{-# LANGUAGE CPP #-} {-# LANGUAGE TypeFamilies #-} {-# OPTIONS_GHC -Wno-incomplete-record-updates #-} module GHC.Rename.Splice ( rnTopSpliceDecls, rnSpliceType, rnSpliceExpr, rnSplicePat, rnSpliceDecl, rnBracket, checkThLocalName , traceSplice, SpliceInfo(..) ) where #include "HsVersions.h" import GHC.Prelude import GHC.Types.Name import GHC.Types.Name.Set import GHC.Hs import GHC.Types.Name.Reader import GHC.Tc.Utils.Monad import GHC.Driver.Env.Types import GHC.Rename.Env import GHC.Rename.Utils ( HsDocContext(..), newLocalBndrRn ) import GHC.Rename.Unbound ( isUnboundName ) import GHC.Rename.Module ( rnSrcDecls, findSplice ) import GHC.Rename.Pat ( rnPat ) import GHC.Types.Basic ( TopLevelFlag, isTopLevel ) import GHC.Types.SourceText ( SourceText(..) ) import GHC.Utils.Outputable import GHC.Unit.Module import GHC.Types.SrcLoc import GHC.Rename.HsType ( rnLHsType ) import Control.Monad ( unless, when ) import {-# SOURCE #-} GHC.Rename.Expr ( rnLExpr ) import GHC.Tc.Utils.Env ( checkWellStaged, tcMetaTy ) import GHC.Driver.Session import GHC.Data.FastString import GHC.Utils.Logger ( dumpIfSet_dyn_printer, DumpFormat (..), getLogger ) import GHC.Utils.Panic import GHC.Driver.Hooks import GHC.Builtin.Names.TH ( decsQTyConName, expQTyConName, liftName , patQTyConName, quoteDecName, quoteExpName , quotePatName, quoteTypeName, typeQTyConName) import {-# SOURCE #-} GHC.Tc.Gen.Expr ( tcCheckPolyExpr ) import {-# SOURCE #-} GHC.Tc.Gen.Splice ( runMetaD , runMetaE , runMetaP , runMetaT , tcTopSpliceExpr ) import GHC.Tc.Utils.Zonk import GHCi.RemoteTypes ( ForeignRef ) import qualified Language.Haskell.TH as TH (Q) import qualified GHC.LanguageExtensions as LangExt {- ************************************************************************ * * Template Haskell brackets * * ************************************************************************ -} rnBracket :: HsExpr GhcPs -> HsBracket GhcPs -> RnM (HsExpr GhcRn, FreeVars) rnBracket e br_body = addErrCtxt (quotationCtxtDoc br_body) $ do { -- Check that -XTemplateHaskellQuotes is enabled and available thQuotesEnabled <- xoptM LangExt.TemplateHaskellQuotes ; unless thQuotesEnabled $ failWith ( vcat [ text "Syntax error on" <+> ppr e , text ("Perhaps you intended to use TemplateHaskell" ++ " or TemplateHaskellQuotes") ] ) -- Check for nested brackets ; cur_stage <- getStage ; case cur_stage of { Splice Typed -> checkTc (isTypedBracket br_body) illegalUntypedBracket ; Splice Untyped -> checkTc (not (isTypedBracket br_body)) illegalTypedBracket ; RunSplice _ -> -- See Note [RunSplice ThLevel] in GHC.Tc.Types. pprPanic "rnBracket: Renaming bracket when running a splice" (ppr e) ; Comp -> return () ; Brack {} -> failWithTc illegalBracket } -- Brackets are desugared to code that mentions the TH package ; recordThUse ; case isTypedBracket br_body of True -> do { traceRn "Renaming typed TH bracket" empty ; (body', fvs_e) <- setStage (Brack cur_stage RnPendingTyped) $ rn_bracket cur_stage br_body ; return (HsBracket noExtField body', fvs_e) } False -> do { traceRn "Renaming untyped TH bracket" empty ; ps_var <- newMutVar [] ; (body', fvs_e) <- -- See Note [Rebindable syntax and Template Haskell] unsetXOptM LangExt.RebindableSyntax $ setStage (Brack cur_stage (RnPendingUntyped ps_var)) $ rn_bracket cur_stage br_body ; pendings <- readMutVar ps_var ; return (HsRnBracketOut noExtField body' pendings, fvs_e) } } rn_bracket :: ThStage -> HsBracket GhcPs -> RnM (HsBracket GhcRn, FreeVars) rn_bracket outer_stage br@(VarBr x flg rdr_name) = do { name <- lookupOccRn rdr_name ; this_mod <- getModule ; when (flg && nameIsLocalOrFrom this_mod name) $ -- Type variables can be quoted in TH. See #5721. do { mb_bind_lvl <- lookupLocalOccThLvl_maybe name ; case mb_bind_lvl of { Nothing -> return () -- Can happen for data constructors, -- but nothing needs to be done for them ; Just (top_lvl, bind_lvl) -- See Note [Quoting names] | isTopLevel top_lvl -> when (isExternalName name) (keepAlive name) | otherwise -> do { traceRn "rn_bracket VarBr" (ppr name <+> ppr bind_lvl <+> ppr outer_stage) ; checkTc (thLevel outer_stage + 1 == bind_lvl) (quotedNameStageErr br) } } } ; return (VarBr x flg name, unitFV name) } rn_bracket _ (ExpBr x e) = do { (e', fvs) <- rnLExpr e ; return (ExpBr x e', fvs) } rn_bracket _ (PatBr x p) = rnPat ThPatQuote p $ \ p' -> return (PatBr x p', emptyFVs) rn_bracket _ (TypBr x t) = do { (t', fvs) <- rnLHsType TypBrCtx t ; return (TypBr x t', fvs) } rn_bracket _ (DecBrL x decls) = do { group <- groupDecls decls ; gbl_env <- getGblEnv ; let new_gbl_env = gbl_env { tcg_dus = emptyDUs } -- The emptyDUs is so that we just collect uses for this -- group alone in the call to rnSrcDecls below ; (tcg_env, group') <- setGblEnv new_gbl_env $ rnSrcDecls group -- Discard the tcg_env; it contains only extra info about fixity ; traceRn "rn_bracket dec" (ppr (tcg_dus tcg_env) $$ ppr (duUses (tcg_dus tcg_env))) ; return (DecBrG x group', duUses (tcg_dus tcg_env)) } where groupDecls :: [LHsDecl GhcPs] -> RnM (HsGroup GhcPs) groupDecls decls = do { (group, mb_splice) <- findSplice decls ; case mb_splice of { Nothing -> return group ; Just (splice, rest) -> do { group' <- groupDecls rest ; let group'' = appendGroups group group' ; return group'' { hs_splcds = noLoc splice : hs_splcds group' } } }} rn_bracket _ (DecBrG {}) = panic "rn_bracket: unexpected DecBrG" rn_bracket _ (TExpBr x e) = do { (e', fvs) <- rnLExpr e ; return (TExpBr x e', fvs) } quotationCtxtDoc :: HsBracket GhcPs -> SDoc quotationCtxtDoc br_body = hang (text "In the Template Haskell quotation") 2 (ppr br_body) illegalBracket :: SDoc illegalBracket = text "Template Haskell brackets cannot be nested" <+> text "(without intervening splices)" illegalTypedBracket :: SDoc illegalTypedBracket = text "Typed brackets may only appear in typed splices." illegalUntypedBracket :: SDoc illegalUntypedBracket = text "Untyped brackets may only appear in untyped splices." quotedNameStageErr :: HsBracket GhcPs -> SDoc quotedNameStageErr br = sep [ text "Stage error: the non-top-level quoted name" <+> ppr br , text "must be used at the same stage at which it is bound" ] {- ********************************************************* * * Splices * * ********************************************************* Note [Free variables of typed splices] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider renaming this: f = ... h = ...$(thing "f")... where the splice is a *typed* splice. The splice can expand into literally anything, so when we do dependency analysis we must assume that it might mention 'f'. So we simply treat all locally-defined names as mentioned by any splice. This is terribly brutal, but I don't see what else to do. For example, it'll mean that every locally-defined thing will appear to be used, so no unused-binding warnings. But if we miss the dependency, then we might typecheck 'h' before 'f', and that will crash the type checker because 'f' isn't in scope. Currently, I'm not treating a splice as also mentioning every import, which is a bit inconsistent -- but there are a lot of them. We might thereby get some bogus unused-import warnings, but we won't crash the type checker. Not very satisfactory really. Note [Renamer errors] ~~~~~~~~~~~~~~~~~~~~~ It's important to wrap renamer calls in checkNoErrs, because the renamer does not fail for out of scope variables etc. Instead it returns a bogus term/type, so that it can report more than one error. We don't want the type checker to see these bogus unbound variables. -} rnSpliceGen :: (HsSplice GhcRn -> RnM (a, FreeVars)) -- Outside brackets, run splice -> (HsSplice GhcRn -> (PendingRnSplice, a)) -- Inside brackets, make it pending -> HsSplice GhcPs -> RnM (a, FreeVars) rnSpliceGen run_splice pend_splice splice = addErrCtxt (spliceCtxt splice) $ do { stage <- getStage ; case stage of Brack pop_stage RnPendingTyped -> do { checkTc is_typed_splice illegalUntypedSplice ; (splice', fvs) <- setStage pop_stage $ rnSplice splice ; let (_pending_splice, result) = pend_splice splice' ; return (result, fvs) } Brack pop_stage (RnPendingUntyped ps_var) -> do { checkTc (not is_typed_splice) illegalTypedSplice ; (splice', fvs) <- setStage pop_stage $ rnSplice splice ; let (pending_splice, result) = pend_splice splice' ; ps <- readMutVar ps_var ; writeMutVar ps_var (pending_splice : ps) ; return (result, fvs) } _ -> do { checkTopSpliceAllowed splice ; (splice', fvs1) <- checkNoErrs $ setStage (Splice splice_type) $ rnSplice splice -- checkNoErrs: don't attempt to run the splice if -- renaming it failed; otherwise we get a cascade of -- errors from e.g. unbound variables ; (result, fvs2) <- run_splice splice' ; return (result, fvs1 `plusFV` fvs2) } } where is_typed_splice = isTypedSplice splice splice_type = if is_typed_splice then Typed else Untyped -- Nested splices are fine without TemplateHaskell because they -- are not executed until the top-level splice is run. checkTopSpliceAllowed :: HsSplice GhcPs -> RnM () checkTopSpliceAllowed splice = do let (herald, ext) = spliceExtension splice extEnabled <- xoptM ext unless extEnabled (failWith $ text herald <+> text "are not permitted without" <+> ppr ext) where spliceExtension :: HsSplice GhcPs -> (String, LangExt.Extension) spliceExtension (HsQuasiQuote {}) = ("Quasi-quotes", LangExt.QuasiQuotes) spliceExtension (HsTypedSplice {}) = ("Top-level splices", LangExt.TemplateHaskell) spliceExtension (HsUntypedSplice {}) = ("Top-level splices", LangExt.TemplateHaskell) spliceExtension s@(HsSpliced {}) = pprPanic "spliceExtension" (ppr s) ------------------ -- | Returns the result of running a splice and the modFinalizers collected -- during the execution. -- -- See Note [Delaying modFinalizers in untyped splices]. runRnSplice :: UntypedSpliceFlavour -> (LHsExpr GhcTc -> TcRn res) -> (res -> SDoc) -- How to pretty-print res -- Usually just ppr, but not for [Decl] -> HsSplice GhcRn -- Always untyped -> TcRn (res, [ForeignRef (TH.Q ())]) runRnSplice flavour run_meta ppr_res splice = do { hooks <- hsc_hooks <$> getTopEnv ; splice' <- case runRnSpliceHook hooks of Nothing -> return splice Just h -> h splice ; let the_expr = case splice' of HsUntypedSplice _ _ _ e -> e HsQuasiQuote _ _ q qs str -> mkQuasiQuoteExpr flavour q qs str HsTypedSplice {} -> pprPanic "runRnSplice" (ppr splice) HsSpliced {} -> pprPanic "runRnSplice" (ppr splice) -- Typecheck the expression ; meta_exp_ty <- tcMetaTy meta_ty_name ; zonked_q_expr <- zonkTopLExpr =<< tcTopSpliceExpr Untyped (tcCheckPolyExpr the_expr meta_exp_ty) -- Run the expression ; mod_finalizers_ref <- newTcRef [] ; result <- setStage (RunSplice mod_finalizers_ref) $ run_meta zonked_q_expr ; mod_finalizers <- readTcRef mod_finalizers_ref ; traceSplice (SpliceInfo { spliceDescription = what , spliceIsDecl = is_decl , spliceSource = Just the_expr , spliceGenerated = ppr_res result }) ; return (result, mod_finalizers) } where meta_ty_name = case flavour of UntypedExpSplice -> expQTyConName UntypedPatSplice -> patQTyConName UntypedTypeSplice -> typeQTyConName UntypedDeclSplice -> decsQTyConName what = case flavour of UntypedExpSplice -> "expression" UntypedPatSplice -> "pattern" UntypedTypeSplice -> "type" UntypedDeclSplice -> "declarations" is_decl = case flavour of UntypedDeclSplice -> True _ -> False ------------------ makePending :: UntypedSpliceFlavour -> HsSplice GhcRn -> PendingRnSplice makePending flavour (HsUntypedSplice _ _ n e) = PendingRnSplice flavour n e makePending flavour (HsQuasiQuote _ n quoter q_span quote) = PendingRnSplice flavour n (mkQuasiQuoteExpr flavour quoter q_span quote) makePending _ splice@(HsTypedSplice {}) = pprPanic "makePending" (ppr splice) makePending _ splice@(HsSpliced {}) = pprPanic "makePending" (ppr splice) ------------------ mkQuasiQuoteExpr :: UntypedSpliceFlavour -> Name -> SrcSpan -> FastString -> LHsExpr GhcRn -- Return the expression (quoter "...quote...") -- which is what we must run in a quasi-quote mkQuasiQuoteExpr flavour quoter q_span quote = L q_span $ HsApp noExtField (L q_span $ HsApp noExtField (L q_span (HsVar noExtField (L q_span quote_selector))) quoterExpr) quoteExpr where quoterExpr = L q_span $! HsVar noExtField $! (L q_span quoter) quoteExpr = L q_span $! HsLit noExtField $! HsString NoSourceText quote quote_selector = case flavour of UntypedExpSplice -> quoteExpName UntypedPatSplice -> quotePatName UntypedTypeSplice -> quoteTypeName UntypedDeclSplice -> quoteDecName --------------------- rnSplice :: HsSplice GhcPs -> RnM (HsSplice GhcRn, FreeVars) -- Not exported...used for all rnSplice (HsTypedSplice x hasParen splice_name expr) = do { loc <- getSrcSpanM ; n' <- newLocalBndrRn (L loc splice_name) ; (expr', fvs) <- rnLExpr expr ; return (HsTypedSplice x hasParen n' expr', fvs) } rnSplice (HsUntypedSplice x hasParen splice_name expr) = do { loc <- getSrcSpanM ; n' <- newLocalBndrRn (L loc splice_name) ; (expr', fvs) <- rnLExpr expr ; return (HsUntypedSplice x hasParen n' expr', fvs) } rnSplice (HsQuasiQuote x splice_name quoter q_loc quote) = do { loc <- getSrcSpanM ; splice_name' <- newLocalBndrRn (L loc splice_name) -- Rename the quoter; akin to the HsVar case of rnExpr ; quoter' <- lookupOccRn quoter ; this_mod <- getModule ; when (nameIsLocalOrFrom this_mod quoter') $ checkThLocalName quoter' ; return (HsQuasiQuote x splice_name' quoter' q_loc quote , unitFV quoter') } rnSplice splice@(HsSpliced {}) = pprPanic "rnSplice" (ppr splice) --------------------- rnSpliceExpr :: HsSplice GhcPs -> RnM (HsExpr GhcRn, FreeVars) rnSpliceExpr splice = rnSpliceGen run_expr_splice pend_expr_splice splice where pend_expr_splice :: HsSplice GhcRn -> (PendingRnSplice, HsExpr GhcRn) pend_expr_splice rn_splice = (makePending UntypedExpSplice rn_splice, HsSpliceE noExtField rn_splice) run_expr_splice :: HsSplice GhcRn -> RnM (HsExpr GhcRn, FreeVars) run_expr_splice rn_splice | isTypedSplice rn_splice -- Run it later, in the type checker = do { -- Ugh! See Note [Splices] above traceRn "rnSpliceExpr: typed expression splice" empty ; lcl_rdr <- getLocalRdrEnv ; gbl_rdr <- getGlobalRdrEnv ; let gbl_names = mkNameSet [greMangledName gre | gre <- globalRdrEnvElts gbl_rdr , isLocalGRE gre] lcl_names = mkNameSet (localRdrEnvElts lcl_rdr) ; return (HsSpliceE noExtField rn_splice, lcl_names `plusFV` gbl_names) } | otherwise -- Run it here, see Note [Running splices in the Renamer] = do { traceRn "rnSpliceExpr: untyped expression splice" empty ; (rn_expr, mod_finalizers) <- runRnSplice UntypedExpSplice runMetaE ppr rn_splice ; (lexpr3, fvs) <- checkNoErrs (rnLExpr rn_expr) -- See Note [Delaying modFinalizers in untyped splices]. ; return ( HsPar noExtField $ HsSpliceE noExtField . HsSpliced noExtField (ThModFinalizers mod_finalizers) . HsSplicedExpr <$> lexpr3 , fvs) } {- Note [Running splices in the Renamer] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Splices used to be run in the typechecker, which led to (#4364). Since the renamer must decide which expressions depend on which others, and it cannot reliably do this for arbitrary splices, we used to conservatively say that splices depend on all other expressions in scope. Unfortunately, this led to the problem of cyclic type declarations seen in (#4364). Instead, by running splices in the renamer, we side-step the problem of determining dependencies: by the time the dependency analysis happens, any splices have already been run, and expression dependencies can be determined as usual. However, see (#9813), for an example where we would like to run splices *after* performing dependency analysis (that is, after renaming). It would be desirable to typecheck "non-splicy" expressions (those expressions that do not contain splices directly or via dependence on an expression that does) before "splicy" expressions, such that types/expressions within the same declaration group would be available to `reify` calls, for example consider the following: > module M where > data D = C > f = 1 > g = $(mapM reify ['f, 'D, ''C] ...) Compilation of this example fails since D/C/f are not in the type environment and thus cannot be reified as they have not been typechecked by the time the splice is renamed and thus run. These requirements are at odds: we do not want to run splices in the renamer as we wish to first determine dependencies and typecheck certain expressions, making them available to reify, but cannot accurately determine dependencies without running splices in the renamer! Indeed, the conclusion of (#9813) was that it is not worth the complexity to try and a) implement and maintain the code for renaming/typechecking non-splicy expressions before splicy expressions, b) explain to TH users which expressions are/not available to reify at any given point. -} {- Note [Rebindable syntax and Template Haskell] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When processing Template Haskell quotes with Rebindable Syntax (RS) enabled, there are two possibilities: apply the RS rules to the quotes or don't. One might expect that with {-# LANGUAGE RebindableSyntax #-} at the top of a module, any 'if' expression would end up being turned into a call to whatever 'ifThenElse' function is in scope, regardless of whether the said if expression appears in "normal" Haskell code or in a TH quote. This however comes with its problems. Consider the following code: {-# LANGUAGE TemplateHaskell, RebindableSyntax #-} module X where import Prelude ( Monad(..), Bool(..), print, ($) ) import Language.Haskell.TH.Syntax $( do stuff <- [| if True then 10 else 15 |] runIO $ print stuff return [] ) If we apply the RS rules, then GHC would complain about not having suitable fromInteger/ifThenElse functions in scope. But this quote is just a bit of Haskell syntax that has yet to be used, or, to put it differently, placed (spliced) in some context where the said functions might be available. More generally, untyped TH quotes are meant to work with yet-unbound identifiers. This tends to show that untyped TH and Rebindable Syntax overall don't play well together. Users still have the option to splice "normal" if expressions into modules where RS is enabled, to turn them into applications of an 'ifThenElse' function of their choice. Typed TH (TTH) quotes, on the other hand, come with different constraints. They don't quite have this "delayed" nature: we typecheck them while processing them, and TTH users expect RS to Just Work in their quotes, exactly like it does outside of the quotes. There, we do not have to accept unbound identifiers and we can apply the RS rules both in the typechecking and desugaring of the quotes without triggering surprising/bad behaviour for users. For instance, the following code is expected to be rejected (because of the lack of suitable 'fromInteger'/'ifThenElse' functions in scope): {-# LANGUAGE TemplateHaskell, RebindableSyntax #-} module X where import Prelude ( Monad(..), Bool(..), print, ($) ) import Language.Haskell.TH.Syntax $$( do stuff <- [|| if True then 10 else 15 ||] runIO $ print stuff return [] ) The conclusion is that even if RS is enabled for a given module, GHC disables it when processing untyped TH quotes from that module, to avoid the aforementioned problems, but keeps it on while processing typed TH quotes. This note and approach originated in #18102. -} {- Note [Delaying modFinalizers in untyped splices] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When splices run in the renamer, 'reify' does not have access to the local type environment (#11832, [1]). For instance, in > let x = e in $(reify (mkName "x") >>= runIO . print >> [| return () |]) 'reify' cannot find @x@, because the local type environment is not yet populated. To address this, we allow 'reify' execution to be deferred with 'addModFinalizer'. > let x = e in $(do addModFinalizer (reify (mkName "x") >>= runIO . print) [| return () |] ) The finalizer is run with the local type environment when type checking is complete. Since the local type environment is not available in the renamer, we annotate the tree at the splice point [2] with @HsSpliceE (HsSpliced finalizers e)@ where @e@ is the result of splicing and @finalizers@ are the finalizers that have been collected during evaluation of the splice [3]. In our example, > HsLet > (x = e) > (HsSpliceE $ HsSpliced [reify (mkName "x") >>= runIO . print] > (HsSplicedExpr $ return ()) > ) When the typechecker finds the annotation, it inserts the finalizers in the global environment and exposes the current local environment to them [4, 5, 6]. > addModFinalizersWithLclEnv [reify (mkName "x") >>= runIO . print] References: [1] https://gitlab.haskell.org/ghc/ghc/wikis/template-haskell/reify [2] 'rnSpliceExpr' [3] 'GHC.Tc.Gen.Splice.qAddModFinalizer' [4] 'GHC.Tc.Gen.Expr.tcExpr' ('HsSpliceE' ('HsSpliced' ...)) [5] 'GHC.Tc.Gen.HsType.tc_hs_type' ('HsSpliceTy' ('HsSpliced' ...)) [6] 'GHC.Tc.Gen.Pat.tc_pat' ('SplicePat' ('HsSpliced' ...)) -} ---------------------- rnSpliceType :: HsSplice GhcPs -> RnM (HsType GhcRn, FreeVars) rnSpliceType splice = rnSpliceGen run_type_splice pend_type_splice splice where pend_type_splice rn_splice = ( makePending UntypedTypeSplice rn_splice , HsSpliceTy noExtField rn_splice) run_type_splice rn_splice = do { traceRn "rnSpliceType: untyped type splice" empty ; (hs_ty2, mod_finalizers) <- runRnSplice UntypedTypeSplice runMetaT ppr rn_splice ; (hs_ty3, fvs) <- do { let doc = SpliceTypeCtx hs_ty2 ; checkNoErrs $ rnLHsType doc hs_ty2 } -- checkNoErrs: see Note [Renamer errors] -- See Note [Delaying modFinalizers in untyped splices]. ; return ( HsParTy noExtField $ HsSpliceTy noExtField . HsSpliced noExtField (ThModFinalizers mod_finalizers) . HsSplicedTy <$> hs_ty3 , fvs ) } -- Wrap the result of the splice in parens so that we don't -- lose the outermost location set by runQuasiQuote (#7918) {- Note [Partial Type Splices] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Partial Type Signatures are partially supported in TH type splices: only anonymous wild cards are allowed. -- ToDo: SLPJ says: I don't understand all this Normally, named wild cards are collected before renaming a (partial) type signature. However, TH type splices are run during renaming, i.e. after the initial traversal, leading to out of scope errors for named wild cards. We can't just extend the initial traversal to collect the named wild cards in TH type splices, as we'd need to expand them, which is supposed to happen only once, during renaming. Similarly, the extra-constraints wild card is handled right before renaming too, and is therefore also not supported in a TH type splice. Another reason to forbid extra-constraints wild cards in TH type splices is that a single signature can contain many TH type splices, whereas it mustn't contain more than one extra-constraints wild card. Enforcing would this be hard the way things are currently organised. Anonymous wild cards pose no problem, because they start out without names and are given names during renaming. These names are collected right after renaming. The names generated for anonymous wild cards in TH type splices will thus be collected as well. For more details about renaming wild cards, see GHC.Rename.HsType.rnHsSigWcType Note that partial type signatures are fully supported in TH declaration splices, e.g.: [d| foo :: _ => _ foo x y = x == y |] This is because in this case, the partial type signature can be treated as a whole signature, instead of as an arbitrary type. -} ---------------------- -- | Rename a splice pattern. See Note [rnSplicePat] rnSplicePat :: HsSplice GhcPs -> RnM ( Either (Pat GhcPs) (Pat GhcRn) , FreeVars) rnSplicePat splice = rnSpliceGen run_pat_splice pend_pat_splice splice where pend_pat_splice :: HsSplice GhcRn -> (PendingRnSplice, Either b (Pat GhcRn)) pend_pat_splice rn_splice = (makePending UntypedPatSplice rn_splice , Right (SplicePat noExtField rn_splice)) run_pat_splice :: HsSplice GhcRn -> RnM (Either (Pat GhcPs) (Pat GhcRn), FreeVars) run_pat_splice rn_splice = do { traceRn "rnSplicePat: untyped pattern splice" empty ; (pat, mod_finalizers) <- runRnSplice UntypedPatSplice runMetaP ppr rn_splice -- See Note [Delaying modFinalizers in untyped splices]. ; return ( Left $ ParPat noExtField $ ((SplicePat noExtField) . HsSpliced noExtField (ThModFinalizers mod_finalizers) . HsSplicedPat) `mapLoc` pat , emptyFVs ) } -- Wrap the result of the quasi-quoter in parens so that we don't -- lose the outermost location set by runQuasiQuote (#7918) ---------------------- rnSpliceDecl :: SpliceDecl GhcPs -> RnM (SpliceDecl GhcRn, FreeVars) rnSpliceDecl (SpliceDecl _ (L loc splice) flg) = rnSpliceGen run_decl_splice pend_decl_splice splice where pend_decl_splice rn_splice = ( makePending UntypedDeclSplice rn_splice , SpliceDecl noExtField (L loc rn_splice) flg) run_decl_splice rn_splice = pprPanic "rnSpliceDecl" (ppr rn_splice) rnTopSpliceDecls :: HsSplice GhcPs -> RnM ([LHsDecl GhcPs], FreeVars) -- Declaration splice at the very top level of the module rnTopSpliceDecls splice = do { checkTopSpliceAllowed splice ; (rn_splice, fvs) <- checkNoErrs $ setStage (Splice Untyped) $ rnSplice splice -- As always, be sure to checkNoErrs above lest we end up with -- holes making it to typechecking, hence #12584. -- -- Note that we cannot call checkNoErrs for the whole duration -- of rnTopSpliceDecls. The reason is that checkNoErrs changes -- the local environment to temporarily contain a new -- reference to store errors, and add_mod_finalizers would -- cause this reference to be stored after checkNoErrs finishes. -- This is checked by test TH_finalizer. ; traceRn "rnTopSpliceDecls: untyped declaration splice" empty ; (decls, mod_finalizers) <- checkNoErrs $ runRnSplice UntypedDeclSplice runMetaD ppr_decls rn_splice ; add_mod_finalizers_now mod_finalizers ; return (decls,fvs) } where ppr_decls :: [LHsDecl GhcPs] -> SDoc ppr_decls ds = vcat (map ppr ds) -- Adds finalizers to the global environment instead of delaying them -- to the type checker. -- -- Declaration splices do not have an interesting local environment so -- there is no point in delaying them. -- -- See Note [Delaying modFinalizers in untyped splices]. add_mod_finalizers_now :: [ForeignRef (TH.Q ())] -> TcRn () add_mod_finalizers_now [] = return () add_mod_finalizers_now mod_finalizers = do th_modfinalizers_var <- fmap tcg_th_modfinalizers getGblEnv env <- getLclEnv updTcRef th_modfinalizers_var $ \fins -> (env, ThModFinalizers mod_finalizers) : fins {- Note [rnSplicePat] ~~~~~~~~~~~~~~~~~~ Renaming a pattern splice is a bit tricky, because we need the variables bound in the pattern to be in scope in the RHS of the pattern. This scope management is effectively done by using continuation-passing style in GHC.Rename.Pat, through the CpsRn monad. We don't wish to be in that monad here (it would create import cycles and generally conflict with renaming other splices), so we really want to return a (Pat RdrName) -- the result of running the splice -- which can then be further renamed in GHC.Rename.Pat, in the CpsRn monad. The problem is that if we're renaming a splice within a bracket, we *don't* want to run the splice now. We really do just want to rename it to an HsSplice Name. Of course, then we can't know what variables are bound within the splice. So we accept any unbound variables and rename them again when the bracket is spliced in. If a variable is brought into scope by a pattern splice all is fine. If it is not then an error is reported. In any case, when we're done in rnSplicePat, we'll either have a Pat RdrName (the result of running a top-level splice) or a Pat Name (the renamed nested splice). Thus, the awkward return type of rnSplicePat. -} spliceCtxt :: HsSplice GhcPs -> SDoc spliceCtxt splice = hang (text "In the" <+> what) 2 (ppr splice) where what = case splice of HsUntypedSplice {} -> text "untyped splice:" HsTypedSplice {} -> text "typed splice:" HsQuasiQuote {} -> text "quasi-quotation:" HsSpliced {} -> text "spliced expression:" -- | The splice data to be logged data SpliceInfo = SpliceInfo { spliceDescription :: String , spliceSource :: Maybe (LHsExpr GhcRn) -- Nothing <=> top-level decls -- added by addTopDecls , spliceIsDecl :: Bool -- True <=> put the generate code in a file -- when -dth-dec-file is on , spliceGenerated :: SDoc } -- Note that 'spliceSource' is *renamed* but not *typechecked* -- Reason (a) less typechecking crap -- (b) data constructors after type checking have been -- changed to their *wrappers*, and that makes them -- print always fully qualified -- | outputs splice information for 2 flags which have different output formats: -- `-ddump-splices` and `-dth-dec-file` traceSplice :: SpliceInfo -> TcM () traceSplice (SpliceInfo { spliceDescription = sd, spliceSource = mb_src , spliceGenerated = gen, spliceIsDecl = is_decl }) = do loc <- case mb_src of Nothing -> getSrcSpanM Just (L loc _) -> return loc traceOptTcRn Opt_D_dump_splices (spliceDebugDoc loc) when is_decl $ do -- Raw material for -dth-dec-file dflags <- getDynFlags logger <- getLogger liftIO $ dumpIfSet_dyn_printer alwaysQualify logger dflags Opt_D_th_dec_file "" FormatHaskell (spliceCodeDoc loc) where -- `-ddump-splices` spliceDebugDoc :: SrcSpan -> SDoc spliceDebugDoc loc = let code = case mb_src of Nothing -> ending Just e -> nest 2 (ppr (stripParensLHsExpr e)) : ending ending = [ text "======>", nest 2 gen ] in hang (ppr loc <> colon <+> text "Splicing" <+> text sd) 2 (sep code) -- `-dth-dec-file` spliceCodeDoc :: SrcSpan -> SDoc spliceCodeDoc loc = vcat [ text "--" <+> ppr loc <> colon <+> text "Splicing" <+> text sd , gen ] illegalTypedSplice :: SDoc illegalTypedSplice = text "Typed splices may not appear in untyped brackets" illegalUntypedSplice :: SDoc illegalUntypedSplice = text "Untyped splices may not appear in typed brackets" checkThLocalName :: Name -> RnM () checkThLocalName name | isUnboundName name -- Do not report two errors for = return () -- $(not_in_scope args) | otherwise = do { traceRn "checkThLocalName" (ppr name) ; mb_local_use <- getStageAndBindLevel name ; case mb_local_use of { Nothing -> return () ; -- Not a locally-bound thing Just (top_lvl, bind_lvl, use_stage) -> do { let use_lvl = thLevel use_stage ; checkWellStaged (quotes (ppr name)) bind_lvl use_lvl ; traceRn "checkThLocalName" (ppr name <+> ppr bind_lvl <+> ppr use_stage <+> ppr use_lvl) ; checkCrossStageLifting top_lvl bind_lvl use_stage use_lvl name } } } -------------------------------------- checkCrossStageLifting :: TopLevelFlag -> ThLevel -> ThStage -> ThLevel -> Name -> TcM () -- We are inside brackets, and (use_lvl > bind_lvl) -- Now we must check whether there's a cross-stage lift to do -- Examples \x -> [| x |] -- [| map |] -- -- This code is similar to checkCrossStageLifting in GHC.Tc.Gen.Expr, but -- this is only run on *untyped* brackets. checkCrossStageLifting top_lvl bind_lvl use_stage use_lvl name | Brack _ (RnPendingUntyped ps_var) <- use_stage -- Only for untyped brackets , use_lvl > bind_lvl -- Cross-stage condition = check_cross_stage_lifting top_lvl name ps_var | otherwise = return () check_cross_stage_lifting :: TopLevelFlag -> Name -> TcRef [PendingRnSplice] -> TcM () check_cross_stage_lifting top_lvl name ps_var | isTopLevel top_lvl -- Top-level identifiers in this module, -- (which have External Names) -- are just like the imported case: -- no need for the 'lifting' treatment -- E.g. this is fine: -- f x = x -- g y = [| f 3 |] = when (isExternalName name) (keepAlive name) -- See Note [Keeping things alive for Template Haskell] | otherwise = -- Nested identifiers, such as 'x' in -- E.g. \x -> [| h x |] -- We must behave as if the reference to x was -- h $(lift x) -- We use 'x' itself as the SplicePointName, used by -- the desugarer to stitch it all back together. -- If 'x' occurs many times we may get many identical -- bindings of the same SplicePointName, but that doesn't -- matter, although it's a mite untidy. do { traceRn "checkCrossStageLifting" (ppr name) -- Construct the (lift x) expression ; let lift_expr = nlHsApp (nlHsVar liftName) (nlHsVar name) pend_splice = PendingRnSplice UntypedExpSplice name lift_expr -- Warning for implicit lift (#17804) ; whenWOptM Opt_WarnImplicitLift $ addWarnTc (Reason Opt_WarnImplicitLift) (text "The variable" <+> quotes (ppr name) <+> text "is implicitly lifted in the TH quotation") -- Update the pending splices ; ps <- readMutVar ps_var ; writeMutVar ps_var (pend_splice : ps) } {- Note [Keeping things alive for Template Haskell] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider f x = x+1 g y = [| f 3 |] Here 'f' is referred to from inside the bracket, which turns into data and mentions only f's *name*, not 'f' itself. So we need some other way to keep 'f' alive, lest it get dropped as dead code. That's what keepAlive does. It puts it in the keep-alive set, which subsequently ensures that 'f' stays as a top level binding. This must be done by the renamer, not the type checker (as of old), because the type checker doesn't typecheck the body of untyped brackets (#8540). A thing can have a bind_lvl of outerLevel, but have an internal name: foo = [d| op = 3 bop = op + 1 |] Here the bind_lvl of 'op' is (bogusly) outerLevel, even though it is bound inside a bracket. That is because we don't even record binding levels for top-level things; the binding levels are in the LocalRdrEnv. So the occurrence of 'op' in the rhs of 'bop' looks a bit like a cross-stage thing, but it isn't really. And in fact we never need to do anything here for top-level bound things, so all is fine, if a bit hacky. For these chaps (which have Internal Names) we don't want to put them in the keep-alive set. Note [Quoting names] ~~~~~~~~~~~~~~~~~~~~ A quoted name 'n is a bit like a quoted expression [| n |], except that we have no cross-stage lifting (c.f. GHC.Tc.Gen.Expr.thBrackId). So, after incrementing the use-level to account for the brackets, the cases are: bind > use Error bind = use+1 OK bind < use Imported things OK Top-level things OK Non-top-level Error where 'use' is the binding level of the 'n quote. (So inside the implied bracket the level would be use+1.) Examples: f 'map -- OK; also for top-level defns of this module \x. f 'x -- Not ok (bind = 1, use = 1) -- (whereas \x. f [| x |] might have been ok, by -- cross-stage lifting \y. [| \x. $(f 'y) |] -- Not ok (bind =1, use = 1) [| \x. $(f 'x) |] -- OK (bind = 2, use = 1) -}