{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 \section[TcBinds]{TcBinds} -} {-# LANGUAGE CPP, RankNTypes, ScopedTypeVariables #-} module TcBinds ( tcLocalBinds, tcTopBinds, tcRecSelBinds, tcValBinds, tcHsBootSigs, tcPolyCheck, tcSpecPrags, tcSpecWrapper, tcVectDecls, addTypecheckedBinds, TcSigInfo(..), TcSigFun, TcPragEnv, mkPragEnv, instTcTySig, instTcTySigFromId, findScopedTyVars, badBootDeclErr, mkExport ) where import {-# SOURCE #-} TcMatches ( tcGRHSsPat, tcMatchesFun ) import {-# SOURCE #-} TcExpr ( tcMonoExpr ) import {-# SOURCE #-} TcPatSyn ( tcInferPatSynDecl, tcCheckPatSynDecl, tcPatSynBuilderBind ) import DynFlags import HsSyn import HscTypes( isHsBoot ) import TcRnMonad import TcEnv import TcUnify import TcSimplify import TcEvidence import TcHsType import TcPat import TcMType import ConLike import Inst( deeplyInstantiate ) import FamInstEnv( normaliseType ) import FamInst( tcGetFamInstEnvs ) import TyCon import TcType import TysPrim import TysWiredIn import Id import Var import VarSet import VarEnv( TidyEnv ) import Module import Name import NameSet import NameEnv import SrcLoc import Bag import PatSyn import ListSetOps import ErrUtils import Digraph import Maybes import Util import BasicTypes import Outputable import FastString import Type(mkStrLitTy) import PrelNames( gHC_PRIM ) import TcValidity (checkValidType) import Control.Monad import Data.List (partition) #include "HsVersions.h" {- ********************************************************************* * * A useful helper function * * ********************************************************************* -} addTypecheckedBinds :: TcGblEnv -> [LHsBinds Id] -> TcGblEnv addTypecheckedBinds tcg_env binds | isHsBoot (tcg_src tcg_env) = tcg_env -- Do not add the code for record-selector bindings -- when compiling hs-boot files | otherwise = tcg_env { tcg_binds = foldr unionBags (tcg_binds tcg_env) binds } {- ************************************************************************ * * \subsection{Type-checking bindings} * * ************************************************************************ @tcBindsAndThen@ typechecks a @HsBinds@. The "and then" part is because it needs to know something about the {\em usage} of the things bound, so that it can create specialisations of them. So @tcBindsAndThen@ takes a function which, given an extended environment, E, typechecks the scope of the bindings returning a typechecked thing and (most important) an LIE. It is this LIE which is then used as the basis for specialising the things bound. @tcBindsAndThen@ also takes a "combiner" which glues together the bindings and the "thing" to make a new "thing". The real work is done by @tcBindWithSigsAndThen@. Recursive and non-recursive binds are handled in essentially the same way: because of uniques there are no scoping issues left. The only difference is that non-recursive bindings can bind primitive values. Even for non-recursive binding groups we add typings for each binder to the LVE for the following reason. When each individual binding is checked the type of its LHS is unified with that of its RHS; and type-checking the LHS of course requires that the binder is in scope. At the top-level the LIE is sure to contain nothing but constant dictionaries, which we resolve at the module level. Note [Polymorphic recursion] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The game plan for polymorphic recursion in the code above is * Bind any variable for which we have a type signature to an Id with a polymorphic type. Then when type-checking the RHSs we'll make a full polymorphic call. This fine, but if you aren't a bit careful you end up with a horrendous amount of partial application and (worse) a huge space leak. For example: f :: Eq a => [a] -> [a] f xs = ...f... If we don't take care, after typechecking we get f = /\a -> \d::Eq a -> let f' = f a d in \ys:[a] -> ...f'... Notice the the stupid construction of (f a d), which is of course identical to the function we're executing. In this case, the polymorphic recursion isn't being used (but that's a very common case). This can lead to a massive space leak, from the following top-level defn (post-typechecking) ff :: [Int] -> [Int] ff = f Int dEqInt Now (f dEqInt) evaluates to a lambda that has f' as a free variable; but f' is another thunk which evaluates to the same thing... and you end up with a chain of identical values all hung onto by the CAF ff. ff = f Int dEqInt = let f' = f Int dEqInt in \ys. ...f'... = let f' = let f' = f Int dEqInt in \ys. ...f'... in \ys. ...f'... Etc. NOTE: a bit of arity anaysis would push the (f a d) inside the (\ys...), which would make the space leak go away in this case Solution: when typechecking the RHSs we always have in hand the *monomorphic* Ids for each binding. So we just need to make sure that if (Method f a d) shows up in the constraints emerging from (...f...) we just use the monomorphic Id. We achieve this by adding monomorphic Ids to the "givens" when simplifying constraints. That's what the "lies_avail" is doing. Then we get f = /\a -> \d::Eq a -> letrec fm = \ys:[a] -> ...fm... in fm -} tcTopBinds :: HsValBinds Name -> TcM (TcGblEnv, TcLclEnv) -- The TcGblEnv contains the new tcg_binds and tcg_spects -- The TcLclEnv has an extended type envt for the new bindings tcTopBinds (ValBindsOut binds sigs) = do { -- Pattern synonym bindings populate the global environment (binds', (tcg_env, tcl_env)) <- tcValBinds TopLevel binds sigs $ do { gbl <- getGblEnv ; lcl <- getLclEnv ; return (gbl, lcl) } ; specs <- tcImpPrags sigs -- SPECIALISE prags for imported Ids ; let { tcg_env' = tcg_env { tcg_imp_specs = specs ++ tcg_imp_specs tcg_env } `addTypecheckedBinds` map snd binds' } ; return (tcg_env', tcl_env) } -- The top level bindings are flattened into a giant -- implicitly-mutually-recursive LHsBinds tcTopBinds (ValBindsIn {}) = panic "tcTopBinds" tcRecSelBinds :: HsValBinds Name -> TcM TcGblEnv tcRecSelBinds (ValBindsOut binds sigs) = -- tcExtendGlobalValEnv [sel_id | L _ (IdSig sel_id) <- sigs] $ -- this envt extension happens in tcValBinds do { (rec_sel_binds, tcg_env) <- discardWarnings $ tcValBinds TopLevel binds sigs getGblEnv ; let tcg_env' | isHsBoot (tcg_src tcg_env) = tcg_env | otherwise = tcg_env { tcg_binds = foldr (unionBags . snd) (tcg_binds tcg_env) rec_sel_binds } -- Do not add the code for record-selector bindings -- when compiling hs-boot files ; return tcg_env' } tcRecSelBinds (ValBindsIn {}) = panic "tcRecSelBinds" tcHsBootSigs :: HsValBinds Name -> TcM [Id] -- A hs-boot file has only one BindGroup, and it only has type -- signatures in it. The renamer checked all this tcHsBootSigs (ValBindsOut binds sigs) = do { checkTc (null binds) badBootDeclErr ; concat <$> mapM (addLocM tc_boot_sig) (filter isTypeLSig sigs) } where tc_boot_sig (TypeSig lnames hs_ty _) = mapM f lnames where f (L _ name) = do { sigma_ty <- tcHsSigType (FunSigCtxt name False) hs_ty ; return (mkVanillaGlobal name sigma_ty) } -- Notice that we make GlobalIds, not LocalIds tc_boot_sig s = pprPanic "tcHsBootSigs/tc_boot_sig" (ppr s) tcHsBootSigs groups = pprPanic "tcHsBootSigs" (ppr groups) badBootDeclErr :: MsgDoc badBootDeclErr = ptext (sLit "Illegal declarations in an hs-boot file") ------------------------ tcLocalBinds :: HsLocalBinds Name -> TcM thing -> TcM (HsLocalBinds TcId, thing) tcLocalBinds EmptyLocalBinds thing_inside = do { thing <- thing_inside ; return (EmptyLocalBinds, thing) } tcLocalBinds (HsValBinds (ValBindsOut binds sigs)) thing_inside = do { (binds', thing) <- tcValBinds NotTopLevel binds sigs thing_inside ; return (HsValBinds (ValBindsOut binds' sigs), thing) } tcLocalBinds (HsValBinds (ValBindsIn {})) _ = panic "tcLocalBinds" tcLocalBinds (HsIPBinds (IPBinds ip_binds _)) thing_inside = do { (given_ips, ip_binds') <- mapAndUnzipM (wrapLocSndM (tc_ip_bind ipClass)) ip_binds -- If the binding binds ?x = E, we must now -- discharge any ?x constraints in expr_lie -- See Note [Implicit parameter untouchables] ; (ev_binds, result) <- checkConstraints (IPSkol ips) [] given_ips thing_inside ; return (HsIPBinds (IPBinds ip_binds' ev_binds), result) } where ips = [ip | L _ (IPBind (Left (L _ ip)) _) <- ip_binds] -- I wonder if we should do these one at at time -- Consider ?x = 4 -- ?y = ?x + 1 tc_ip_bind ipClass (IPBind (Left (L _ ip)) expr) = do { ty <- newFlexiTyVarTy openTypeKind ; let p = mkStrLitTy $ hsIPNameFS ip ; ip_id <- newDict ipClass [ p, ty ] ; expr' <- tcMonoExpr expr ty ; let d = toDict ipClass p ty `fmap` expr' ; return (ip_id, (IPBind (Right ip_id) d)) } tc_ip_bind _ (IPBind (Right {}) _) = panic "tc_ip_bind" -- Coerces a `t` into a dictionry for `IP "x" t`. -- co : t -> IP "x" t toDict ipClass x ty = HsWrap $ mkWpCast $ TcCoercion $ wrapIP $ mkClassPred ipClass [x,ty] {- Note [Implicit parameter untouchables] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We add the type variables in the types of the implicit parameters as untouchables, not so much because we really must not unify them, but rather because we otherwise end up with constraints like this Num alpha, Implic { wanted = alpha ~ Int } The constraint solver solves alpha~Int by unification, but then doesn't float that solved constraint out (it's not an unsolved wanted). Result disaster: the (Num alpha) is again solved, this time by defaulting. No no no. However [Oct 10] this is all handled automatically by the untouchable-range idea. Note [Placeholder PatSyn kinds] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this (Trac #9161) {-# LANGUAGE PatternSynonyms, DataKinds #-} pattern A = () b :: A b = undefined Here, the type signature for b mentions A. But A is a pattern synonym, which is typechecked (for very good reasons; a view pattern in the RHS may mention a value binding) as part of a group of bindings. It is entirely resonable to reject this, but to do so we need A to be in the kind environment when kind-checking the signature for B. Hence the tcExtendKindEnv2 patsyn_placeholder_kinds, which adds a binding A -> AGlobal (AConLike (PatSynCon _|_)) to the environment. Then TcHsType.tcTyVar will find A in the kind environment, and will give a 'wrongThingErr' as a result. But the lookup of A won't fail. The _|_ (= panic "fakePatSynCon") works because the wrongThingErr call, in tcTyVar, doesn't look inside the TcTyThing. Note [Inlining and hs-boot files] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this example (Trac #10083): ---------- RSR.hs-boot ------------ module RSR where data RSR eqRSR :: RSR -> RSR -> Bool ---------- SR.hs ------------ module SR where import {-# SOURCE #-} RSR data SR = MkSR RSR eqSR (MkSR r1) (MkSR r2) = eqRSR r1 r2 ---------- RSR.hs ------------ module RSR where import SR data RSR = MkRSR SR -- deriving( Eq ) eqRSR (MkRSR s1) (MkRSR s2) = (eqSR s1 s2) foo x y = not (eqRSR x y) When compiling RSR we get this code RSR.eqRSR :: RSR -> RSR -> Bool RSR.eqRSR = \ (ds1 :: RSR.RSR) (ds2 :: RSR.RSR) -> case ds1 of _ { RSR.MkRSR s1 -> case ds2 of _ { RSR.MkRSR s2 -> SR.eqSR s1 s2 }} RSR.foo :: RSR -> RSR -> Bool RSR.foo = \ (x :: RSR) (y :: RSR) -> not (RSR.eqRSR x y) Now, when optimising foo: Inline eqRSR (small, non-rec) Inline eqSR (small, non-rec) but the result of inlining eqSR from SR is another call to eqRSR, so everything repeats. Neither eqSR nor eqRSR are (apparently) loop breakers. Solution: when compiling RSR, add a NOINLINE pragma to every function exported by the boot-file for RSR (if it exists). ALAS: doing so makes the boostrappted GHC itself slower by 8% overall (on Trac #9872a-d, and T1969. So I un-did this change, and parked it for now. Sigh. -} tcValBinds :: TopLevelFlag -> [(RecFlag, LHsBinds Name)] -> [LSig Name] -> TcM thing -> TcM ([(RecFlag, LHsBinds TcId)], thing) tcValBinds top_lvl binds sigs thing_inside = do { -- Typecheck the signature ; (poly_ids, sig_fn) <- tcExtendKindEnv2 patsyn_placeholder_kinds $ -- See Note [Placeholder PatSyn kinds] tcTySigs sigs ; _self_boot <- tcSelfBootInfo ; let prag_fn = mkPragEnv sigs (foldr (unionBags . snd) emptyBag binds) -- ------- See Note [Inlining and hs-boot files] (change parked) -------- -- prag_fn | isTopLevel top_lvl -- See Note [Inlining and hs-boot files] -- , SelfBoot { sb_ids = boot_id_names } <- self_boot -- = foldNameSet add_no_inl prag_fn1 boot_id_names -- | otherwise -- = prag_fn1 -- add_no_inl boot_id_name prag_fn -- = extendPragEnv prag_fn (boot_id_name, no_inl_sig boot_id_name) -- no_inl_sig name = L boot_loc (InlineSig (L boot_loc name) neverInlinePragma) -- boot_loc = mkGeneralSrcSpan (fsLit "The hs-boot file for this module") -- Extend the envt right away with all the Ids -- declared with complete type signatures -- Do not extend the TcIdBinderStack; instead -- we extend it on a per-rhs basis in tcExtendForRhs ; tcExtendLetEnvIds top_lvl [(idName id, id) | id <- poly_ids] $ do { (binds', (extra_binds', thing)) <- tcBindGroups top_lvl sig_fn prag_fn binds $ do { thing <- thing_inside -- See Note [Pattern synonym builders don't yield dependencies] ; patsyn_builders <- mapM tcPatSynBuilderBind patsyns ; let extra_binds = [ (NonRecursive, builder) | builder <- patsyn_builders ] ; return (extra_binds, thing) } ; return (binds' ++ extra_binds', thing) }} where patsyns = [psb | (_, lbinds) <- binds, L _ (PatSynBind psb) <- bagToList lbinds] patsyn_placeholder_kinds -- See Note [Placeholder PatSyn kinds] = [(name, placeholder_patsyn_tything)| PSB{ psb_id = L _ name } <- patsyns ] placeholder_patsyn_tything = AGlobal $ AConLike $ PatSynCon $ panic "fakePatSynCon" ------------------------ tcBindGroups :: TopLevelFlag -> TcSigFun -> TcPragEnv -> [(RecFlag, LHsBinds Name)] -> TcM thing -> TcM ([(RecFlag, LHsBinds TcId)], thing) -- Typecheck a whole lot of value bindings, -- one strongly-connected component at a time -- Here a "strongly connected component" has the strightforward -- meaning of a group of bindings that mention each other, -- ignoring type signatures (that part comes later) tcBindGroups _ _ _ [] thing_inside = do { thing <- thing_inside ; return ([], thing) } tcBindGroups top_lvl sig_fn prag_fn (group : groups) thing_inside = do { (group', (groups', thing)) <- tc_group top_lvl sig_fn prag_fn group $ tcBindGroups top_lvl sig_fn prag_fn groups thing_inside ; return (group' ++ groups', thing) } ------------------------ tc_group :: forall thing. TopLevelFlag -> TcSigFun -> TcPragEnv -> (RecFlag, LHsBinds Name) -> TcM thing -> TcM ([(RecFlag, LHsBinds TcId)], thing) -- Typecheck one strongly-connected component of the original program. -- We get a list of groups back, because there may -- be specialisations etc as well tc_group top_lvl sig_fn prag_fn (NonRecursive, binds) thing_inside -- A single non-recursive binding -- We want to keep non-recursive things non-recursive -- so that we desugar unlifted bindings correctly = do { let bind = case bagToList binds of [bind] -> bind [] -> panic "tc_group: empty list of binds" _ -> panic "tc_group: NonRecursive binds is not a singleton bag" ; (bind', thing) <- tc_single top_lvl sig_fn prag_fn bind thing_inside ; return ( [(NonRecursive, bind')], thing) } tc_group top_lvl sig_fn prag_fn (Recursive, binds) thing_inside = -- To maximise polymorphism, we do a new -- strongly-connected-component analysis, this time omitting -- any references to variables with type signatures. -- (This used to be optional, but isn't now.) do { traceTc "tc_group rec" (pprLHsBinds binds) ; when hasPatSyn $ recursivePatSynErr binds ; (binds1, thing) <- go sccs ; return ([(Recursive, binds1)], thing) } -- Rec them all together where hasPatSyn = anyBag (isPatSyn . unLoc) binds isPatSyn PatSynBind{} = True isPatSyn _ = False sccs :: [SCC (LHsBind Name)] sccs = stronglyConnCompFromEdgedVertices (mkEdges sig_fn binds) go :: [SCC (LHsBind Name)] -> TcM (LHsBinds TcId, thing) go (scc:sccs) = do { (binds1, ids1) <- tc_scc scc ; (binds2, thing) <- tcExtendLetEnv top_lvl ids1 $ go sccs ; return (binds1 `unionBags` binds2, thing) } go [] = do { thing <- thing_inside; return (emptyBag, thing) } tc_scc (AcyclicSCC bind) = tc_sub_group NonRecursive [bind] tc_scc (CyclicSCC binds) = tc_sub_group Recursive binds tc_sub_group = tcPolyBinds top_lvl sig_fn prag_fn Recursive recursivePatSynErr :: OutputableBndr name => LHsBinds name -> TcM a recursivePatSynErr binds = failWithTc $ hang (ptext (sLit "Recursive pattern synonym definition with following bindings:")) 2 (vcat $ map pprLBind . bagToList $ binds) where pprLoc loc = parens (ptext (sLit "defined at") <+> ppr loc) pprLBind (L loc bind) = pprWithCommas ppr (collectHsBindBinders bind) <+> pprLoc loc tc_single :: forall thing. TopLevelFlag -> TcSigFun -> TcPragEnv -> LHsBind Name -> TcM thing -> TcM (LHsBinds TcId, thing) tc_single _top_lvl sig_fn _prag_fn (L _ (PatSynBind psb@PSB{ psb_id = L _ name })) thing_inside = do { (pat_syn, aux_binds, tcg_env) <- tc_pat_syn_decl ; let tything = AConLike (PatSynCon pat_syn) ; thing <- setGblEnv tcg_env $ tcExtendGlobalEnv [tything] thing_inside ; return (aux_binds, thing) } where tc_pat_syn_decl :: TcM (PatSyn, LHsBinds TcId, TcGblEnv) tc_pat_syn_decl = case sig_fn name of Nothing -> tcInferPatSynDecl psb Just (TcPatSynSig tpsi) -> tcCheckPatSynDecl psb tpsi Just _ -> panic "tc_single" tc_single top_lvl sig_fn prag_fn lbind thing_inside = do { (binds1, ids) <- tcPolyBinds top_lvl sig_fn prag_fn NonRecursive NonRecursive [lbind] ; thing <- tcExtendLetEnv top_lvl ids thing_inside ; return (binds1, thing) } ------------------------ mkEdges :: TcSigFun -> LHsBinds Name -> [Node BKey (LHsBind Name)] type BKey = Int -- Just number off the bindings mkEdges sig_fn binds = [ (bind, key, [key | n <- nameSetElems (bind_fvs (unLoc bind)), Just key <- [lookupNameEnv key_map n], no_sig n ]) | (bind, key) <- keyd_binds ] where no_sig :: Name -> Bool no_sig n = noCompleteSig (sig_fn n) keyd_binds = bagToList binds `zip` [0::BKey ..] key_map :: NameEnv BKey -- Which binding it comes from key_map = mkNameEnv [(bndr, key) | (L _ bind, key) <- keyd_binds , bndr <- collectHsBindBinders bind ] ------------------------ tcPolyBinds :: TopLevelFlag -> TcSigFun -> TcPragEnv -> RecFlag -- Whether the group is really recursive -> RecFlag -- Whether it's recursive after breaking -- dependencies based on type signatures -> [LHsBind Name] -- None are PatSynBind -> TcM (LHsBinds TcId, [TcId]) -- Typechecks a single bunch of values bindings all together, -- and generalises them. The bunch may be only part of a recursive -- group, because we use type signatures to maximise polymorphism -- -- Returns a list because the input may be a single non-recursive binding, -- in which case the dependency order of the resulting bindings is -- important. -- -- Knows nothing about the scope of the bindings -- None of the bindings are pattern synonyms tcPolyBinds top_lvl sig_fn prag_fn rec_group rec_tc bind_list = setSrcSpan loc $ recoverM (recoveryCode binder_names sig_fn) $ do -- Set up main recover; take advantage of any type sigs { traceTc "------------------------------------------------" Outputable.empty ; traceTc "Bindings for {" (ppr binder_names) ; dflags <- getDynFlags ; type_env <- getLclTypeEnv ; let plan = decideGeneralisationPlan dflags type_env binder_names bind_list sig_fn ; traceTc "Generalisation plan" (ppr plan) ; result@(tc_binds, poly_ids) <- case plan of NoGen -> tcPolyNoGen rec_tc prag_fn sig_fn bind_list InferGen mn -> tcPolyInfer rec_tc prag_fn sig_fn mn bind_list CheckGen lbind sig -> tcPolyCheck rec_tc prag_fn sig lbind -- Check whether strict bindings are ok -- These must be non-recursive etc, and are not generalised -- They desugar to a case expression in the end ; checkStrictBinds top_lvl rec_group bind_list tc_binds poly_ids ; traceTc "} End of bindings for" (vcat [ ppr binder_names, ppr rec_group , vcat [ppr id <+> ppr (idType id) | id <- poly_ids] ]) ; return result } where binder_names = collectHsBindListBinders bind_list loc = foldr1 combineSrcSpans (map getLoc bind_list) -- The mbinds have been dependency analysed and -- may no longer be adjacent; so find the narrowest -- span that includes them all ------------------ tcPolyNoGen -- No generalisation whatsoever :: RecFlag -- Whether it's recursive after breaking -- dependencies based on type signatures -> TcPragEnv -> TcSigFun -> [LHsBind Name] -> TcM (LHsBinds TcId, [TcId]) tcPolyNoGen rec_tc prag_fn tc_sig_fn bind_list = do { (binds', mono_infos) <- tcMonoBinds rec_tc tc_sig_fn (LetGblBndr prag_fn) bind_list ; mono_ids' <- mapM tc_mono_info mono_infos ; return (binds', mono_ids') } where tc_mono_info (name, _, mono_id) = do { mono_ty' <- zonkTcType (idType mono_id) -- Zonk, mainly to expose unboxed types to checkStrictBinds ; let mono_id' = setIdType mono_id mono_ty' ; _specs <- tcSpecPrags mono_id' (lookupPragEnv prag_fn name) ; return mono_id' } -- NB: tcPrags generates error messages for -- specialisation pragmas for non-overloaded sigs -- Indeed that is why we call it here! -- So we can safely ignore _specs ------------------ tcPolyCheck :: RecFlag -- Whether it's recursive after breaking -- dependencies based on type signatures -> TcPragEnv -> TcIdSigInfo -> LHsBind Name -> TcM (LHsBinds TcId, [TcId]) -- There is just one binding, -- it binds a single variable, -- it has a complete type signature, tcPolyCheck rec_tc prag_fn sig@(TISI { sig_bndr = CompleteSig poly_id , sig_tvs = tvs_w_scoped , sig_theta = theta , sig_tau = tau , sig_ctxt = ctxt , sig_loc = loc }) bind = do { ev_vars <- newEvVars theta ; let skol_info = SigSkol ctxt (mkPhiTy theta tau) prag_sigs = lookupPragEnv prag_fn name tvs = map snd tvs_w_scoped -- Find the location of the original source type sig, if -- there is was one. This will appear in messages like -- "type variable x is bound by .. at " name = idName poly_id ; (ev_binds, (binds', [mono_info])) <- setSrcSpan loc $ checkConstraints skol_info tvs ev_vars $ tcMonoBinds rec_tc (\_ -> Just (TcIdSig sig)) LetLclBndr [bind] ; spec_prags <- tcSpecPrags poly_id prag_sigs ; poly_id <- addInlinePrags poly_id prag_sigs ; let (_, _, mono_id) = mono_info export = ABE { abe_wrap = idHsWrapper , abe_poly = poly_id , abe_mono = mono_id , abe_prags = SpecPrags spec_prags } abs_bind = L loc $ AbsBinds { abs_tvs = tvs , abs_ev_vars = ev_vars, abs_ev_binds = [ev_binds] , abs_exports = [export], abs_binds = binds' } ; return (unitBag abs_bind, [poly_id]) } tcPolyCheck _rec_tc _prag_fn sig _bind = pprPanic "tcPolyCheck" (ppr sig) ------------------ tcPolyInfer :: RecFlag -- Whether it's recursive after breaking -- dependencies based on type signatures -> TcPragEnv -> TcSigFun -> Bool -- True <=> apply the monomorphism restriction -> [LHsBind Name] -> TcM (LHsBinds TcId, [TcId]) tcPolyInfer rec_tc prag_fn tc_sig_fn mono bind_list = do { ((binds', mono_infos), tclvl, wanted) <- pushLevelAndCaptureConstraints $ tcMonoBinds rec_tc tc_sig_fn LetLclBndr bind_list ; let name_taus = [(name, idType mono_id) | (name, _, mono_id) <- mono_infos] sig_qtvs = [ tv | (_, Just sig, _) <- mono_infos , (_, tv) <- sig_tvs sig ] ; traceTc "simplifyInfer call" (ppr name_taus $$ ppr wanted) ; (qtvs, givens, ev_binds) <- simplifyInfer tclvl mono sig_qtvs name_taus wanted ; let inferred_theta = map evVarPred givens ; exports <- checkNoErrs $ mapM (mkExport prag_fn qtvs inferred_theta) mono_infos ; loc <- getSrcSpanM ; let poly_ids = map abe_poly exports abs_bind = L loc $ AbsBinds { abs_tvs = qtvs , abs_ev_vars = givens, abs_ev_binds = [ev_binds] , abs_exports = exports, abs_binds = binds' } ; traceTc "Binding:" (ppr (poly_ids `zip` map idType poly_ids)) ; return (unitBag abs_bind, poly_ids) } -- poly_ids are guaranteed zonked by mkExport -------------- mkExport :: TcPragEnv -> [TyVar] -> TcThetaType -- Both already zonked -> MonoBindInfo -> TcM (ABExport Id) -- Only called for generalisation plan IferGen, not by CheckGen or NoGen -- -- mkExport generates exports with -- zonked type variables, -- zonked poly_ids -- The former is just because no further unifications will change -- the quantified type variables, so we can fix their final form -- right now. -- The latter is needed because the poly_ids are used to extend the -- type environment; see the invariant on TcEnv.tcExtendIdEnv -- Pre-condition: the qtvs and theta are already zonked mkExport prag_fn qtvs inferred_theta (poly_name, mb_sig, mono_id) = do { mono_ty <- zonkTcType (idType mono_id) ; (poly_id, inferred) <- case mb_sig of Nothing -> do { poly_id <- mkInferredPolyId poly_name qtvs inferred_theta mono_ty ; return (poly_id, True) } Just sig | Just poly_id <- completeIdSigPolyId_maybe sig -> return (poly_id, False) | otherwise -> do { final_theta <- completeTheta inferred_theta sig ; poly_id <- mkInferredPolyId poly_name qtvs final_theta mono_ty ; return (poly_id, True) } -- NB: poly_id has a zonked type ; poly_id <- addInlinePrags poly_id prag_sigs ; spec_prags <- tcSpecPrags poly_id prag_sigs -- tcPrags requires a zonked poly_id ; let sel_poly_ty = mkSigmaTy qtvs inferred_theta mono_ty ; traceTc "mkExport: check sig" (vcat [ ppr poly_name, ppr sel_poly_ty, ppr (idType poly_id) ]) -- Perform the impedance-matching and ambiguity check -- right away. If it fails, we want to fail now (and recover -- in tcPolyBinds). If we delay checking, we get an error cascade. -- Remember we are in the tcPolyInfer case, so the type envt is -- closed (unless we are doing NoMonoLocalBinds in which case all bets -- are off) -- See Note [Impedence matching] ; (wrap, wanted) <- addErrCtxtM (mk_bind_msg inferred True poly_name (idType poly_id)) $ captureConstraints $ tcSubType_NC sig_ctxt sel_poly_ty (idType poly_id) ; ev_binds <- simplifyTop wanted ; return (ABE { abe_wrap = mkWpLet (EvBinds ev_binds) <.> wrap , abe_poly = poly_id , abe_mono = mono_id , abe_prags = SpecPrags spec_prags}) } where prag_sigs = lookupPragEnv prag_fn poly_name sig_ctxt = InfSigCtxt poly_name mkInferredPolyId :: Name -> [TyVar] -> TcThetaType -> TcType -> TcM Id -- In the inference case (no signature) this stuff figures out -- the right type variables and theta to quantify over -- See Note [Validity of inferred types] mkInferredPolyId poly_name qtvs theta mono_ty = do { fam_envs <- tcGetFamInstEnvs ; let (_co, norm_mono_ty) = normaliseType fam_envs Nominal mono_ty -- Unification may not have normalised the type, -- (see Note [Lazy flattening] in TcFlatten) so do it -- here to make it as uncomplicated as possible. -- Example: f :: [F Int] -> Bool -- should be rewritten to f :: [Char] -> Bool, if possible my_tvs2 = closeOverKinds (growThetaTyVars theta (tyVarsOfType norm_mono_ty)) -- Include kind variables! Trac #7916 ; my_theta <- pickQuantifiablePreds my_tvs2 theta ; let my_tvs = filter (`elemVarSet` my_tvs2) qtvs -- Maintain original order inferred_poly_ty = mkSigmaTy my_tvs my_theta norm_mono_ty ; addErrCtxtM (mk_bind_msg True False poly_name inferred_poly_ty) $ checkValidType (InfSigCtxt poly_name) inferred_poly_ty ; return (mkLocalId poly_name inferred_poly_ty) } mk_bind_msg :: Bool -> Bool -> Name -> TcType -> TidyEnv -> TcM (TidyEnv, SDoc) mk_bind_msg inferred want_ambig poly_name poly_ty tidy_env = do { (tidy_env', tidy_ty) <- zonkTidyTcType tidy_env poly_ty ; return (tidy_env', mk_msg tidy_ty) } where mk_msg ty = vcat [ ptext (sLit "When checking that") <+> quotes (ppr poly_name) <+> ptext (sLit "has the") <+> what <+> ptext (sLit "type") , nest 2 (ppr poly_name <+> dcolon <+> ppr ty) , ppWhen want_ambig $ ptext (sLit "Probable cause: the inferred type is ambiguous") ] what | inferred = ptext (sLit "inferred") | otherwise = ptext (sLit "specified") -- | Report the inferred constraints for an extra-constraints wildcard/hole as -- an error message, unless the PartialTypeSignatures flag is enabled. In this -- case, the extra inferred constraints are accepted without complaining. -- Returns the annotated constraints combined with the inferred constraints. completeTheta :: TcThetaType -> TcIdSigInfo -> TcM TcThetaType completeTheta inferred_theta (TISI { sig_bndr = s_bndr , sig_theta = annotated_theta }) | PartialSig { sig_cts = Just loc } <- s_bndr = do { annotated_theta <- zonkTcThetaType annotated_theta ; let inferred_diff = minusList inferred_theta annotated_theta final_theta = annotated_theta ++ inferred_diff ; partial_sigs <- xoptM Opt_PartialTypeSignatures ; warn_partial_sigs <- woptM Opt_WarnPartialTypeSignatures ; msg <- mkLongErrAt loc (mk_msg inferred_diff partial_sigs) empty ; case partial_sigs of True | warn_partial_sigs -> reportWarning msg | otherwise -> return () False -> reportError msg ; return final_theta } | otherwise = zonkTcThetaType annotated_theta -- No extra-constraints wildcard means no extra constraints will be added -- to the context, so just return the possibly empty (zonked) -- annotated_theta. where pts_hint = text "To use the inferred type, enable PartialTypeSignatures" mk_msg inferred_diff suppress_hint = vcat [ hang ((text "Found hole") <+> quotes (char '_')) 2 (text "with inferred constraints:") <+> pprTheta inferred_diff , if suppress_hint then empty else pts_hint , typeSigCtxt s_bndr ] {- Note [Partial type signatures and generalisation] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When we have a partial type signature, like f :: _ -> Int then we *always* use the InferGen plan, and hence tcPolyInfer. We do this even for a local binding with -XMonoLocalBinds. Reasons: * The TcSigInfo for 'f' has a unification variable for the '_', whose TcLevel is one level deeper than the current level. (See pushTcLevelM in tcTySig.) But NoGen doesn't increase the TcLevel like InferGen, so we lose the level invariant. * The signature might be f :: forall a. _ -> a so it really is polymorphic. It's not clear what it would mean to use NoGen on this, and indeed the ASSERT in tcLhs, in the (Just sig) case, checks that if there is a signature then we are using LetLclBndr, and hence a nested AbsBinds with increased TcLevel It might be possible to fix these difficulties somehow, but there doesn't seem much point. Indeed, adding a partial type signature is a way to get per-binding inferred generalisation. Note [Validity of inferred types] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We need to check inferred type for validity, in case it uses language extensions that are not turned on. The principle is that if the user simply adds the inferred type to the program source, it'll compile fine. See #8883. Examples that might fail: - an inferred theta that requires type equalities e.g. (F a ~ G b) or multi-parameter type classes - an inferred type that includes unboxed tuples However we don't do the ambiguity check (checkValidType omits it for InfSigCtxt) because the impedance-matching stage, which follows immediately, will do it and we don't want two error messages. Moreover, because of the impedance matching stage, the ambiguity-check suggestion of -XAllowAmbiguiousTypes will not work. Note [Impedence matching] ~~~~~~~~~~~~~~~~~~~~~~~~~ Consider f 0 x = x f n x = g [] (not x) g [] y = f 10 y g _ y = f 9 y After typechecking we'll get f_mono_ty :: a -> Bool -> Bool g_mono_ty :: [b] -> Bool -> Bool with constraints (Eq a, Num a) Note that f is polymorphic in 'a' and g in 'b'; and these are not linked. The types we really want for f and g are f :: forall a. (Eq a, Num a) => a -> Bool -> Bool g :: forall b. [b] -> Bool -> Bool We can get these by "impedance matching": tuple :: forall a b. (Eq a, Num a) => (a -> Bool -> Bool, [b] -> Bool -> Bool) tuple a b d1 d1 = let ...bind f_mono, g_mono in (f_mono, g_mono) f a d1 d2 = case tuple a Any d1 d2 of (f, g) -> f g b = case tuple Integer b dEqInteger dNumInteger of (f,g) -> g Suppose the shared quantified tyvars are qtvs and constraints theta. Then we want to check that f's polytype is more polymorphic than forall qtvs. theta => f_mono_ty and the proof is the impedance matcher. Notice that the impedance matcher may do defaulting. See Trac #7173. It also cleverly does an ambiguity check; for example, rejecting f :: F a -> a where F is a non-injective type function. -} -------------- -- If typechecking the binds fails, then return with each -- signature-less binder given type (forall a.a), to minimise -- subsequent error messages recoveryCode :: [Name] -> TcSigFun -> TcM (LHsBinds TcId, [Id]) recoveryCode binder_names sig_fn = do { traceTc "tcBindsWithSigs: error recovery" (ppr binder_names) ; let poly_ids = map mk_dummy binder_names ; return (emptyBag, poly_ids) } where mk_dummy name | Just sig <- sig_fn name , Just poly_id <- completeSigPolyId_maybe sig = poly_id | otherwise = mkLocalId name forall_a_a forall_a_a :: TcType forall_a_a = mkForAllTy openAlphaTyVar (mkTyVarTy openAlphaTyVar) {- ********************************************************************* * * Pragmas, including SPECIALISE * * ************************************************************************ Note [Handling SPECIALISE pragmas] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The basic idea is this: f:: Num a => a -> b -> a {-# SPECIALISE foo :: Int -> b -> Int #-} We check that (forall a. Num a => a -> a) is more polymorphic than Int -> Int (for which we could use tcSubType, but see below), generating a HsWrapper to connect the two, something like wrap = /\b. Int b dNumInt This wrapper is put in the TcSpecPrag, in the ABExport record of the AbsBinds. f :: (Eq a, Ix b) => a -> b -> Bool {-# SPECIALISE f :: (Ix p, Ix q) => Int -> (p,q) -> Bool #-} f = From this the typechecker generates AbsBinds [ab] [d1,d2] [([ab], f, f_mono, prags)] binds SpecPrag (wrap_fn :: forall a b. (Eq a, Ix b) => XXX -> forall p q. (Ix p, Ix q) => XXX[ Int/a, (p,q)/b ]) From these we generate: Rule: forall p, q, (dp:Ix p), (dq:Ix q). f Int (p,q) dInt ($dfInPair dp dq) = f_spec p q dp dq Spec bind: f_spec = wrap_fn Note that * The LHS of the rule may mention dictionary *expressions* (eg $dfIxPair dp dq), and that is essential because the dp, dq are needed on the RHS. * The RHS of f_spec, has a *copy* of 'binds', so that it can fully specialise it. From the TcSpecPrag, in DsBinds we generate a binding for f_spec and a RULE: f_spec :: Int -> b -> Int f_spec = wrap RULE: forall b (d:Num b). f b d = f_spec b The RULE is generated by taking apart the HsWrapper, which is a little delicate, but works. Some wrinkles 1. We don't use full-on tcSubType, because that does co and contra variance and that in turn will generate too complex a LHS for the RULE. So we use a single invocation of deeplySkolemise / deeplyInstantiate in tcSpecWrapper. (Actually I think that even the "deeply" stuff may be too much, because it introduces lambdas, though I think it can be made to work without too much trouble.) 2. We need to take care with type families (Trac #5821). Consider type instance F Int = Bool f :: Num a => a -> F a {-# SPECIALISE foo :: Int -> Bool #-} We *could* try to generate an f_spec with precisely the declared type: f_spec :: Int -> Bool f_spec = Int dNumInt |> co RULE: forall d. f Int d = f_spec |> sym co but the 'co' and 'sym co' are (a) playing no useful role, and (b) are hard to generate. At all costs we must avoid this: RULE: forall d. f Int d |> co = f_spec because the LHS will never match (indeed it's rejected in decomposeRuleLhs). So we simply do this: - Generate a constraint to check that the specialised type (after skolemiseation) is equal to the instantiated function type. - But *discard* the evidence (coercion) for that constraint, so that we ultimately generate the simpler code f_spec :: Int -> F Int f_spec = Int dNumInt RULE: forall d. f Int d = f_spec You can see this discarding happening in 3. Note that the HsWrapper can transform *any* function with the right type prefix forall ab. (Eq a, Ix b) => XXX regardless of XXX. It's sort of polymorphic in XXX. This is useful: we use the same wrapper to transform each of the class ops, as well as the dict. That's what goes on in TcInstDcls.mk_meth_spec_prags -} mkPragEnv :: [LSig Name] -> LHsBinds Name -> TcPragEnv mkPragEnv sigs binds = foldl extendPragEnv emptyNameEnv prs where prs = mapMaybe get_sig sigs get_sig :: LSig Name -> Maybe (Name, LSig Name) get_sig (L l (SpecSig lnm@(L _ nm) ty inl)) = Just (nm, L l $ SpecSig lnm ty (add_arity nm inl)) get_sig (L l (InlineSig lnm@(L _ nm) inl)) = Just (nm, L l $ InlineSig lnm (add_arity nm inl)) get_sig _ = Nothing add_arity n inl_prag -- Adjust inl_sat field to match visible arity of function | Inline <- inl_inline inl_prag -- add arity only for real INLINE pragmas, not INLINABLE = case lookupNameEnv ar_env n of Just ar -> inl_prag { inl_sat = Just ar } Nothing -> WARN( True, ptext (sLit "mkPragEnv no arity") <+> ppr n ) -- There really should be a binding for every INLINE pragma inl_prag | otherwise = inl_prag -- ar_env maps a local to the arity of its definition ar_env :: NameEnv Arity ar_env = foldrBag lhsBindArity emptyNameEnv binds extendPragEnv :: TcPragEnv -> (Name, LSig Name) -> TcPragEnv extendPragEnv prag_fn (n, sig) = extendNameEnv_Acc (:) singleton prag_fn n sig lhsBindArity :: LHsBind Name -> NameEnv Arity -> NameEnv Arity lhsBindArity (L _ (FunBind { fun_id = id, fun_matches = ms })) env = extendNameEnv env (unLoc id) (matchGroupArity ms) lhsBindArity _ env = env -- PatBind/VarBind ------------------ tcSpecPrags :: Id -> [LSig Name] -> TcM [LTcSpecPrag] -- Add INLINE and SPECIALSE pragmas -- INLINE prags are added to the (polymorphic) Id directly -- SPECIALISE prags are passed to the desugarer via TcSpecPrags -- Pre-condition: the poly_id is zonked -- Reason: required by tcSubExp tcSpecPrags poly_id prag_sigs = do { traceTc "tcSpecPrags" (ppr poly_id <+> ppr spec_sigs) ; unless (null bad_sigs) warn_discarded_sigs ; pss <- mapAndRecoverM (wrapLocM (tcSpecPrag poly_id)) spec_sigs ; return $ concatMap (\(L l ps) -> map (L l) ps) pss } where spec_sigs = filter isSpecLSig prag_sigs bad_sigs = filter is_bad_sig prag_sigs is_bad_sig s = not (isSpecLSig s || isInlineLSig s) warn_discarded_sigs = addWarnTc (hang (ptext (sLit "Discarding unexpected pragmas for") <+> ppr poly_id) 2 (vcat (map (ppr . getLoc) bad_sigs))) -------------- tcSpecPrag :: TcId -> Sig Name -> TcM [TcSpecPrag] tcSpecPrag poly_id prag@(SpecSig fun_name hs_tys inl) -- See Note [Handling SPECIALISE pragmas] -- -- The Name fun_name in the SpecSig may not be the same as that of the poly_id -- Example: SPECIALISE for a class method: the Name in the SpecSig is -- for the selector Id, but the poly_id is something like $cop -- However we want to use fun_name in the error message, since that is -- what the user wrote (Trac #8537) = addErrCtxt (spec_ctxt prag) $ do { warnIf (not (isOverloadedTy poly_ty || isInlinePragma inl)) (ptext (sLit "SPECIALISE pragma for non-overloaded function") <+> quotes (ppr fun_name)) -- Note [SPECIALISE pragmas] ; spec_prags <- mapM tc_one hs_tys ; traceTc "tcSpecPrag" (ppr poly_id $$ nest 2 (vcat (map ppr spec_prags))) ; return spec_prags } where name = idName poly_id poly_ty = idType poly_id spec_ctxt prag = hang (ptext (sLit "In the SPECIALISE pragma")) 2 (ppr prag) tc_one hs_ty = do { spec_ty <- tcHsSigType (FunSigCtxt name False) hs_ty ; wrap <- tcSpecWrapper (FunSigCtxt name True) poly_ty spec_ty ; return (SpecPrag poly_id wrap inl) } tcSpecPrag _ prag = pprPanic "tcSpecPrag" (ppr prag) -------------- tcSpecWrapper :: UserTypeCtxt -> TcType -> TcType -> TcM HsWrapper -- A simpler variant of tcSubType, used for SPECIALISE pragmas -- See Note [Handling SPECIALISE pragmas], wrinkle 1 tcSpecWrapper ctxt poly_ty spec_ty = do { (sk_wrap, inst_wrap) <- tcGen ctxt spec_ty $ \ _ spec_tau -> do { (inst_wrap, tau) <- deeplyInstantiate orig poly_ty ; _ <- unifyType spec_tau tau -- Deliberately ignore the evidence -- See Note [Handling SPECIALISE pragmas], -- wrinkle (2) ; return inst_wrap } ; return (sk_wrap <.> inst_wrap) } where orig = SpecPragOrigin ctxt -------------- tcImpPrags :: [LSig Name] -> TcM [LTcSpecPrag] -- SPECIALISE pragmas for imported things tcImpPrags prags = do { this_mod <- getModule ; dflags <- getDynFlags ; if (not_specialising dflags) then return [] else do { pss <- mapAndRecoverM (wrapLocM tcImpSpec) [L loc (name,prag) | (L loc prag@(SpecSig (L _ name) _ _)) <- prags , not (nameIsLocalOrFrom this_mod name) ] ; return $ concatMap (\(L l ps) -> map (L l) ps) pss } } where -- Ignore SPECIALISE pragmas for imported things -- when we aren't specialising, or when we aren't generating -- code. The latter happens when Haddocking the base library; -- we don't wnat complaints about lack of INLINABLE pragmas not_specialising dflags | not (gopt Opt_Specialise dflags) = True | otherwise = case hscTarget dflags of HscNothing -> True HscInterpreted -> True _other -> False tcImpSpec :: (Name, Sig Name) -> TcM [TcSpecPrag] tcImpSpec (name, prag) = do { id <- tcLookupId name ; unless (isAnyInlinePragma (idInlinePragma id)) (addWarnTc (impSpecErr name)) ; tcSpecPrag id prag } impSpecErr :: Name -> SDoc impSpecErr name = hang (ptext (sLit "You cannot SPECIALISE") <+> quotes (ppr name)) 2 (vcat [ ptext (sLit "because its definition has no INLINE/INLINABLE pragma") , parens $ sep [ ptext (sLit "or its defining module") <+> quotes (ppr mod) , ptext (sLit "was compiled without -O")]]) where mod = nameModule name {- ********************************************************************* * * Vectorisation * * ********************************************************************* -} tcVectDecls :: [LVectDecl Name] -> TcM ([LVectDecl TcId]) tcVectDecls decls = do { decls' <- mapM (wrapLocM tcVect) decls ; let ids = [lvectDeclName decl | decl <- decls', not $ lvectInstDecl decl] dups = findDupsEq (==) ids ; mapM_ reportVectDups dups ; traceTcConstraints "End of tcVectDecls" ; return decls' } where reportVectDups (first:_second:_more) = addErrAt (getSrcSpan first) $ ptext (sLit "Duplicate vectorisation declarations for") <+> ppr first reportVectDups _ = return () -------------- tcVect :: VectDecl Name -> TcM (VectDecl TcId) -- FIXME: We can't typecheck the expression of a vectorisation declaration against the vectorised -- type of the original definition as this requires internals of the vectoriser not available -- during type checking. Instead, constrain the rhs of a vectorisation declaration to be a single -- identifier (this is checked in 'rnHsVectDecl'). Fix this by enabling the use of 'vectType' -- from the vectoriser here. tcVect (HsVect s name rhs) = addErrCtxt (vectCtxt name) $ do { var <- wrapLocM tcLookupId name ; let L rhs_loc (HsVar rhs_var_name) = rhs ; rhs_id <- tcLookupId rhs_var_name ; return $ HsVect s var (L rhs_loc (HsVar rhs_id)) } {- OLD CODE: -- turn the vectorisation declaration into a single non-recursive binding ; let bind = L loc $ mkTopFunBind name [mkSimpleMatch [] rhs] sigFun = const Nothing pragFun = emptyPragEnv -- perform type inference (including generalisation) ; (binds, [id'], _) <- tcPolyInfer False True sigFun pragFun NonRecursive [bind] ; traceTc "tcVect inferred type" $ ppr (varType id') ; traceTc "tcVect bindings" $ ppr binds -- add all bindings, including the type variable and dictionary bindings produced by type -- generalisation to the right-hand side of the vectorisation declaration ; let [AbsBinds tvs evs _ evBinds actualBinds] = (map unLoc . bagToList) binds ; let [bind'] = bagToList actualBinds MatchGroup [L _ (Match _ _ (GRHSs [L _ (GRHS _ rhs')] _))] _ = (fun_matches . unLoc) bind' rhsWrapped = mkHsLams tvs evs (mkHsDictLet evBinds rhs') -- We return the type-checked 'Id', to propagate the inferred signature -- to the vectoriser - see "Note [Typechecked vectorisation pragmas]" in HsDecls ; return $ HsVect (L loc id') (Just rhsWrapped) } -} tcVect (HsNoVect s name) = addErrCtxt (vectCtxt name) $ do { var <- wrapLocM tcLookupId name ; return $ HsNoVect s var } tcVect (HsVectTypeIn _ isScalar lname rhs_name) = addErrCtxt (vectCtxt lname) $ do { tycon <- tcLookupLocatedTyCon lname ; checkTc ( not isScalar -- either we have a non-SCALAR declaration || isJust rhs_name -- or we explicitly provide a vectorised type || tyConArity tycon == 0 -- otherwise the type constructor must be nullary ) scalarTyConMustBeNullary ; rhs_tycon <- fmapMaybeM (tcLookupTyCon . unLoc) rhs_name ; return $ HsVectTypeOut isScalar tycon rhs_tycon } tcVect (HsVectTypeOut _ _ _) = panic "TcBinds.tcVect: Unexpected 'HsVectTypeOut'" tcVect (HsVectClassIn _ lname) = addErrCtxt (vectCtxt lname) $ do { cls <- tcLookupLocatedClass lname ; return $ HsVectClassOut cls } tcVect (HsVectClassOut _) = panic "TcBinds.tcVect: Unexpected 'HsVectClassOut'" tcVect (HsVectInstIn linstTy) = addErrCtxt (vectCtxt linstTy) $ do { (cls, tys) <- tcHsVectInst linstTy ; inst <- tcLookupInstance cls tys ; return $ HsVectInstOut inst } tcVect (HsVectInstOut _) = panic "TcBinds.tcVect: Unexpected 'HsVectInstOut'" vectCtxt :: Outputable thing => thing -> SDoc vectCtxt thing = ptext (sLit "When checking the vectorisation declaration for") <+> ppr thing scalarTyConMustBeNullary :: MsgDoc scalarTyConMustBeNullary = ptext (sLit "VECTORISE SCALAR type constructor must be nullary") {- Note [SPECIALISE pragmas] ~~~~~~~~~~~~~~~~~~~~~~~~~ There is no point in a SPECIALISE pragma for a non-overloaded function: reverse :: [a] -> [a] {-# SPECIALISE reverse :: [Int] -> [Int] #-} But SPECIALISE INLINE *can* make sense for GADTS: data Arr e where ArrInt :: !Int -> ByteArray# -> Arr Int ArrPair :: !Int -> Arr e1 -> Arr e2 -> Arr (e1, e2) (!:) :: Arr e -> Int -> e {-# SPECIALISE INLINE (!:) :: Arr Int -> Int -> Int #-} {-# SPECIALISE INLINE (!:) :: Arr (a, b) -> Int -> (a, b) #-} (ArrInt _ ba) !: (I# i) = I# (indexIntArray# ba i) (ArrPair _ a1 a2) !: i = (a1 !: i, a2 !: i) When (!:) is specialised it becomes non-recursive, and can usefully be inlined. Scary! So we only warn for SPECIALISE *without* INLINE for a non-overloaded function. ************************************************************************ * * tcMonoBinds * * ************************************************************************ @tcMonoBinds@ deals with a perhaps-recursive group of HsBinds. The signatures have been dealt with already. Note [Pattern bindings] ~~~~~~~~~~~~~~~~~~~~~~~ The rule for typing pattern bindings is this: ..sigs.. p = e where 'p' binds v1..vn, and 'e' may mention v1..vn, typechecks exactly like ..sigs.. x = e -- Inferred type v1 = case x of p -> v1 .. vn = case x of p -> vn Note that (f :: forall a. a -> a) = id should not typecheck because case id of { (f :: forall a. a->a) -> f } will not typecheck. -} tcMonoBinds :: RecFlag -- Whether the binding is recursive for typechecking purposes -- i.e. the binders are mentioned in their RHSs, and -- we are not rescued by a type signature -> TcSigFun -> LetBndrSpec -> [LHsBind Name] -> TcM (LHsBinds TcId, [MonoBindInfo]) tcMonoBinds is_rec sig_fn no_gen [ L b_loc (FunBind { fun_id = L nm_loc name, fun_infix = inf, fun_matches = matches, bind_fvs = fvs })] -- Single function binding, | NonRecursive <- is_rec -- ...binder isn't mentioned in RHS , Nothing <- sig_fn name -- ...with no type signature = -- In this very special case we infer the type of the -- right hand side first (it may have a higher-rank type) -- and *then* make the monomorphic Id for the LHS -- e.g. f = \(x::forall a. a->a) -> -- We want to infer a higher-rank type for f setSrcSpan b_loc $ do { rhs_ty <- newFlexiTyVarTy openTypeKind ; mono_id <- newNoSigLetBndr no_gen name rhs_ty ; (co_fn, matches') <- tcExtendIdBndrs [TcIdBndr mono_id NotTopLevel] $ -- We extend the error context even for a non-recursive -- function so that in type error messages we show the -- type of the thing whose rhs we are type checking tcMatchesFun name inf matches rhs_ty ; return (unitBag $ L b_loc $ FunBind { fun_id = L nm_loc mono_id, fun_infix = inf, fun_matches = matches', bind_fvs = fvs, fun_co_fn = co_fn, fun_tick = [] }, [(name, Nothing, mono_id)]) } tcMonoBinds _ sig_fn no_gen binds = do { tc_binds <- mapM (wrapLocM (tcLhs sig_fn no_gen)) binds -- Bring the monomorphic Ids, into scope for the RHSs ; let mono_info = getMonoBindInfo tc_binds rhs_id_env = [(name, mono_id) | (name, mb_sig, mono_id) <- mono_info , case mb_sig of Just sig -> isPartialSig sig Nothing -> True ] -- A monomorphic binding for each term variable that lacks -- a type sig. (Ones with a sig are already in scope.) ; traceTc "tcMonoBinds" $ vcat [ ppr n <+> ppr id <+> ppr (idType id) | (n,id) <- rhs_id_env] ; binds' <- tcExtendLetEnvIds NotTopLevel rhs_id_env $ mapM (wrapLocM tcRhs) tc_binds ; return (listToBag binds', mono_info) } ------------------------ -- tcLhs typechecks the LHS of the bindings, to construct the environment in which -- we typecheck the RHSs. Basically what we are doing is this: for each binder: -- if there's a signature for it, use the instantiated signature type -- otherwise invent a type variable -- You see that quite directly in the FunBind case. -- -- But there's a complication for pattern bindings: -- data T = MkT (forall a. a->a) -- MkT f = e -- Here we can guess a type variable for the entire LHS (which will be refined to T) -- but we want to get (f::forall a. a->a) as the RHS environment. -- The simplest way to do this is to typecheck the pattern, and then look up the -- bound mono-ids. Then we want to retain the typechecked pattern to avoid re-doing -- it; hence the TcMonoBind data type in which the LHS is done but the RHS isn't data TcMonoBind -- Half completed; LHS done, RHS not done = TcFunBind MonoBindInfo SrcSpan Bool (MatchGroup Name (LHsExpr Name)) | TcPatBind [MonoBindInfo] (LPat TcId) (GRHSs Name (LHsExpr Name)) TcSigmaType type MonoBindInfo = (Name, Maybe TcIdSigInfo, TcId) -- Type signature (if any), and -- the monomorphic bound things tcLhs :: TcSigFun -> LetBndrSpec -> HsBind Name -> TcM TcMonoBind tcLhs sig_fn no_gen (FunBind { fun_id = L nm_loc name, fun_infix = inf, fun_matches = matches }) | Just (TcIdSig sig) <- sig_fn name , TISI { sig_bndr = s_bndr, sig_tau = tau } <- sig = ASSERT2( case no_gen of { LetLclBndr -> True; LetGblBndr {} -> False } , ppr name ) -- { f :: ty; f x = e } is always done via CheckGen (full signature) -- or InferGen (partial signature) -- see Note [Partial type signatures and generalisation] -- Both InferGen and CheckGen gives rise to LetLclBndr do { mono_name <- newLocalName name ; let mono_id = mkLocalId mono_name tau ; case s_bndr of PartialSig { sig_nwcs = nwcs } -> addErrCtxt (typeSigCtxt s_bndr) $ emitWildcardHoleConstraints nwcs CompleteSig {} -> return () ; return (TcFunBind (name, Just sig, mono_id) nm_loc inf matches) } | otherwise = do { mono_ty <- newFlexiTyVarTy openTypeKind ; mono_id <- newNoSigLetBndr no_gen name mono_ty ; return (TcFunBind (name, Nothing, mono_id) nm_loc inf matches) } -- TODO: emit Hole Constraints for wildcards tcLhs sig_fn no_gen (PatBind { pat_lhs = pat, pat_rhs = grhss }) = do { let tc_pat exp_ty = tcLetPat sig_fn no_gen pat exp_ty $ mapM lookup_info (collectPatBinders pat) -- After typechecking the pattern, look up the binder -- names, which the pattern has brought into scope. lookup_info :: Name -> TcM MonoBindInfo lookup_info name = do { mono_id <- tcLookupId name ; let mb_sig = case sig_fn name of Just (TcIdSig sig) -> Just sig _ -> Nothing ; return (name, mb_sig, mono_id) } ; ((pat', infos), pat_ty) <- addErrCtxt (patMonoBindsCtxt pat grhss) $ tcInfer tc_pat ; return (TcPatBind infos pat' grhss pat_ty) } tcLhs _ _ other_bind = pprPanic "tcLhs" (ppr other_bind) -- AbsBind, VarBind impossible ------------------- tcRhs :: TcMonoBind -> TcM (HsBind TcId) tcRhs (TcFunBind info@(_, mb_sig, mono_id) loc inf matches) = tcExtendForRhs [info] $ tcExtendTyVarEnv2 (lexically_scoped_tvs mb_sig) $ do { traceTc "tcRhs: fun bind" (ppr mono_id $$ ppr (idType mono_id)) ; (co_fn, matches') <- tcMatchesFun (idName mono_id) inf matches (idType mono_id) ; return (FunBind { fun_id = L loc mono_id, fun_infix = inf , fun_matches = matches' , fun_co_fn = co_fn , bind_fvs = placeHolderNamesTc , fun_tick = [] }) } where lexically_scoped_tvs :: Maybe TcIdSigInfo -> [(Name, TcTyVar)] lexically_scoped_tvs (Just (TISI { sig_bndr = s_bndr, sig_tvs = user_tvs })) = hole_tvs ++ [(n, tv) | (Just n, tv) <- user_tvs] where hole_tvs = case s_bndr of -- See RnBinds: Note [Scoping of named wildcards] PartialSig { sig_nwcs = nwcs } -> nwcs CompleteSig {} -> [] lexically_scoped_tvs _ = [] tcRhs (TcPatBind infos pat' grhss pat_ty) = -- When we are doing pattern bindings we *don't* bring any scoped -- type variables into scope unlike function bindings -- Wny not? They are not completely rigid. -- That's why we have the special case for a single FunBind in tcMonoBinds tcExtendForRhs infos $ do { traceTc "tcRhs: pat bind" (ppr pat' $$ ppr pat_ty) ; grhss' <- addErrCtxt (patMonoBindsCtxt pat' grhss) $ tcGRHSsPat grhss pat_ty ; return (PatBind { pat_lhs = pat', pat_rhs = grhss', pat_rhs_ty = pat_ty , bind_fvs = placeHolderNamesTc , pat_ticks = ([],[]) }) } tcExtendForRhs :: [MonoBindInfo] -> TcM a -> TcM a -- Extend the TcIdBinderStack for the RHS of the binding, with -- the monomorphic Id. That way, if we have, say -- f = \x -> blah -- and something goes wrong in 'blah', we get a "relevant binding" -- looking like f :: alpha -> beta -- This applies if 'f' has a type signature too: -- f :: forall a. [a] -> [a] -- f x = True -- We can't unify True with [a], and a relevant binding is f :: [a] -> [a] -- If we had the *polymorphic* version of f in the TcIdBinderStack, it -- would not be reported as relevant, because its type is closed tcExtendForRhs infos thing_inside = tcExtendIdBndrs [TcIdBndr mono_id NotTopLevel | (_, _, mono_id) <- infos] thing_inside -- NotTopLevel: it's a monomorphic binding --------------------- getMonoBindInfo :: [Located TcMonoBind] -> [MonoBindInfo] getMonoBindInfo tc_binds = foldr (get_info . unLoc) [] tc_binds where get_info (TcFunBind info _ _ _) rest = info : rest get_info (TcPatBind infos _ _ _) rest = infos ++ rest {- ************************************************************************ * * Signatures * * ************************************************************************ Type signatures are tricky. See Note [Signature skolems] in TcType @tcSigs@ checks the signatures for validity, and returns a list of {\em freshly-instantiated} signatures. That is, the types are already split up, and have fresh type variables installed. All non-type-signature "RenamedSigs" are ignored. The @TcSigInfo@ contains @TcTypes@ because they are unified with the variable's type, and after that checked to see whether they've been instantiated. Note [Scoped tyvars] ~~~~~~~~~~~~~~~~~~~~ The -XScopedTypeVariables flag brings lexically-scoped type variables into scope for any explicitly forall-quantified type variables: f :: forall a. a -> a f x = e Then 'a' is in scope inside 'e'. However, we do *not* support this - For pattern bindings e.g f :: forall a. a->a (f,g) = e Note [Signature skolems] ~~~~~~~~~~~~~~~~~~~~~~~~ When instantiating a type signature, we do so with either skolems or SigTv meta-type variables depending on the use_skols boolean. This variable is set True when we are typechecking a single function binding; and False for pattern bindings and a group of several function bindings. Reason: in the latter cases, the "skolems" can be unified together, so they aren't properly rigid in the type-refinement sense. NB: unless we are doing H98, each function with a sig will be done separately, even if it's mutually recursive, so use_skols will be True Note [Only scoped tyvars are in the TyVarEnv] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We are careful to keep only the *lexically scoped* type variables in the type environment. Why? After all, the renamer has ensured that only legal occurrences occur, so we could put all type variables into the type env. But we want to check that two distinct lexically scoped type variables do not map to the same internal type variable. So we need to know which the lexically-scoped ones are... and at the moment we do that by putting only the lexically scoped ones into the environment. Note [Instantiate sig with fresh variables] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It's vital to instantiate a type signature with fresh variables. For example: type T = forall a. [a] -> [a] f :: T; f = g where { g :: T; g = } We must not use the same 'a' from the defn of T at both places!! (Instantiation is only necessary because of type synonyms. Otherwise, it's all cool; each signature has distinct type variables from the renamer.) Note [Fail eagerly on bad signatures] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If a type signaure is wrong, fail immediately: * the type sigs may bind type variables, so proceeding without them can lead to a cascade of errors * the type signature might be ambiguous, in which case checking the code against the signature will give a very similar error to the ambiguity error. ToDo: this means we fall over if any type sig is wrong (eg at the top level of the module), which is over-conservative -} tcTySigs :: [LSig Name] -> TcM ([TcId], TcSigFun) tcTySigs hs_sigs = checkNoErrs $ -- See Note [Fail eagerly on bad signatures] do { ty_sigs_s <- mapAndRecoverM tcTySig hs_sigs ; let ty_sigs = concat ty_sigs_s poly_ids = mapMaybe completeSigPolyId_maybe ty_sigs -- The returned [TcId] are the ones for which we have -- a complete type signature. -- See Note [Complete and partial type signatures] env = mkNameEnv [(getName sig, sig) | sig <- ty_sigs] ; return (poly_ids, lookupNameEnv env) } tcTySig :: LSig Name -> TcM [TcSigInfo] tcTySig (L _ (IdSig id)) = do { sig <- instTcTySigFromId id ; return [TcIdSig sig] } tcTySig (L loc (TypeSig names@(L _ name1 : _) hs_ty wcs)) = setSrcSpan loc $ pushTcLevelM_ $ -- When instantiating the signature, do so "one level in" -- so that they can be unified under the forall tcWildcardBinders wcs $ \ wc_prs -> do { sigma_ty <- tcHsSigType (FunSigCtxt name1 False) hs_ty ; mapM (do_one wc_prs sigma_ty) names } where extra_cts (L _ (HsForAllTy _ extra _ _ _)) = extra extra_cts _ = Nothing do_one wc_prs sigma_ty (L _ name) = do { let ctxt = FunSigCtxt name True ; sig <- instTcTySig ctxt hs_ty sigma_ty (extra_cts hs_ty) wc_prs name ; return (TcIdSig sig) } tcTySig (L loc (PatSynSig (L _ name) (_, qtvs) req prov ty)) = setSrcSpan loc $ do { traceTc "tcTySig {" $ ppr name $$ ppr qtvs $$ ppr req $$ ppr prov $$ ppr ty ; let ctxt = PatSynCtxt name ; tcHsTyVarBndrs qtvs $ \ qtvs' -> do { ty' <- tcHsSigType ctxt ty ; req' <- tcHsContext req ; prov' <- tcHsContext prov -- These are /signatures/ so we zonk to squeeze out any kind -- unification variables. Thta has happened automatically in tcHsSigType ; req' <- zonkTcThetaType req' ; prov' <- zonkTcThetaType prov' ; qtvs' <- mapM zonkQuantifiedTyVar qtvs' ; let (_, pat_ty) = tcSplitFunTys ty' univ_set = tyVarsOfType pat_ty (univ_tvs, ex_tvs) = partition (`elemVarSet` univ_set) qtvs' bad_tvs = varSetElems (tyVarsOfTypes req' `minusVarSet` univ_set) ; unless (null bad_tvs) $ addErr $ hang (ptext (sLit "The 'required' context") <+> quotes (pprTheta req')) 2 (ptext (sLit "mentions existential type variable") <> plural bad_tvs <+> pprQuotedList bad_tvs) ; traceTc "tcTySig }" $ ppr (ex_tvs, prov') $$ ppr (univ_tvs, req') $$ ppr ty' ; let tpsi = TPSI{ patsig_name = name, patsig_tau = ty', patsig_ex = ex_tvs, patsig_univ = univ_tvs, patsig_prov = prov', patsig_req = req' } ; return [TcPatSynSig tpsi] }} tcTySig _ = return [] instTcTySigFromId :: Id -> TcM TcIdSigInfo -- Used for instance methods and record selectors instTcTySigFromId id = do { let name = idName id loc = getSrcSpan name ; (tvs, theta, tau) <- tcInstType (tcInstSigTyVarsLoc loc) (idType id) ; return (TISI { sig_bndr = CompleteSig id , sig_tvs = [(Nothing, tv) | tv <- tvs] , sig_theta = theta , sig_tau = tau , sig_ctxt = FunSigCtxt name False -- Do not report redundant constraints for -- instance methods and record selectors , sig_loc = loc }) } instTcTySig :: UserTypeCtxt -> LHsType Name -> TcType -> Maybe SrcSpan -- Just loc <=> an extra-constraints -- wildcard is present at location loc. -> [(Name, TcTyVar)] -- Named wildcards -> Name -- Name of the function -> TcM TcIdSigInfo instTcTySig ctxt hs_ty sigma_ty extra_cts nwcs name = do { (inst_tvs, theta, tau) <- tcInstType tcInstSigTyVars sigma_ty ; let bndr | isNothing extra_cts && null nwcs = CompleteSig (mkLocalId name sigma_ty) | otherwise = PartialSig { sig_name = name, sig_nwcs = nwcs , sig_cts = extra_cts, sig_hs_ty = hs_ty } ; return (TISI { sig_bndr = bndr , sig_tvs = findScopedTyVars hs_ty sigma_ty inst_tvs , sig_theta = theta , sig_tau = tau , sig_ctxt = ctxt , sig_loc = getLoc hs_ty -- SrcSpan from the signature }) } ------------------------------- data GeneralisationPlan = NoGen -- No generalisation, no AbsBinds | InferGen -- Implicit generalisation; there is an AbsBinds Bool -- True <=> apply the MR; generalise only unconstrained type vars | CheckGen (LHsBind Name) TcIdSigInfo -- One binding with a signature -- Explicit generalisation; there is an AbsBinds -- A consequence of the no-AbsBinds choice (NoGen) is that there is -- no "polymorphic Id" and "monmomorphic Id"; there is just the one instance Outputable GeneralisationPlan where ppr NoGen = ptext (sLit "NoGen") ppr (InferGen b) = ptext (sLit "InferGen") <+> ppr b ppr (CheckGen _ s) = ptext (sLit "CheckGen") <+> ppr s decideGeneralisationPlan :: DynFlags -> TcTypeEnv -> [Name] -> [LHsBind Name] -> TcSigFun -> GeneralisationPlan decideGeneralisationPlan dflags type_env bndr_names lbinds sig_fn | strict_pat_binds = NoGen | Just (lbind, sig) <- one_funbind_with_sig = if isPartialSig sig -- See Note [Partial type signatures and generalisation] then infer_plan else CheckGen lbind sig | mono_local_binds = NoGen | otherwise = infer_plan where infer_plan = InferGen mono_restriction bndr_set = mkNameSet bndr_names binds = map unLoc lbinds strict_pat_binds = any isStrictHsBind binds -- Strict patterns (top level bang or unboxed tuple) must not -- be polymorphic, because we are going to force them -- See Trac #4498, #8762 mono_restriction = xopt Opt_MonomorphismRestriction dflags && any restricted binds is_closed_ns :: NameSet -> Bool -> Bool is_closed_ns ns b = foldNameSet ((&&) . is_closed_id) b ns -- ns are the Names referred to from the RHS of this bind is_closed_id :: Name -> Bool -- See Note [Bindings with closed types] in TcRnTypes is_closed_id name | name `elemNameSet` bndr_set = True -- Ignore binders in this groups, of course | Just thing <- lookupNameEnv type_env name = case thing of ATcId { tct_closed = cl } -> isTopLevel cl -- This is the key line ATyVar {} -> False -- In-scope type variables AGlobal {} -> True -- are not closed! _ -> pprPanic "is_closed_id" (ppr name) | otherwise = WARN( isInternalName name, ppr name ) True -- The free-var set for a top level binding mentions -- imported things too, so that we can report unused imports -- These won't be in the local type env. -- Ditto class method etc from the current module mono_local_binds = xopt Opt_MonoLocalBinds dflags && not closed_flag closed_flag = foldr (is_closed_ns . bind_fvs) True binds no_sig n = noCompleteSig (sig_fn n) -- With OutsideIn, all nested bindings are monomorphic -- except a single function binding with a signature one_funbind_with_sig | [lbind@(L _ (FunBind { fun_id = v }))] <- lbinds , Just (TcIdSig sig) <- sig_fn (unLoc v) = Just (lbind, sig) | otherwise = Nothing -- The Haskell 98 monomorphism resetriction restricted (PatBind {}) = True restricted (VarBind { var_id = v }) = no_sig v restricted (FunBind { fun_id = v, fun_matches = m }) = restricted_match m && no_sig (unLoc v) restricted (PatSynBind {}) = panic "isRestrictedGroup/unrestricted PatSynBind" restricted (AbsBinds {}) = panic "isRestrictedGroup/unrestricted AbsBinds" restricted_match (MG { mg_alts = L _ (Match _ [] _ _) : _ }) = True restricted_match _ = False -- No args => like a pattern binding -- Some args => a function binding ------------------- checkStrictBinds :: TopLevelFlag -> RecFlag -> [LHsBind Name] -> LHsBinds TcId -> [Id] -> TcM () -- Check that non-overloaded unlifted bindings are -- a) non-recursive, -- b) not top level, -- c) not a multiple-binding group (more or less implied by (a)) checkStrictBinds top_lvl rec_group orig_binds tc_binds poly_ids | any_unlifted_bndr || any_strict_pat -- This binding group must be matched strictly = do { check (isNotTopLevel top_lvl) (strictBindErr "Top-level" any_unlifted_bndr orig_binds) ; check (isNonRec rec_group) (strictBindErr "Recursive" any_unlifted_bndr orig_binds) ; check (all is_monomorphic (bagToList tc_binds)) (polyBindErr orig_binds) -- data Ptr a = Ptr Addr# -- f x = let p@(Ptr y) = ... in ... -- Here the binding for 'p' is polymorphic, but does -- not mix with an unlifted binding for 'y'. You should -- use a bang pattern. Trac #6078. ; check (isSingleton orig_binds) (strictBindErr "Multiple" any_unlifted_bndr orig_binds) -- Complain about a binding that looks lazy -- e.g. let I# y = x in ... -- Remember, in checkStrictBinds we are going to do strict -- matching, so (for software engineering reasons) we insist -- that the strictness is manifest on each binding -- However, lone (unboxed) variables are ok ; check (not any_pat_looks_lazy) (unliftedMustBeBang orig_binds) } | otherwise = traceTc "csb2" (ppr [(id, idType id) | id <- poly_ids]) >> return () where any_unlifted_bndr = any is_unlifted poly_ids any_strict_pat = any (isStrictHsBind . unLoc) orig_binds any_pat_looks_lazy = any (looksLazyPatBind . unLoc) orig_binds is_unlifted id = case tcSplitSigmaTy (idType id) of (_, _, rho) -> isUnLiftedType rho -- For the is_unlifted check, we need to look inside polymorphism -- and overloading. E.g. x = (# 1, True #) -- would get type forall a. Num a => (# a, Bool #) -- and we want to reject that. See Trac #9140 is_monomorphic (L _ (AbsBinds { abs_tvs = tvs, abs_ev_vars = evs })) = null tvs && null evs is_monomorphic _ = True check :: Bool -> MsgDoc -> TcM () -- Just like checkTc, but with a special case for module GHC.Prim: -- see Note [Compiling GHC.Prim] check True _ = return () check False err = do { mod <- getModule ; checkTc (mod == gHC_PRIM) err } unliftedMustBeBang :: [LHsBind Name] -> SDoc unliftedMustBeBang binds = hang (text "Pattern bindings containing unlifted types should use an outermost bang pattern:") 2 (vcat (map ppr binds)) polyBindErr :: [LHsBind Name] -> SDoc polyBindErr binds = hang (ptext (sLit "You can't mix polymorphic and unlifted bindings")) 2 (vcat [vcat (map ppr binds), ptext (sLit "Probable fix: use a bang pattern")]) strictBindErr :: String -> Bool -> [LHsBind Name] -> SDoc strictBindErr flavour any_unlifted_bndr binds = hang (text flavour <+> msg <+> ptext (sLit "aren't allowed:")) 2 (vcat (map ppr binds)) where msg | any_unlifted_bndr = ptext (sLit "bindings for unlifted types") | otherwise = ptext (sLit "bang-pattern or unboxed-tuple bindings") {- Note [Compiling GHC.Prim] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Module GHC.Prim has no source code: it is the host module for primitive, built-in functions and types. However, for Haddock-ing purposes we generate (via utils/genprimopcode) a fake source file GHC/Prim.hs, and give it to Haddock, so that it can generate documentation. It contains definitions like nullAddr# :: NullAddr# which would normally be rejected as a top-level unlifted binding. But we don't want to complain, because we are only "compiling" this fake mdule for documentation purposes. Hence this hacky test for gHC_PRIM in checkStrictBinds. (We only make the test if things look wrong, so there is no cost in the common case.) -} {- ********************************************************************* * * Error contexts and messages * * ********************************************************************* -} -- This one is called on LHS, when pat and grhss are both Name -- and on RHS, when pat is TcId and grhss is still Name patMonoBindsCtxt :: (OutputableBndr id, Outputable body) => LPat id -> GRHSs Name body -> SDoc patMonoBindsCtxt pat grhss = hang (ptext (sLit "In a pattern binding:")) 2 (pprPatBind pat grhss) typeSigCtxt :: TcIdSigBndr -> SDoc typeSigCtxt (PartialSig { sig_name = n, sig_hs_ty = hs_ty }) = vcat [ ptext (sLit "In the type signature for:") , nest 2 (pprPrefixOcc n <+> dcolon <+> ppr hs_ty) ] typeSigCtxt (CompleteSig id) = vcat [ ptext (sLit "In the type signature for:") , nest 2 (pprPrefixOcc id <+> dcolon <+> ppr (idType id)) ]