.
%************************************************************************
%* *
\subsection{Extracting instance decls}
%* *
%************************************************************************
Gather up the instance declarations from their various sources
\begin{code}
tcInstDecls1
:: [LTyClDecl Name]
-> [LInstDecl Name]
-> [LDerivDecl Name]
-> TcM (TcGblEnv,
[InstInfo Name],
HsValBinds Name)
tcInstDecls1 tycl_decls inst_decls deriv_decls
= checkNoErrs $
do {
; 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
; implicit_things = concatMap implicitTyConThings at_idx_tycons
; aux_binds = mkRecSelBinds at_idx_tycons }
; tcExtendGlobalEnv (map ATyCon at_idx_tycons ++ implicit_things) $ do {
; addInsts local_info $
addFamInsts at_idx_tycons $ do {
failIfErrsM
; (deriv_inst_info, deriv_binds, deriv_dus, deriv_tys, deriv_ty_insts)
<- tcDeriving tycl_decls inst_decls deriv_decls
; let all_tycons = map ATyCon (deriv_tys ++ deriv_ty_insts)
; gbl_env <- tcExtendGlobalEnv all_tycons $
tcExtendGlobalEnv (concatMap implicitTyThings all_tycons) $
addFamInsts deriv_ty_insts $
addInsts deriv_inst_info getGblEnv
; dflags <- getDOpts
; when (safeLanguageOn dflags) $
mapM_ (\x -> when (is_cls (iSpec x) `elem` typeableClassNames)
(addErrAt (getSrcSpan $ iSpec x) typInstErr))
local_info
; return ( addTcgDUs gbl_env deriv_dus,
deriv_inst_info ++ local_info,
aux_binds `plusHsValBinds` deriv_binds)
}}}
where
typInstErr = ptext $ sLit $ "Can't create hand written instances of Typeable in Safe"
++ " Haskell! Can only derive them"
addInsts :: [InstInfo Name] -> TcM a -> TcM a
addInsts infos thing_inside
= tcExtendLocalInstEnv (map iSpec infos) thing_inside
addFamInsts :: [TyCon] -> TcM a -> TcM a
addFamInsts tycons thing_inside
= tcExtendLocalFamInstEnv (map mkLocalFamInst tycons) thing_inside
\end{code}
\begin{code}
tcLocalInstDecl1 :: LInstDecl Name
-> TcM (InstInfo Name, [TyCon])
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, clas, inst_tys) <- tcHsInstHead poly_ty
; checkValidInstance poly_ty tyvars theta clas inst_tys
; idx_tycons <- recoverM (return []) $
do { idx_tycons <- checkNoErrs $
mapAndRecoverM (tcFamInstDecl NotTopLevel) ats
; checkValidAndMissingATs clas (tyvars, inst_tys)
(zip ats idx_tycons)
; return idx_tycons }
; dfun_name <- newDFunName clas inst_tys (getLoc poly_ty)
; 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
checkValidAndMissingATs :: Class
-> ([TyVar], [TcType])
-> [(LTyClDecl Name,
TyCon)]
-> TcM ()
checkValidAndMissingATs clas inst_tys ats
= do {
; let class_ats = map tyConName (classATs clas)
defined_ats = listToNameSet . map (tcdName.unLoc.fst) $ ats
omitted = filterOut (`elemNameSet` defined_ats) class_ats
; warn <- woptM Opt_WarnMissingMethods
; mapM_ (warnTc warn . omittedATWarn) omitted
; mapM_ (checkIndexes clas inst_tys) ats
}
checkIndexes clas inst_tys (hsAT, tycon)
= checkIndexes' clas inst_tys hsAT
(tyConTyVars tycon,
snd . fromJust . tyConFamInst_maybe $ tycon)
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
Just atycon ->
let poss :: [Int]
poss = catMaybes [ tv `elemIndex` classTyVars clas
| tv <- tyConTyVars atycon]
relevantInstTys = map (instTys !!) poss
instArgs = map Just relevantInstTys ++
repeat Nothing
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 `eqType` 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
TcType.extendTvSubst (substSameTyVar tvs replacingTvs) tv replacement
\end{code}
%************************************************************************
%* *
Type checking family instances
%* *
%************************************************************************
Family instances are somewhat of a hybrid. They are processed together with
class instance heads, but can contain data constructors and hence they share a
lot of kinding and type checking code with ordinary algebraic data types (and
GADTs).
\begin{code}
tcFamInstDecl :: TopLevelFlag -> LTyClDecl Name -> TcM TyCon
tcFamInstDecl top_lvl (L loc decl)
=
setSrcSpan loc $
tcAddDeclCtxt decl $
do {
; type_families <- xoptM Opt_TypeFamilies
; is_boot <- tcIsHsBoot
; checkTc type_families $ badFamInstDecl (tcdLName decl)
; checkTc (not is_boot) $ badBootFamInstDeclErr
; tc <- tcFamInstDecl1 decl
; checkValidTyCon tc
; when (isTopLevel top_lvl && isAssocFamily tc)
(addErr $ assocInClassErr (tcdName decl))
; return tc }
isAssocFamily :: TyCon -> Bool
isAssocFamily tycon
= case tyConFamInst_maybe tycon of
Nothing -> panic "isAssocFamily: no family?!?"
Just (fam, _) -> isTyConAssoc fam
assocInClassErr :: Name -> SDoc
assocInClassErr name
= ptext (sLit "Associated type") <+> quotes (ppr name) <+>
ptext (sLit "must be inside a class instance")
tcFamInstDecl1 :: TyClDecl Name -> TcM TyCon
tcFamInstDecl1 (decl@TySynonym {tcdLName = L loc tc_name})
= kcIdxTyPats decl $ \k_tvs k_typats resKind family ->
do {
checkTc (isFamilyTyCon family) (notFamily family)
; checkTc (isSynTyCon family) (wrongKindOfFamily family)
;
; k_rhs <- kcCheckLHsType (tcdSynRhs decl) (EK resKind EkUnk)
; let famArity = tyConArity family
; checkTc (length k_typats == famArity) $
wrongNumberOfParmsErr famArity
; tcTyVarBndrs k_tvs $ \t_tvs -> do {
; t_typats <- mapM tcHsKindedType k_typats
; t_rhs <- tcHsKindedType k_rhs
; checkValidTypeInst t_typats t_rhs
; rep_tc_name <- newFamInstTyConName tc_name t_typats loc
; buildSynTyCon rep_tc_name t_tvs (SynonymTyCon t_rhs)
(typeKind t_rhs)
NoParentTyCon (Just (family, t_typats))
}}
tcFamInstDecl1 (decl@TyData {tcdND = new_or_data, tcdLName = L loc tc_name,
tcdCons = cons})
= kcIdxTyPats decl $ \k_tvs k_typats resKind fam_tycon ->
do {
checkTc (isFamilyTyCon fam_tycon) (notFamily fam_tycon)
; checkTc (isAlgTyCon fam_tycon) (wrongKindOfFamily fam_tycon)
;
; k_decl <- kcDataDecl decl k_tvs
; let k_ctxt = tcdCtxt k_decl
k_cons = tcdCons k_decl
; checkTc (isLiftedTypeKind resKind) $ tooFewParmsErr (tyConArity fam_tycon)
; tcTyVarBndrs k_tvs $ \t_tvs -> do {
; t_typats <- mapM tcHsKindedType k_typats
; stupid_theta <- tcHsKindedContext k_ctxt
; mapM_ checkTyFamFreeness t_typats
; dataDeclChecks tc_name new_or_data stupid_theta k_cons
; rep_tc_name <- newFamInstTyConName tc_name t_typats loc
; let ex_ok = True
; fixM (\ rep_tycon -> do
{ let orig_res_ty = mkTyConApp fam_tycon t_typats
; data_cons <- tcConDecls ex_ok rep_tycon
(t_tvs, orig_res_ty) k_cons
; tc_rhs <-
case new_or_data of
DataType -> return (mkDataTyConRhs data_cons)
NewType -> ASSERT( not (null data_cons) )
mkNewTyConRhs rep_tc_name rep_tycon (head data_cons)
; buildAlgTyCon rep_tc_name t_tvs stupid_theta tc_rhs Recursive
h98_syntax NoParentTyCon (Just (fam_tycon, t_typats))
})
}}
where
h98_syntax = case cons of
L _ (ConDecl { con_res = ResTyGADT _ }) : _ -> False
_ -> True
tcFamInstDecl1 d = pprPanic "tcFamInstDecl1" (ppr d)
kcIdxTyPats :: TyClDecl Name
-> ([LHsTyVarBndr Name] -> [LHsType Name] -> Kind -> TyCon -> TcM a)
-> TcM a
kcIdxTyPats decl thing_inside
= kcHsTyVars (tcdTyVars decl) $ \tvs ->
do { let tc_name = tcdLName decl
; fam_tycon <- tcLookupLocatedTyCon tc_name
; let { (kinds, resKind) = splitKindFunTys (tyConKind fam_tycon)
; hs_typats = fromJust $ tcdTyPats decl }
; checkTc (length kinds >= length hs_typats) $
tooManyParmsErr (tcdLName decl)
; let resultKind = mkArrowKinds (drop (length hs_typats) kinds) resKind
; typats <- zipWithM kcCheckLHsType hs_typats
[ EK kind (EkArg (ppr tc_name) n)
| (kind,n) <- kinds `zip` [1..]]
; thing_inside tvs typats resultKind fam_tycon
}
\end{code}
%************************************************************************
%* *
Type-checking instance declarations, pass 2
%* *
%************************************************************************
\begin{code}
tcInstDecls2 :: [LTyClDecl Name] -> [InstInfo Name]
-> TcM (LHsBinds Id)
tcInstDecls2 tycl_decls inst_decls
= do {
let class_decls = filter (isClassDecl . unLoc) tycl_decls
; dm_binds_s <- mapM tcClassDecl2 class_decls
; let dm_binds = unionManyBags dm_binds_s
; let dm_ids = collectHsBindsBinders dm_binds
; inst_binds_s <- tcExtendIdEnv dm_ids $
mapM tcInstDecl2 inst_decls
; return (dm_binds `unionBags` unionManyBags inst_binds_s) }
\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}
tcInstDecl2 :: InstInfo Name -> TcM (LHsBinds Id)
tcInstDecl2 (InstInfo { iSpec = ispec, iBinds = ibinds })
= recoverM (return emptyLHsBinds) $
setSrcSpan loc $
addErrCtxt (instDeclCtxt2 (idType dfun_id)) $
do {
; (inst_tyvars, dfun_theta, inst_head) <- tcSkolDFunType (idType dfun_id)
; let (clas, inst_tys) = tcSplitDFunHead inst_head
(class_tyvars, sc_theta, sc_sels, op_items) = classBigSig clas
sc_theta' = substTheta (zipOpenTvSubst class_tyvars inst_tys) sc_theta
; dfun_ev_vars <- newEvVars dfun_theta
; (sc_args, sc_binds)
<- mapAndUnzipM (tcSuperClass inst_tyvars dfun_ev_vars)
(sc_sels `zip` sc_theta')
; spec_info@(spec_inst_prags,_) <- tcSpecInstPrags dfun_id ibinds
; (meth_ids, meth_binds)
<- tcExtendTyVarEnv inst_tyvars $
tcInstanceMethods dfun_id clas inst_tyvars dfun_ev_vars
inst_tys spec_info
op_items ibinds
; self_dict <- newEvVar (ClassP clas inst_tys)
; let class_tc = classTyCon clas
[dict_constr] = tyConDataCons class_tc
dict_bind = mkVarBind self_dict (L loc con_app_args)
con_app_tys = wrapId (mkWpTyApps inst_tys)
(dataConWrapId dict_constr)
con_app_scs = mkHsWrap (mkWpEvApps (map mk_sc_ev_term sc_args)) con_app_tys
con_app_args = foldl mk_app con_app_scs $
map (wrapId arg_wrapper) meth_ids
mk_app :: HsExpr Id -> HsExpr Id -> HsExpr Id
mk_app fun arg = HsApp (L loc fun) (L loc arg)
mk_sc_ev_term :: EvVar -> EvTerm
mk_sc_ev_term sc
| null inst_tv_tys
, null dfun_ev_vars = evVarTerm sc
| otherwise = EvDFunApp sc inst_tv_tys dfun_ev_vars
inst_tv_tys = mkTyVarTys inst_tyvars
arg_wrapper = mkWpEvVarApps dfun_ev_vars <.> mkWpTyApps inst_tv_tys
dfun_id_w_fun
| isNewTyCon class_tc
= dfun_id `setInlinePragma` alwaysInlinePragma { inl_sat = Just 0 }
| otherwise
= dfun_id `setIdUnfolding` mkDFunUnfolding dfun_ty dfun_args
`setInlinePragma` dfunInlinePragma
dfun_args :: [CoreExpr]
dfun_args = map varToCoreExpr sc_args ++
map Var meth_ids
main_bind = AbsBinds { abs_tvs = inst_tyvars
, abs_ev_vars = dfun_ev_vars
, abs_exports = [(inst_tyvars, dfun_id_w_fun, self_dict,
SpecPrags spec_inst_prags)]
, abs_ev_binds = emptyTcEvBinds
, abs_binds = unitBag dict_bind }
; return (unitBag (L loc main_bind) `unionBags`
listToBag meth_binds `unionBags`
unionManyBags sc_binds)
}
where
dfun_ty = idType dfun_id
dfun_id = instanceDFunId ispec
loc = getSrcSpan dfun_id
tcSuperClass :: [TcTyVar] -> [EvVar]
-> (Id, PredType)
-> TcM (TcId, LHsBinds TcId)
tcSuperClass tyvars ev_vars (sc_sel, sc_pred)
= do { (ev_binds, sc_dict)
<- newImplication InstSkol tyvars ev_vars $
emitWanted ScOrigin sc_pred
; uniq <- newUnique
; let sc_op_ty = mkForAllTys tyvars $ mkPiTypes ev_vars (varType sc_dict)
sc_op_name = mkDerivedInternalName mkClassOpAuxOcc uniq
(getName sc_sel)
sc_op_id = mkLocalId sc_op_name sc_op_ty
sc_op_bind = mkVarBind sc_op_id (L noSrcSpan $ wrapId sc_wrapper sc_dict)
sc_wrapper = mkWpTyLams tyvars
<.> mkWpLams ev_vars
<.> mkWpLet ev_binds
; return (sc_op_id, unitBag sc_op_bind) }
tcSpecInstPrags :: DFunId -> InstBindings Name
-> TcM ([Located TcSpecPrag], PragFun)
tcSpecInstPrags _ (NewTypeDerived {})
= return ([], \_ -> [])
tcSpecInstPrags dfun_id (VanillaInst binds uprags _)
= do { spec_inst_prags <- mapM (wrapLocM (tcSpecInst dfun_id)) $
filter isSpecInstLSig uprags
; return (spec_inst_prags, mkPragFun uprags binds) }
\end{code}
Note [Superclass loop avoidance]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider the following (extreme) situation:
class C a => D a where ...
instance D [a] => D [a] where ...
Although this looks wrong (assume D [a] to prove D [a]), it is only a
more extreme case of what happens with recursive dictionaries, and it
can, just about, make sense because the methods do some work before
recursing.
To implement the dfun we must generate code for the superclass C [a],
which we had better not get by superclass selection from the supplied
argument:
dfun :: forall a. D [a] -> D [a]
dfun = \d::D [a] -> MkD (scsel d) ..
Rather, we want to get it by finding an instance for (C [a]). We
achieve this by
not making the superclasses of a "wanted"
available for solving wanted constraints.
Test case SCLoop tests this fix.
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, clas, tys) <- tcHsInstHead hs_ty
; let spec_dfun_ty = mkDictFunTy tyvars theta clas tys
; co_fn <- tcSubType (SpecPragOrigin name) SpecInstCtxt
(idType dfun_id) spec_dfun_ty
; return (SpecPrag dfun_id 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}
tcInstanceMethods :: DFunId -> Class -> [TcTyVar]
-> [EvVar]
-> [TcType]
-> ([Located TcSpecPrag], PragFun)
-> [(Id, DefMeth)]
-> InstBindings Name
-> TcM ([Id], [LHsBind Id])
tcInstanceMethods dfun_id clas tyvars dfun_ev_vars inst_tys
(spec_inst_prags, prag_fn)
op_items (VanillaInst binds _ standalone_deriv)
= mapAndUnzipM tc_item op_items
where
tc_item :: (Id, DefMeth) -> TcM (Id, LHsBind Id)
tc_item (sel_id, dm_info)
= case findMethodBind (idName sel_id) binds of
Just user_bind -> tc_body sel_id standalone_deriv user_bind
Nothing -> tc_default sel_id dm_info
tc_body :: Id -> Bool -> LHsBind Name -> TcM (TcId, LHsBind Id)
tc_body sel_id generated_code rn_bind
= add_meth_ctxt sel_id generated_code rn_bind $
do { (meth_id, local_meth_id) <- mkMethIds clas tyvars dfun_ev_vars
inst_tys sel_id
; let prags = prag_fn (idName sel_id)
; meth_id1 <- addInlinePrags meth_id prags
; spec_prags <- tcSpecPrags meth_id1 prags
; bind <- tcInstanceMethodBody InstSkol
tyvars dfun_ev_vars
meth_id1 local_meth_id meth_sig_fn
(mk_meth_spec_prags meth_id1 spec_prags)
rn_bind
; return (meth_id1, bind) }
tc_default :: Id -> DefMeth -> TcM (TcId, LHsBind Id)
tc_default sel_id (GenDefMeth dm_name)
= do { meth_bind <- mkGenericDefMethBind clas inst_tys sel_id dm_name
; tc_body sel_id False meth_bind }
tc_default sel_id NoDefMeth
= do { warnMissingMethod sel_id
; (meth_id, _) <- mkMethIds clas tyvars dfun_ev_vars
inst_tys sel_id
; return (meth_id, mkVarBind meth_id $
mkLHsWrap lam_wrapper error_rhs) }
where
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 ])
lam_wrapper = mkWpTyLams tyvars <.> mkWpLams dfun_ev_vars
tc_default sel_id (DefMeth dm_name)
= do {
; self_dict <- newEvVar (ClassP clas inst_tys)
; let self_ev_bind = EvBind self_dict $
EvDFunApp dfun_id (mkTyVarTys tyvars) dfun_ev_vars
; (meth_id, local_meth_id) <- mkMethIds clas tyvars dfun_ev_vars
inst_tys sel_id
; dm_id <- tcLookupId dm_name
; let dm_inline_prag = idInlinePragma dm_id
rhs = HsWrap (mkWpEvVarApps [self_dict] <.> mkWpTyApps inst_tys) $
HsVar dm_id
meth_bind = mkVarBind local_meth_id (L loc rhs)
meth_id1 = meth_id `setInlinePragma` dm_inline_prag
bind = AbsBinds { abs_tvs = tyvars, abs_ev_vars = dfun_ev_vars
, abs_exports = [( tyvars, meth_id1, local_meth_id
, mk_meth_spec_prags meth_id1 [])]
, abs_ev_binds = EvBinds (unitBag self_ev_bind)
, abs_binds = unitBag meth_bind }
; return (meth_id1, L loc bind) }
mk_meth_spec_prags :: Id -> [LTcSpecPrag] -> TcSpecPrags
mk_meth_spec_prags meth_id spec_prags_for_me
= SpecPrags (spec_prags_for_me ++
[ L loc (SpecPrag meth_id wrap inl)
| L loc (SpecPrag _ wrap inl) <- spec_inst_prags])
loc = getSrcSpan dfun_id
meth_sig_fn _ = Just ([],loc)
add_meth_ctxt sel_id generated_code rn_bind thing
| generated_code = addLandmarkErrCtxt (derivBindCtxt sel_id clas inst_tys rn_bind) thing
| otherwise = thing
tcInstanceMethods dfun_id clas tyvars dfun_ev_vars inst_tys
_ op_items (NewTypeDerived coi _)
= do { rep_d_stuff <- checkConstraints InstSkol tyvars dfun_ev_vars $
emitWanted ScOrigin rep_pred
; mapAndUnzipM (tc_item rep_d_stuff) op_items }
where
loc = getSrcSpan dfun_id
inst_tvs = fst (tcSplitForAllTys (idType dfun_id))
Just (init_inst_tys, _) = snocView inst_tys
rep_ty = pFst (coercionKind co)
rep_pred = mkClassPred clas (init_inst_tys ++ [rep_ty])
co = substCoWithTys (mkInScopeSet (mkVarSet tyvars))
inst_tvs (mkTyVarTys tyvars) $
mkSymCo coi
tc_item :: (TcEvBinds, EvVar) -> (Id, DefMeth) -> TcM (TcId, LHsBind TcId)
tc_item (rep_ev_binds, rep_d) (sel_id, _)
= do { (meth_id, local_meth_id) <- mkMethIds clas tyvars dfun_ev_vars
inst_tys sel_id
; let meth_rhs = wrapId (mk_op_wrapper sel_id rep_d) sel_id
meth_bind = mkVarBind local_meth_id (L loc meth_rhs)
bind = AbsBinds { abs_tvs = tyvars, abs_ev_vars = dfun_ev_vars
, abs_exports = [(tyvars, meth_id,
local_meth_id, noSpecPrags)]
, abs_ev_binds = rep_ev_binds
, abs_binds = unitBag $ meth_bind }
; return (meth_id, L loc bind) }
mk_op_wrapper :: Id -> EvVar -> HsWrapper
mk_op_wrapper sel_id rep_d
= WpCast (liftCoSubstWith sel_tvs (map mkReflCo init_inst_tys ++ [co])
local_meth_ty)
<.> WpEvApp (EvId rep_d)
<.> mkWpTyApps (init_inst_tys ++ [rep_ty])
where
(sel_tvs, sel_rho) = tcSplitForAllTys (idType sel_id)
(_, local_meth_ty) = tcSplitPredFunTy_maybe sel_rho
`orElse` pprPanic "tcInstanceMethods" (ppr sel_id)
mkMethIds :: Class -> [TcTyVar] -> [EvVar] -> [TcType] -> Id -> TcM (TcId, TcId)
mkMethIds clas tyvars dfun_ev_vars inst_tys sel_id
= do { uniq <- newUnique
; let meth_name = mkDerivedInternalName mkClassOpAuxOcc uniq sel_name
; local_meth_name <- newLocalName sel_name
; let meth_id = mkLocalId meth_name meth_ty
local_meth_id = mkLocalId local_meth_name local_meth_ty
; return (meth_id, local_meth_id) }
where
local_meth_ty = instantiateMethod clas sel_id inst_tys
meth_ty = mkForAllTys tyvars $ mkPiTypes dfun_ev_vars local_meth_ty
sel_name = idName sel_id
wrapId :: HsWrapper -> id -> HsExpr id
wrapId wrapper id = mkHsWrap wrapper (HsVar id)
derivBindCtxt :: Id -> Class -> [Type ] -> LHsBind Name -> SDoc
derivBindCtxt sel_id clas tys _bind
= vcat [ ptext (sLit "When typechecking the code for ") <+> quotes (ppr sel_id)
, nest 2 (ptext (sLit "in a standalone derived instance for")
<+> quotes (pprClassPred clas tys) <> colon)
, nest 2 $ ptext (sLit "To see the code I am typechecking, use -ddump-deriv") ]
warnMissingMethod :: Id -> TcM ()
warnMissingMethod sel_id
= do { warn <- woptM Opt_WarnMissingMethods
; warnTc (warn
&& not (startsWithUnderscore (getOccName sel_id)))
(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)
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
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)
]
tooManyParmsErr :: Located Name -> SDoc
tooManyParmsErr tc_name
= ptext (sLit "Family instance has too many parameters:") <+>
quotes (ppr tc_name)
tooFewParmsErr :: Arity -> SDoc
tooFewParmsErr arity
= ptext (sLit "Family instance has too few parameters; expected") <+>
ppr arity
wrongNumberOfParmsErr :: Arity -> SDoc
wrongNumberOfParmsErr exp_arity
= ptext (sLit "Number of parameters must match family declaration; expected")
<+> ppr exp_arity
badBootFamInstDeclErr :: SDoc
badBootFamInstDeclErr
= ptext (sLit "Illegal family instance in hs-boot file")
notFamily :: TyCon -> SDoc
notFamily tycon
= vcat [ ptext (sLit "Illegal family instance for") <+> quotes (ppr tycon)
, nest 2 $ parens (ppr tycon <+> ptext (sLit "is not an indexed type family"))]
wrongKindOfFamily :: TyCon -> SDoc
wrongKindOfFamily family
= ptext (sLit "Wrong category of family instance; declaration was for a")
<+> kindOfFamily
where
kindOfFamily | isSynTyCon family = ptext (sLit "type synonym")
| isAlgTyCon family = ptext (sLit "data type")
| otherwise = pprPanic "wrongKindOfFamily" (ppr family)
\end{code}