather than generate an HsCon directly, because -- it means that the special cases (e.g. dictionary with only one -- member) are dealt with by the common MkId.mkDataConWrapId code rather -- than needing to be repeated here. mk_app :: LHsExpr Id -> Id -> LHsExpr Id mk_app fun arg_id = L loc (HsApp fun (L loc (wrapId arg_wrapper arg_id))) arg_wrapper = mkWpApps dfun_lam_vars <.> mkWpTyApps (mkTyVarTys inst_tyvars') Just the_nt_co -- (Just co) for a single-method class -> return (unitBag (L loc nt_bind) `unionBags` arg_binds) where nt_dfun_id = dfun_id -- Just let the dfun inline; see Note [Single-method classes] `setInlinePragma` alwaysInlinePragma local_nt_dfun = setIdType this_dict_id inst_ty -- A bit of a hack, but convenient nt_bind = AbsBinds [] [] [([], nt_dfun_id, local_nt_dfun, spec_inst_prags)] (unitBag (mkVarBind local_nt_dfun (L loc (wrapId nt_cast the_meth_id)))) the_meth_id = ASSERT( length arg_ids == 1 ) head arg_ids nt_cast = WpCast $ mkPiTypes (inst_tyvars' ++ dfun_lam_vars) $ mkSymCoercion (mkTyConApp the_nt_co inst_tys') -} ------------------------------ tcSuperClass :: InstLoc -> [TyVar] -> [Inst] -> (Inst, LHsBinds Id) -> (Id, Inst) -> TcM (Id, LHsBind Id) -- Build a top level decl like -- sc_op = /\a \d. let this = ... in -- let sc = ... in -- sc -- The "this" part is just-in-case (discarded if not used) -- See Note [Recursive superclasses] tcSuperClass inst_loc tyvars dicts (this_dict, this_bind) (sc_sel, sc_dict) = addErrCtxt superClassCtxt $ do { sc_binds <- tcSimplifySuperClasses inst_loc this_dict dicts [sc_dict] -- Don't include this_dict in the 'givens', else -- sc_dicts get bound by just selecting from this_dict!! ; uniq <- newUnique ; let sc_op_ty = mkSigmaTy tyvars (map dictPred dicts) (mkPredTy (dictPred sc_dict)) sc_op_name = mkDerivedInternalName mkClassOpAuxOcc uniq (getName sc_sel) sc_op_id = mkLocalId sc_op_name sc_op_ty sc_id = instToVar sc_dict sc_op_bind = AbsBinds tyvars (map instToVar dicts) [(tyvars, sc_op_id, sc_id, noSpecPrags)] (this_bind `unionBags` sc_binds) ; return (sc_op_id, noLoc sc_op_bind) } \end{code} Note [Recursive superclasses] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ See Trac #1470 for why we would *like* to add "this_dict" to the available instances here. But we can't do so because then the superclases get satisfied by selection from this_dict, and that leads to an immediate loop. What we need is to add this_dict to Avails without adding its superclasses, and we currently have no way to do that. Note [SPECIALISE instance pragmas] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider instance (Ix a, Ix b) => Ix (a,b) where {-# SPECIALISE instance Ix (Int,Int) #-} range (x,y) = ... We do *not* want to make a specialised version of the dictionary function. Rather, we want specialised versions of each method. Thus we should generate something like this: $dfIx :: (Ix a, Ix x) => Ix (a,b) {- DFUN [$crange, ...] -} $dfIx da db = Ix ($crange da db) (...other methods...) $dfIxPair :: (Ix a, Ix x) => Ix (a,b) {- DFUN [$crangePair, ...] -} $dfIxPair = Ix ($crangePair da db) (...other methods...) $crange :: (Ix a, Ix b) -> ((a,b),(a,b)) -> [(a,b)] {-# SPECIALISE $crange :: ((Int,Int),(Int,Int)) -> [(Int,Int)] #-} $crange da db = {-# RULE range ($dfIx da db) = $crange da db #-} Note that * The RULE is unaffected by the specialisation. We don't want to specialise $dfIx, because then it would need a specialised RULE which is a pain. The single RULE works fine at all specialisations. See Note [How instance declarations are translated] above * Instead, we want to specialise the *method*, $crange In practice, rather than faking up a SPECIALISE pragama for each method (which is painful, since we'd have to figure out its specialised type), we call tcSpecPrag *as if* were going to specialise $dfIx -- you can see that in the call to tcSpecInst. That generates a SpecPrag which, as it turns out, can be used unchanged for each method. The "it turns out" bit is delicate, but it works fine! \begin{code} tcSpecInst :: Id -> Sig Name -> TcM TcSpecPrag tcSpecInst dfun_id prag@(SpecInstSig hs_ty) = addErrCtxt (spec_ctxt prag) $ do { let name = idName dfun_id ; (tyvars, theta, tau) <- tcHsInstHead hs_ty ; let spec_ty = mkSigmaTy tyvars theta tau ; co_fn <- tcSubExp (SpecPragOrigin name) (idType dfun_id) spec_ty ; return (SpecPrag co_fn defaultInlinePragma) } where spec_ctxt prag = hang (ptext (sLit "In the SPECIALISE pragma")) 2 (ppr prag) tcSpecInst _ _ = panic "tcSpecInst" \end{code} %************************************************************************ %* * Type-checking an instance method %* * %************************************************************************ tcInstanceMethod - Make the method bindings, as a [(NonRec, HsBinds)], one per method - Remembering to use fresh Name (the instance method Name) as the binder - Bring the instance method Ids into scope, for the benefit of tcInstSig - Use sig_fn mapping instance method Name -> instance tyvars - Ditto prag_fn - Use tcValBinds to do the checking \begin{code} tcInstanceMethod :: SrcSpan -> Bool -> Class -> [TcTyVar] -> [Inst] -> [TcType] -> (Inst, LHsBinds Id) -- "This" and its binding -> TcPragFun -- Local prags -> [Located TcSpecPrag] -- Arising from 'SPECLALISE instance' -> LHsBinds Name -> (Id, DefMeth) -> TcM (Id, LHsBind Id) -- The returned inst_meth_ids all have types starting -- forall tvs. theta => ... tcInstanceMethod loc standalone_deriv clas tyvars dfun_dicts inst_tys (this_dict, this_dict_bind) prag_fn spec_inst_prags binds_in (sel_id, dm_info) = do { uniq <- newUnique ; let meth_name = mkDerivedInternalName mkClassOpAuxOcc uniq sel_name ; local_meth_name <- newLocalName sel_name -- Base the local_meth_name on the selector name, becuase -- type errors from tcInstanceMethodBody come from here ; let local_meth_ty = instantiateMethod clas sel_id inst_tys meth_ty = mkSigmaTy tyvars (map dictPred dfun_dicts) local_meth_ty meth_id = mkLocalId meth_name meth_ty local_meth_id = mkLocalId local_meth_name local_meth_ty -------------- tc_body rn_bind = add_meth_ctxt rn_bind $ do { (meth_id1, spec_prags) <- tcPrags NonRecursive False True meth_id (prag_fn sel_name) ; bind <- tcInstanceMethodBody (instLoc this_dict) tyvars dfun_dicts ([this_dict], this_dict_bind) meth_id1 local_meth_id meth_sig_fn (SpecPrags (spec_inst_prags ++ spec_prags)) rn_bind ; return (meth_id1, bind) } -------------- tc_default :: DefMeth -> TcM (Id, LHsBind Id) -- The user didn't supply a method binding, so we have to make -- up a default binding, in a way depending on the default-method info tc_default NoDefMeth -- No default method at all = do { warnMissingMethod sel_id ; return (meth_id, mkVarBind meth_id $ mkLHsWrap lam_wrapper error_rhs) } tc_default GenDefMeth -- Derivable type classes stuff = do { meth_bind <- mkGenericDefMethBind clas inst_tys sel_id local_meth_name ; tc_body meth_bind } tc_default (DefMeth dm_name) -- An polymorphic default method = do { -- Build the typechecked version directly, -- without calling typecheck_method; -- see Note [Default methods in instances] -- Generate /\as.\ds. let this = df as ds -- in $dm inst_tys this -- The 'let' is necessary only because HsSyn doesn't allow -- you to apply a function to a dictionary *expression*. ; dm_id <- tcLookupId dm_name ; let dm_inline_prag = idInlinePragma dm_id rhs = HsWrap (WpApp (instToId this_dict) <.> mkWpTyApps inst_tys) $ HsVar dm_id meth_bind = L loc $ VarBind { var_id = local_meth_id , var_rhs = L loc rhs , var_inline = False } meth_id1 = meth_id `setInlinePragma` dm_inline_prag -- Copy the inline pragma (if any) from the default -- method to this version. Note [INLINE and default methods] bind = AbsBinds { abs_tvs = tyvars, abs_dicts = dfun_lam_vars , abs_exports = [( tyvars, meth_id1, local_meth_id , SpecPrags spec_inst_prags)] , abs_binds = this_dict_bind `unionBags` unitBag meth_bind } -- Default methods in an instance declaration can't have their own -- INLINE or SPECIALISE pragmas. It'd be possible to allow them, but -- currently they are rejected with -- "INLINE pragma lacks an accompanying binding" ; return (meth_id1, L loc bind) } ; case findMethodBind sel_name local_meth_name binds_in of Just user_bind -> tc_body user_bind -- User-supplied method binding Nothing -> tc_default dm_info -- None supplied } where sel_name = idName sel_id meth_sig_fn _ = Just [] -- The 'Just' says "yes, there's a type sig" -- But there are no scoped type variables from local_method_id -- Only the ones from the instance decl itself, which are already -- in scope. Example: -- class C a where { op :: forall b. Eq b => ... } -- instance C [c] where { op = } -- In , 'c' is scope but 'b' is not! error_rhs = L loc $ HsApp error_fun error_msg error_fun = L loc $ wrapId (WpTyApp meth_tau) nO_METHOD_BINDING_ERROR_ID error_msg = L loc (HsLit (HsStringPrim (mkFastString error_string))) meth_tau = funResultTy (applyTys (idType sel_id) inst_tys) error_string = showSDoc (hcat [ppr loc, text "|", ppr sel_id ]) dfun_lam_vars = map instToVar dfun_dicts lam_wrapper = mkWpTyLams tyvars <.> mkWpLams dfun_lam_vars -- For instance decls that come from standalone deriving clauses -- we want to print out the full source code if there's an error -- because otherwise the user won't see the code at all add_meth_ctxt rn_bind thing | standalone_deriv = addLandmarkErrCtxt (derivBindCtxt clas inst_tys rn_bind) thing | otherwise = thing wrapId :: HsWrapper -> id -> HsExpr id wrapId wrapper id = mkHsWrap wrapper (HsVar id) derivBindCtxt :: Class -> [Type ] -> LHsBind Name -> SDoc derivBindCtxt clas tys bind = vcat [ ptext (sLit "When typechecking a standalone-derived method for") <+> quotes (pprClassPred clas tys) <> colon , nest 2 $ pprSetDepth AllTheWay $ ppr bind ] warnMissingMethod :: Id -> TcM () warnMissingMethod sel_id = do { warn <- doptM Opt_WarnMissingMethods ; warnTc (warn -- Warn only if -fwarn-missing-methods && not (startsWithUnderscore (getOccName sel_id))) -- Don't warn about _foo methods (ptext (sLit "No explicit method nor default method for") <+> quotes (ppr sel_id)) } \end{code} Note [Export helper functions] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We arrange to export the "helper functions" of an instance declaration, so that they are not subject to preInlineUnconditionally, even if their RHS is trivial. Reason: they are mentioned in the DFunUnfolding of the dict fun as Ids, not as CoreExprs, so we can't substitute a non-variable for them. We could change this by making DFunUnfoldings have CoreExprs, but it seems a bit simpler this way. Note [Default methods in instances] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this class Baz v x where foo :: x -> x foo y = instance Baz Int Int From the class decl we get $dmfoo :: forall v x. Baz v x => x -> x $dmfoo y = Notice that the type is ambiguous. That's fine, though. The instance decl generates $dBazIntInt = MkBaz fooIntInt fooIntInt = $dmfoo Int Int $dBazIntInt BUT this does mean we must generate the dictionary translation of fooIntInt directly, rather than generating source-code and type-checking it. That was the bug in Trac #1061. In any case it's less work to generate the translated version! Note [INLINE and default methods] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Default methods need special case. They are supposed to behave rather like macros. For exmample class Foo a where op1, op2 :: Bool -> a -> a {-# INLINE op1 #-} op1 b x = op2 (not b) x instance Foo Int where -- op1 via default method op2 b x = The instance declaration should behave just as if 'op1' had been defined with the code, and INLINE pragma, from its original definition. That is, just as if you'd written instance Foo Int where op2 b x = {-# INLINE op1 #-} op1 b x = op2 (not b) x So for the above example we generate: {-# INLINE $dmop1 #-} -- $dmop1 has an InlineCompulsory unfolding $dmop1 d b x = op2 d (not b) x $fFooInt = MkD $cop1 $cop2 {-# INLINE $cop1 #-} $cop1 = $dmop1 $fFooInt $cop2 = Note carefullly: * We *copy* any INLINE pragma from the default method $dmop1 to the instance $cop1. Otherwise we'll just inline the former in the latter and stop, which isn't what the user expected * Regardless of its pragma, we give the default method an unfolding with an InlineCompulsory source. That means that it'll be inlined at every use site, notably in each instance declaration, such as $cop1. This inlining must happen even though a) $dmop1 is not saturated in $cop1 b) $cop1 itself has an INLINE pragma It's vital that $dmop1 *is* inlined in this way, to allow the mutual recursion between $fooInt and $cop1 to be broken * To communicate the need for an InlineCompulsory to the desugarer (which makes the Unfoldings), we use the IsDefaultMethod constructor in TcSpecPrags. %************************************************************************ %* * \subsection{Error messages} %* * %************************************************************************ \begin{code} instDeclCtxt1 :: LHsType Name -> SDoc instDeclCtxt1 hs_inst_ty = inst_decl_ctxt (case unLoc hs_inst_ty of HsForAllTy _ _ _ (L _ (HsPredTy pred)) -> ppr pred HsPredTy pred -> ppr pred _ -> ppr hs_inst_ty) -- Don't expect this instDeclCtxt2 :: Type -> SDoc instDeclCtxt2 dfun_ty = inst_decl_ctxt (ppr (mkClassPred cls tys)) where (_,cls,tys) = tcSplitDFunTy dfun_ty inst_decl_ctxt :: SDoc -> SDoc inst_decl_ctxt doc = ptext (sLit "In the instance declaration for") <+> quotes doc superClassCtxt :: SDoc superClassCtxt = ptext (sLit "When checking the super-classes of an instance declaration") atInstCtxt :: Name -> SDoc atInstCtxt name = ptext (sLit "In the associated type instance for") <+> quotes (ppr name) mustBeVarArgErr :: Type -> SDoc mustBeVarArgErr ty = sep [ ptext (sLit "Arguments that do not correspond to a class parameter") <+> ptext (sLit "must be variables") , ptext (sLit "Instead of a variable, found") <+> ppr ty ] wrongATArgErr :: Type -> Type -> SDoc wrongATArgErr ty instTy = sep [ ptext (sLit "Type indexes must match class instance head") , ptext (sLit "Found") <+> quotes (ppr ty) <+> ptext (sLit "but expected") <+> quotes (ppr instTy) ] \end{code}