-- -*-haskell-*- -- --------------------------------------------------------------------------- -- (c) The University of Glasgow 1997-2003 --- -- The GHC grammar. -- -- Author(s): Simon Marlow, Sven Panne 1997, 1998, 1999 -- --------------------------------------------------------------------------- { {-# LANGUAGE ViewPatterns #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE LambdaCase #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE ScopedTypeVariables #-} -- | This module provides the generated Happy parser for Haskell. It exports -- a number of parsers which may be used in any library that uses the GHC API. -- A common usage pattern is to initialize the parser state with a given string -- and then parse that string: -- -- @ -- runParser :: ParserOpts -> String -> P a -> ParseResult a -- runParser opts str parser = unP parser parseState -- where -- filename = "\" -- location = mkRealSrcLoc (mkFastString filename) 1 1 -- buffer = stringToStringBuffer str -- parseState = initParserState opts buffer location -- @ module GHC.Parser ( parseModule, parseSignature, parseImport, parseStatement, parseBackpack , parseDeclaration, parseExpression, parsePattern , parseTypeSignature , parseStmt, parseIdentifier , parseType, parseHeader , parseModuleNoHaddock ) where -- base import Control.Monad ( unless, liftM, when, (<=<) ) import GHC.Exts import Data.Maybe ( maybeToList ) import qualified Prelude -- for happy-generated code import GHC.Prelude import GHC.Hs import GHC.Driver.Backpack.Syntax import GHC.Unit.Info import GHC.Unit.Module import GHC.Unit.Module.Warnings import GHC.Data.OrdList import GHC.Data.BooleanFormula ( BooleanFormula(..), LBooleanFormula, mkTrue ) import GHC.Data.FastString import GHC.Data.Maybe ( orElse ) import GHC.Utils.Outputable import GHC.Utils.Misc ( looksLikePackageName, fstOf3, sndOf3, thdOf3 ) import GHC.Utils.Panic import GHC.Prelude import GHC.Types.Name.Reader import GHC.Types.Name.Occurrence ( varName, dataName, tcClsName, tvName, occNameFS, mkVarOcc, occNameString) import GHC.Types.SrcLoc import GHC.Types.Basic import GHC.Types.Fixity import GHC.Types.ForeignCall import GHC.Types.SourceFile import GHC.Types.SourceText import GHC.Core.Type ( unrestrictedFunTyCon, Specificity(..) ) import GHC.Core.Class ( FunDep ) import GHC.Core.DataCon ( DataCon, dataConName ) import GHC.Parser.PostProcess import GHC.Parser.PostProcess.Haddock import GHC.Parser.Lexer import GHC.Parser.Annotation import GHC.Parser.Errors import GHC.Builtin.Types ( unitTyCon, unitDataCon, tupleTyCon, tupleDataCon, nilDataCon, unboxedUnitTyCon, unboxedUnitDataCon, listTyCon_RDR, consDataCon_RDR, eqTyCon_RDR) import qualified Data.Semigroup as Semi } %expect 0 -- shift/reduce conflicts {- Note [shift/reduce conflicts] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The 'happy' tool turns this grammar into an efficient parser that follows the shift-reduce parsing model. There's a parse stack that contains items parsed so far (both terminals and non-terminals). Every next token produced by the lexer results in one of two actions: SHIFT: push the token onto the parse stack REDUCE: pop a few items off the parse stack and combine them with a function (reduction rule) However, sometimes it's unclear which of the two actions to take. Consider this code example: if x then y else f z There are two ways to parse it: (if x then y else f) z if x then y else (f z) How is this determined? At some point, the parser gets to the following state: parse stack: 'if' exp 'then' exp 'else' "f" next token: "z" Scenario A (simplified): 1. REDUCE, parse stack: 'if' exp 'then' exp 'else' exp next token: "z" (Note that "f" reduced to exp here) 2. REDUCE, parse stack: exp next token: "z" 3. SHIFT, parse stack: exp "z" next token: ... 4. REDUCE, parse stack: exp next token: ... This way we get: (if x then y else f) z Scenario B (simplified): 1. SHIFT, parse stack: 'if' exp 'then' exp 'else' "f" "z" next token: ... 2. REDUCE, parse stack: 'if' exp 'then' exp 'else' exp next token: ... 3. REDUCE, parse stack: exp next token: ... This way we get: if x then y else (f z) The end result is determined by the chosen action. When Happy detects this, it reports a shift/reduce conflict. At the top of the file, we have the following directive: %expect 0 It means that we expect no unresolved shift/reduce conflicts in this grammar. If you modify the grammar and get shift/reduce conflicts, follow the steps below to resolve them. STEP ONE is to figure out what causes the conflict. That's where the -i flag comes in handy: happy -agc --strict compiler/GHC/Parser.y -idetailed-info By analysing the output of this command, in a new file `detailed-info`, you can figure out which reduction rule causes the issue. At the top of the generated report, you will see a line like this: state 147 contains 67 shift/reduce conflicts. Scroll down to section State 147 (in your case it could be a different state). The start of the section lists the reduction rules that can fire and shows their context: exp10 -> fexp . (rule 492) fexp -> fexp . aexp (rule 498) fexp -> fexp . PREFIX_AT atype (rule 499) And then, for every token, it tells you the parsing action: ']' reduce using rule 492 '::' reduce using rule 492 '(' shift, and enter state 178 QVARID shift, and enter state 44 DO shift, and enter state 182 ... But if you look closer, some of these tokens also have another parsing action in parentheses: QVARID shift, and enter state 44 (reduce using rule 492) That's how you know rule 492 is causing trouble. Scroll back to the top to see what this rule is: ---------------------------------- Grammar ---------------------------------- ... ... exp10 -> fexp (492) optSemi -> ';' (493) ... ... Hence the shift/reduce conflict is caused by this parser production: exp10 :: { ECP } : '-' fexp { ... } | fexp { ... } -- problematic rule STEP TWO is to mark the problematic rule with the %shift pragma. This signals to 'happy' that any shift/reduce conflicts involving this rule must be resolved in favor of a shift. There's currently no dedicated pragma to resolve in favor of the reduce. STEP THREE is to add a dedicated Note for this specific conflict, as is done for all other conflicts below. -} {- Note [%shift: rule_activation -> {- empty -}] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: rule -> STRING . rule_activation rule_foralls infixexp '=' exp Example: {-# RULES "name" [0] f = rhs #-} Ambiguity: If we reduced, then we'd get an empty activation rule, and [0] would be parsed as part of the left-hand side expression. We shift, so [0] is parsed as an activation rule. -} {- Note [%shift: rule_foralls -> 'forall' rule_vars '.'] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: rule_foralls -> 'forall' rule_vars '.' . 'forall' rule_vars '.' rule_foralls -> 'forall' rule_vars '.' . Example: {-# RULES "name" forall a1. forall a2. lhs = rhs #-} Ambiguity: Same as in Note [%shift: rule_foralls -> {- empty -}] but for the second 'forall'. -} {- Note [%shift: rule_foralls -> {- empty -}] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: rule -> STRING rule_activation . rule_foralls infixexp '=' exp Example: {-# RULES "name" forall a1. lhs = rhs #-} Ambiguity: If we reduced, then we would get an empty rule_foralls; the 'forall', being a valid term-level identifier, would be parsed as part of the left-hand side expression. We shift, so the 'forall' is parsed as part of rule_foralls. -} {- Note [%shift: type -> btype] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: context -> btype . type -> btype . type -> btype . '->' ctype type -> btype . '->.' ctype Example: a :: Maybe Integer -> Bool Ambiguity: If we reduced, we would get: (a :: Maybe Integer) -> Bool We shift to get this instead: a :: (Maybe Integer -> Bool) -} {- Note [%shift: infixtype -> ftype] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: infixtype -> ftype . infixtype -> ftype . tyop infixtype ftype -> ftype . tyarg ftype -> ftype . PREFIX_AT tyarg Example: a :: Maybe Integer Ambiguity: If we reduced, we would get: (a :: Maybe) Integer We shift to get this instead: a :: (Maybe Integer) -} {- Note [%shift: atype -> tyvar] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: atype -> tyvar . tv_bndr_no_braces -> '(' tyvar . '::' kind ')' Example: class C a where type D a = (a :: Type ... Ambiguity: If we reduced, we could specify a default for an associated type like this: class C a where type D a type D a = (a :: Type) But we shift in order to allow injectivity signatures like this: class C a where type D a = (r :: Type) | r -> a -} {- Note [%shift: exp -> infixexp] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: exp -> infixexp . '::' sigtype exp -> infixexp . '-<' exp exp -> infixexp . '>-' exp exp -> infixexp . '-<<' exp exp -> infixexp . '>>-' exp exp -> infixexp . infixexp -> infixexp . qop exp10p Examples: 1) if x then y else z -< e 2) if x then y else z :: T 3) if x then y else z + 1 -- (NB: '+' is in VARSYM) Ambiguity: If we reduced, we would get: 1) (if x then y else z) -< e 2) (if x then y else z) :: T 3) (if x then y else z) + 1 We shift to get this instead: 1) if x then y else (z -< e) 2) if x then y else (z :: T) 3) if x then y else (z + 1) -} {- Note [%shift: exp10 -> '-' fexp] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: exp10 -> '-' fexp . fexp -> fexp . aexp fexp -> fexp . PREFIX_AT atype Examples & Ambiguity: Same as in Note [%shift: exp10 -> fexp], but with a '-' in front. -} {- Note [%shift: exp10 -> fexp] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: exp10 -> fexp . fexp -> fexp . aexp fexp -> fexp . PREFIX_AT atype Examples: 1) if x then y else f z 2) if x then y else f @z Ambiguity: If we reduced, we would get: 1) (if x then y else f) z 2) (if x then y else f) @z We shift to get this instead: 1) if x then y else (f z) 2) if x then y else (f @z) -} {- Note [%shift: aexp2 -> ipvar] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: aexp2 -> ipvar . dbind -> ipvar . '=' exp Example: let ?x = ... Ambiguity: If we reduced, ?x would be parsed as the LHS of a normal binding, eventually producing an error. We shift, so it is parsed as the LHS of an implicit binding. -} {- Note [%shift: aexp2 -> TH_TY_QUOTE] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: aexp2 -> TH_TY_QUOTE . tyvar aexp2 -> TH_TY_QUOTE . gtycon aexp2 -> TH_TY_QUOTE . Examples: 1) x = '' 2) x = ''a 3) x = ''T Ambiguity: If we reduced, the '' would result in reportEmptyDoubleQuotes even when followed by a type variable or a type constructor. But the only reason this reduction rule exists is to improve error messages. Naturally, we shift instead, so that ''a and ''T work as expected. -} {- Note [%shift: tup_tail -> {- empty -}] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: tup_exprs -> commas . tup_tail sysdcon_nolist -> '(' commas . ')' sysdcon_nolist -> '(#' commas . '#)' commas -> commas . ',' Example: (,,) Ambiguity: A tuple section with no components is indistinguishable from the Haskell98 data constructor for a tuple. If we reduced, (,,) would be parsed as a tuple section. We shift, so (,,) is parsed as a data constructor. This is preferable because we want to accept (,,) without -XTupleSections. See also Note [ExplicitTuple] in GHC.Hs.Expr. -} {- Note [%shift: qtyconop -> qtyconsym] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: oqtycon -> '(' qtyconsym . ')' qtyconop -> qtyconsym . Example: foo :: (:%) Ambiguity: If we reduced, (:%) would be parsed as a parenthehsized infix type expression without arguments, resulting in the 'failOpFewArgs' error. We shift, so it is parsed as a type constructor. -} {- Note [%shift: special_id -> 'group'] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: transformqual -> 'then' 'group' . 'using' exp transformqual -> 'then' 'group' . 'by' exp 'using' exp special_id -> 'group' . Example: [ ... | then group by dept using groupWith , then take 5 ] Ambiguity: If we reduced, 'group' would be parsed as a term-level identifier, just as 'take' in the other clause. We shift, so it is parsed as part of the 'group by' clause introduced by the -XTransformListComp extension. -} {- Note [%shift: activation -> {- empty -}] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Context: sigdecl -> '{-# INLINE' . activation qvarcon '#-}' activation -> {- empty -} activation -> explicit_activation Example: {-# INLINE [0] Something #-} Ambiguity: We don't know whether the '[' is the start of the activation or the beginning of the [] data constructor. We parse this as having '[0]' activation for inlining 'Something', rather than empty activation and inlining '[0] Something'. -} {- Note [Parser API Annotations] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ A lot of the productions are now cluttered with calls to aa,am,acs,acsA etc. These are helper functions to make sure that the locations of the various keywords such as do / let / in are captured for use by tools that want to do source to source conversions, such as refactorers or structured editors. The helper functions are defined at the bottom of this file. See https://gitlab.haskell.org/ghc/ghc/wikis/api-annotations and https://gitlab.haskell.org/ghc/ghc/wikis/ghc-ast-annotations for some background. -} {- Note [Parsing lists] ~~~~~~~~~~~~~~~~~~~~~~~ You might be wondering why we spend so much effort encoding our lists this way: importdecls : importdecls ';' importdecl | importdecls ';' | importdecl | {- empty -} This might seem like an awfully roundabout way to declare a list; plus, to add insult to injury you have to reverse the results at the end. The answer is that left recursion prevents us from running out of stack space when parsing long sequences. See: https://www.haskell.org/happy/doc/html/sec-sequences.html for more guidance. By adding/removing branches, you can affect what lists are accepted. Here are the most common patterns, rewritten as regular expressions for clarity: -- Equivalent to: ';'* (x ';'+)* x? (can be empty, permits leading/trailing semis) xs : xs ';' x | xs ';' | x | {- empty -} -- Equivalent to x (';' x)* ';'* (non-empty, permits trailing semis) xs : xs ';' x | xs ';' | x -- Equivalent to ';'* alts (';' alts)* ';'* (non-empty, permits leading/trailing semis) alts : alts1 | ';' alts alts1 : alts1 ';' alt | alts1 ';' | alt -- Equivalent to x (',' x)+ (non-empty, no trailing semis) xs : x | x ',' xs -} %token '_' { L _ ITunderscore } -- Haskell keywords 'as' { L _ ITas } 'case' { L _ ITcase } 'class' { L _ ITclass } 'data' { L _ ITdata } 'default' { L _ ITdefault } 'deriving' { L _ ITderiving } 'else' { L _ ITelse } 'hiding' { L _ IThiding } 'if' { L _ ITif } 'import' { L _ ITimport } 'in' { L _ ITin } 'infix' { L _ ITinfix } 'infixl' { L _ ITinfixl } 'infixr' { L _ ITinfixr } 'instance' { L _ ITinstance } 'let' { L _ ITlet } 'module' { L _ ITmodule } 'newtype' { L _ ITnewtype } 'of' { L _ ITof } 'qualified' { L _ ITqualified } 'then' { L _ ITthen } 'type' { L _ ITtype } 'where' { L _ ITwhere } 'forall' { L _ (ITforall _) } -- GHC extension keywords 'foreign' { L _ ITforeign } 'export' { L _ ITexport } 'label' { L _ ITlabel } 'dynamic' { L _ ITdynamic } 'safe' { L _ ITsafe } 'interruptible' { L _ ITinterruptible } 'unsafe' { L _ ITunsafe } 'family' { L _ ITfamily } 'role' { L _ ITrole } 'stdcall' { L _ ITstdcallconv } 'ccall' { L _ ITccallconv } 'capi' { L _ ITcapiconv } 'prim' { L _ ITprimcallconv } 'javascript' { L _ ITjavascriptcallconv } 'proc' { L _ ITproc } -- for arrow notation extension 'rec' { L _ ITrec } -- for arrow notation extension 'group' { L _ ITgroup } -- for list transform extension 'by' { L _ ITby } -- for list transform extension 'using' { L _ ITusing } -- for list transform extension 'pattern' { L _ ITpattern } -- for pattern synonyms 'static' { L _ ITstatic } -- for static pointers extension 'stock' { L _ ITstock } -- for DerivingStrategies extension 'anyclass' { L _ ITanyclass } -- for DerivingStrategies extension 'via' { L _ ITvia } -- for DerivingStrategies extension 'unit' { L _ ITunit } 'signature' { L _ ITsignature } 'dependency' { L _ ITdependency } '{-# INLINE' { L _ (ITinline_prag _ _ _) } -- INLINE or INLINABLE '{-# SPECIALISE' { L _ (ITspec_prag _) } '{-# SPECIALISE_INLINE' { L _ (ITspec_inline_prag _ _) } '{-# SOURCE' { L _ (ITsource_prag _) } '{-# RULES' { L _ (ITrules_prag _) } '{-# SCC' { L _ (ITscc_prag _)} '{-# DEPRECATED' { L _ (ITdeprecated_prag _) } '{-# WARNING' { L _ (ITwarning_prag _) } '{-# UNPACK' { L _ (ITunpack_prag _) } '{-# NOUNPACK' { L _ (ITnounpack_prag _) } '{-# ANN' { L _ (ITann_prag _) } '{-# MINIMAL' { L _ (ITminimal_prag _) } '{-# CTYPE' { L _ (ITctype _) } '{-# OVERLAPPING' { L _ (IToverlapping_prag _) } '{-# OVERLAPPABLE' { L _ (IToverlappable_prag _) } '{-# OVERLAPS' { L _ (IToverlaps_prag _) } '{-# INCOHERENT' { L _ (ITincoherent_prag _) } '{-# COMPLETE' { L _ (ITcomplete_prag _) } '#-}' { L _ ITclose_prag } '..' { L _ ITdotdot } -- reserved symbols ':' { L _ ITcolon } '::' { L _ (ITdcolon _) } '=' { L _ ITequal } '\\' { L _ ITlam } 'lcase' { L _ ITlcase } '|' { L _ ITvbar } '<-' { L _ (ITlarrow _) } '->' { L _ (ITrarrow _) } '->.' { L _ ITlolly } TIGHT_INFIX_AT { L _ ITat } '=>' { L _ (ITdarrow _) } '-' { L _ ITminus } PREFIX_TILDE { L _ ITtilde } PREFIX_BANG { L _ ITbang } PREFIX_MINUS { L _ ITprefixminus } '*' { L _ (ITstar _) } '-<' { L _ (ITlarrowtail _) } -- for arrow notation '>-' { L _ (ITrarrowtail _) } -- for arrow notation '-<<' { L _ (ITLarrowtail _) } -- for arrow notation '>>-' { L _ (ITRarrowtail _) } -- for arrow notation '.' { L _ ITdot } PREFIX_PROJ { L _ (ITproj True) } -- RecordDotSyntax TIGHT_INFIX_PROJ { L _ (ITproj False) } -- RecordDotSyntax PREFIX_AT { L _ ITtypeApp } PREFIX_PERCENT { L _ ITpercent } -- for linear types '{' { L _ ITocurly } -- special symbols '}' { L _ ITccurly } vocurly { L _ ITvocurly } -- virtual open curly (from layout) vccurly { L _ ITvccurly } -- virtual close curly (from layout) '[' { L _ ITobrack } ']' { L _ ITcbrack } '(' { L _ IToparen } ')' { L _ ITcparen } '(#' { L _ IToubxparen } '#)' { L _ ITcubxparen } '(|' { L _ (IToparenbar _) } '|)' { L _ (ITcparenbar _) } ';' { L _ ITsemi } ',' { L _ ITcomma } '`' { L _ ITbackquote } SIMPLEQUOTE { L _ ITsimpleQuote } -- 'x VARID { L _ (ITvarid _) } -- identifiers CONID { L _ (ITconid _) } VARSYM { L _ (ITvarsym _) } CONSYM { L _ (ITconsym _) } QVARID { L _ (ITqvarid _) } QCONID { L _ (ITqconid _) } QVARSYM { L _ (ITqvarsym _) } QCONSYM { L _ (ITqconsym _) } -- QualifiedDo DO { L _ (ITdo _) } MDO { L _ (ITmdo _) } IPDUPVARID { L _ (ITdupipvarid _) } -- GHC extension LABELVARID { L _ (ITlabelvarid _) } CHAR { L _ (ITchar _ _) } STRING { L _ (ITstring _ _) } INTEGER { L _ (ITinteger _) } RATIONAL { L _ (ITrational _) } PRIMCHAR { L _ (ITprimchar _ _) } PRIMSTRING { L _ (ITprimstring _ _) } PRIMINTEGER { L _ (ITprimint _ _) } PRIMWORD { L _ (ITprimword _ _) } PRIMFLOAT { L _ (ITprimfloat _) } PRIMDOUBLE { L _ (ITprimdouble _) } -- Template Haskell '[|' { L _ (ITopenExpQuote _ _) } '[p|' { L _ ITopenPatQuote } '[t|' { L _ ITopenTypQuote } '[d|' { L _ ITopenDecQuote } '|]' { L _ (ITcloseQuote _) } '[||' { L _ (ITopenTExpQuote _) } '||]' { L _ ITcloseTExpQuote } PREFIX_DOLLAR { L _ ITdollar } PREFIX_DOLLAR_DOLLAR { L _ ITdollardollar } TH_TY_QUOTE { L _ ITtyQuote } -- ''T TH_QUASIQUOTE { L _ (ITquasiQuote _) } TH_QQUASIQUOTE { L _ (ITqQuasiQuote _) } %monad { P } { >>= } { return } %lexer { (lexer True) } { L _ ITeof } -- Replace 'lexer' above with 'lexerDbg' -- to dump the tokens fed to the parser. %tokentype { (Located Token) } -- Exported parsers %name parseModuleNoHaddock module %name parseSignature signature %name parseImport importdecl %name parseStatement e_stmt %name parseDeclaration topdecl %name parseExpression exp %name parsePattern pat %name parseTypeSignature sigdecl %name parseStmt maybe_stmt %name parseIdentifier identifier %name parseType ktype %name parseBackpack backpack %partial parseHeader header %% ----------------------------------------------------------------------------- -- Identifiers; one of the entry points identifier :: { LocatedN RdrName } : qvar { $1 } | qcon { $1 } | qvarop { $1 } | qconop { $1 } | '(' '->' ')' {% amsrn (sLL $1 $> $ getRdrName unrestrictedFunTyCon) (NameAnn NameParens (glAA $1) (glAA $2) (glAA $3) []) } | '->' {% amsrn (sLL $1 $> $ getRdrName unrestrictedFunTyCon) (NameAnnRArrow (glAA $1) []) } ----------------------------------------------------------------------------- -- Backpack stuff backpack :: { [LHsUnit PackageName] } : implicit_top units close { fromOL $2 } | '{' units '}' { fromOL $2 } units :: { OrdList (LHsUnit PackageName) } : units ';' unit { $1 `appOL` unitOL $3 } | units ';' { $1 } | unit { unitOL $1 } unit :: { LHsUnit PackageName } : 'unit' pkgname 'where' unitbody { sL1 $1 $ HsUnit { hsunitName = $2 , hsunitBody = fromOL $4 } } unitid :: { LHsUnitId PackageName } : pkgname { sL1 $1 $ HsUnitId $1 [] } | pkgname '[' msubsts ']' { sLL $1 $> $ HsUnitId $1 (fromOL $3) } msubsts :: { OrdList (LHsModuleSubst PackageName) } : msubsts ',' msubst { $1 `appOL` unitOL $3 } | msubsts ',' { $1 } | msubst { unitOL $1 } msubst :: { LHsModuleSubst PackageName } : modid '=' moduleid { sLL $1 $> $ ($1, $3) } | modid VARSYM modid VARSYM { sLL $1 $> $ ($1, sLL $2 $> $ HsModuleVar $3) } moduleid :: { LHsModuleId PackageName } : VARSYM modid VARSYM { sLL $1 $> $ HsModuleVar $2 } | unitid ':' modid { sLL $1 $> $ HsModuleId $1 $3 } pkgname :: { Located PackageName } : STRING { sL1 $1 $ PackageName (getSTRING $1) } | litpkgname { sL1 $1 $ PackageName (unLoc $1) } litpkgname_segment :: { Located FastString } : VARID { sL1 $1 $ getVARID $1 } | CONID { sL1 $1 $ getCONID $1 } | special_id { $1 } -- Parse a minus sign regardless of whether -XLexicalNegation is turned on or off. -- See Note [Minus tokens] in GHC.Parser.Lexer HYPHEN :: { [AddEpAnn] } : '-' { [mj AnnMinus $1 ] } | PREFIX_MINUS { [mj AnnMinus $1 ] } | VARSYM {% if (getVARSYM $1 == fsLit "-") then return [mj AnnMinus $1] else do { addError $ PsError PsErrExpectedHyphen [] (getLoc $1) ; return [] } } litpkgname :: { Located FastString } : litpkgname_segment { $1 } -- a bit of a hack, means p - b is parsed same as p-b, enough for now. | litpkgname_segment HYPHEN litpkgname { sLL $1 $> $ appendFS (unLoc $1) (consFS '-' (unLoc $3)) } mayberns :: { Maybe [LRenaming] } : {- empty -} { Nothing } | '(' rns ')' { Just (fromOL $2) } rns :: { OrdList LRenaming } : rns ',' rn { $1 `appOL` unitOL $3 } | rns ',' { $1 } | rn { unitOL $1 } rn :: { LRenaming } : modid 'as' modid { sLL $1 $> $ Renaming $1 (Just $3) } | modid { sL1 $1 $ Renaming $1 Nothing } unitbody :: { OrdList (LHsUnitDecl PackageName) } : '{' unitdecls '}' { $2 } | vocurly unitdecls close { $2 } unitdecls :: { OrdList (LHsUnitDecl PackageName) } : unitdecls ';' unitdecl { $1 `appOL` unitOL $3 } | unitdecls ';' { $1 } | unitdecl { unitOL $1 } unitdecl :: { LHsUnitDecl PackageName } : 'module' maybe_src modid maybemodwarning maybeexports 'where' body -- XXX not accurate { sL1 $1 $ DeclD (case snd $2 of NotBoot -> HsSrcFile IsBoot -> HsBootFile) $3 (Just $ sL1 $1 (HsModule noAnn (thdOf3 $7) (Just $3) $5 (fst $ sndOf3 $7) (snd $ sndOf3 $7) $4 Nothing)) } | 'signature' modid maybemodwarning maybeexports 'where' body { sL1 $1 $ DeclD HsigFile $2 (Just $ sL1 $1 (HsModule noAnn (thdOf3 $6) (Just $2) $4 (fst $ sndOf3 $6) (snd $ sndOf3 $6) $3 Nothing)) } | 'module' maybe_src modid { sL1 $1 $ DeclD (case snd $2 of NotBoot -> HsSrcFile IsBoot -> HsBootFile) $3 Nothing } | 'signature' modid { sL1 $1 $ DeclD HsigFile $2 Nothing } | 'dependency' unitid mayberns { sL1 $1 $ IncludeD (IncludeDecl { idUnitId = $2 , idModRenaming = $3 , idSignatureInclude = False }) } | 'dependency' 'signature' unitid { sL1 $1 $ IncludeD (IncludeDecl { idUnitId = $3 , idModRenaming = Nothing , idSignatureInclude = True }) } ----------------------------------------------------------------------------- -- Module Header -- The place for module deprecation is really too restrictive, but if it -- was allowed at its natural place just before 'module', we get an ugly -- s/r conflict with the second alternative. Another solution would be the -- introduction of a new pragma DEPRECATED_MODULE, but this is not very nice, -- either, and DEPRECATED is only expected to be used by people who really -- know what they are doing. :-) signature :: { Located HsModule } : 'signature' modid maybemodwarning maybeexports 'where' body {% fileSrcSpan >>= \ loc -> acs (\cs-> (L loc (HsModule (EpAnn (spanAsAnchor loc) (AnnsModule [mj AnnSignature $1, mj AnnWhere $5] (fstOf3 $6)) cs) (thdOf3 $6) (Just $2) $4 (fst $ sndOf3 $6) (snd $ sndOf3 $6) $3 Nothing)) ) } module :: { Located HsModule } : 'module' modid maybemodwarning maybeexports 'where' body {% fileSrcSpan >>= \ loc -> acsFinal (\cs -> (L loc (HsModule (EpAnn (spanAsAnchor loc) (AnnsModule [mj AnnModule $1, mj AnnWhere $5] (fstOf3 $6)) cs) (thdOf3 $6) (Just $2) $4 (fst $ sndOf3 $6) (snd $ sndOf3 $6) $3 Nothing) )) } | body2 {% fileSrcSpan >>= \ loc -> acsFinal (\cs -> (L loc (HsModule (EpAnn (spanAsAnchor loc) (AnnsModule [] (fstOf3 $1)) cs) (thdOf3 $1) Nothing Nothing (fst $ sndOf3 $1) (snd $ sndOf3 $1) Nothing Nothing))) } missing_module_keyword :: { () } : {- empty -} {% pushModuleContext } implicit_top :: { () } : {- empty -} {% pushModuleContext } maybemodwarning :: { Maybe (LocatedP WarningTxt) } : '{-# DEPRECATED' strings '#-}' {% fmap Just $ amsrp (sLL $1 $> $ DeprecatedTxt (sL1 $1 $ getDEPRECATED_PRAGs $1) (snd $ unLoc $2)) (AnnPragma (mo $1) (mc $3) (fst $ unLoc $2)) } | '{-# WARNING' strings '#-}' {% fmap Just $ amsrp (sLL $1 $> $ WarningTxt (sL1 $1 $ getWARNING_PRAGs $1) (snd $ unLoc $2)) (AnnPragma (mo $1) (mc $3) (fst $ unLoc $2))} | {- empty -} { Nothing } body :: { (AnnList ,([LImportDecl GhcPs], [LHsDecl GhcPs]) ,LayoutInfo) } : '{' top '}' { (AnnList Nothing (Just $ moc $1) (Just $ mcc $3) [] (fst $2) , snd $2, ExplicitBraces) } | vocurly top close { (AnnList Nothing Nothing Nothing [] (fst $2) , snd $2, VirtualBraces (getVOCURLY $1)) } body2 :: { (AnnList ,([LImportDecl GhcPs], [LHsDecl GhcPs]) ,LayoutInfo) } : '{' top '}' { (AnnList Nothing (Just $ moc $1) (Just $ mcc $3) [] (fst $2) , snd $2, ExplicitBraces) } | missing_module_keyword top close { (AnnList Nothing Nothing Nothing [] [], snd $2, VirtualBraces leftmostColumn) } top :: { ([TrailingAnn] ,([LImportDecl GhcPs], [LHsDecl GhcPs])) } : semis top1 { ($1, $2) } top1 :: { ([LImportDecl GhcPs], [LHsDecl GhcPs]) } : importdecls_semi topdecls_cs_semi { (reverse $1, cvTopDecls $2) } | importdecls_semi topdecls_cs { (reverse $1, cvTopDecls $2) } | importdecls { (reverse $1, []) } ----------------------------------------------------------------------------- -- Module declaration & imports only header :: { Located HsModule } : 'module' modid maybemodwarning maybeexports 'where' header_body {% fileSrcSpan >>= \ loc -> acs (\cs -> (L loc (HsModule (EpAnn (spanAsAnchor loc) (AnnsModule [mj AnnModule $1,mj AnnWhere $5] (AnnList Nothing Nothing Nothing [] [])) cs) NoLayoutInfo (Just $2) $4 $6 [] $3 Nothing ))) } | 'signature' modid maybemodwarning maybeexports 'where' header_body {% fileSrcSpan >>= \ loc -> acs (\cs -> (L loc (HsModule (EpAnn (spanAsAnchor loc) (AnnsModule [mj AnnModule $1,mj AnnWhere $5] (AnnList Nothing Nothing Nothing [] [])) cs) NoLayoutInfo (Just $2) $4 $6 [] $3 Nothing ))) } | header_body2 {% fileSrcSpan >>= \ loc -> return (L loc (HsModule noAnn NoLayoutInfo Nothing Nothing $1 [] Nothing Nothing)) } header_body :: { [LImportDecl GhcPs] } : '{' header_top { $2 } | vocurly header_top { $2 } header_body2 :: { [LImportDecl GhcPs] } : '{' header_top { $2 } | missing_module_keyword header_top { $2 } header_top :: { [LImportDecl GhcPs] } : semis header_top_importdecls { $2 } header_top_importdecls :: { [LImportDecl GhcPs] } : importdecls_semi { $1 } | importdecls { $1 } ----------------------------------------------------------------------------- -- The Export List maybeexports :: { (Maybe (LocatedL [LIE GhcPs])) } : '(' exportlist ')' {% fmap Just $ amsrl (sLL $1 $> (fromOL $ snd $2)) (AnnList Nothing (Just $ mop $1) (Just $ mcp $3) (fst $2) []) } | {- empty -} { Nothing } exportlist :: { ([AddEpAnn], OrdList (LIE GhcPs)) } : exportlist1 { ([], $1) } | {- empty -} { ([], nilOL) } -- trailing comma: | exportlist1 ',' {% case $1 of SnocOL hs t -> do t' <- addTrailingCommaA t (gl $2) return ([], snocOL hs t')} | ',' { ([mj AnnComma $1], nilOL) } exportlist1 :: { OrdList (LIE GhcPs) } : exportlist1 ',' export {% let ls = $1 in if isNilOL ls then return (ls `appOL` $3) else case ls of SnocOL hs t -> do t' <- addTrailingCommaA t (gl $2) return (snocOL hs t' `appOL` $3)} | export { $1 } -- No longer allow things like [] and (,,,) to be exported -- They are built in syntax, always available export :: { OrdList (LIE GhcPs) } : qcname_ext export_subspec {% mkModuleImpExp (fst $ unLoc $2) $1 (snd $ unLoc $2) >>= \ie -> fmap (unitOL . reLocA) (return (sLL (reLoc $1) $> ie)) } | 'module' modid {% fmap (unitOL . reLocA) (acs (\cs -> sLL $1 $> (IEModuleContents (EpAnn (glR $1) [mj AnnModule $1] cs) $2))) } | 'pattern' qcon { unitOL (reLocA (sLL $1 (reLocN $>) (IEVar noExtField (sLLa $1 (reLocN $>) (IEPattern (glAA $1) $2))))) } export_subspec :: { Located ([AddEpAnn],ImpExpSubSpec) } : {- empty -} { sL0 ([],ImpExpAbs) } | '(' qcnames ')' {% mkImpExpSubSpec (reverse (snd $2)) >>= \(as,ie) -> return $ sLL $1 $> (as ++ [mop $1,mcp $3] ++ fst $2, ie) } qcnames :: { ([AddEpAnn], [LocatedA ImpExpQcSpec]) } : {- empty -} { ([],[]) } | qcnames1 { $1 } qcnames1 :: { ([AddEpAnn], [LocatedA ImpExpQcSpec]) } -- A reversed list : qcnames1 ',' qcname_ext_w_wildcard {% case (snd $1) of (l@(L la ImpExpQcWildcard):t) -> do { l' <- addTrailingCommaA l (gl $2) ; return ([mj AnnDotdot (reLoc l), mj AnnComma $2] ,(snd (unLoc $3) : l' : t)) } (l:t) -> do { l' <- addTrailingCommaA l (gl $2) ; return (fst $1 ++ fst (unLoc $3) , snd (unLoc $3) : l' : t)} } -- Annotations re-added in mkImpExpSubSpec | qcname_ext_w_wildcard { (fst (unLoc $1),[snd (unLoc $1)]) } -- Variable, data constructor or wildcard -- or tagged type constructor qcname_ext_w_wildcard :: { Located ([AddEpAnn], LocatedA ImpExpQcSpec) } : qcname_ext { sL1A $1 ([],$1) } | '..' { sL1 $1 ([mj AnnDotdot $1], sL1a $1 ImpExpQcWildcard) } qcname_ext :: { LocatedA ImpExpQcSpec } : qcname { reLocA $ sL1N $1 (ImpExpQcName $1) } | 'type' oqtycon {% do { n <- mkTypeImpExp $2 ; return $ sLLa $1 (reLocN $>) (ImpExpQcType (glAA $1) n) }} qcname :: { LocatedN RdrName } -- Variable or type constructor : qvar { $1 } -- Things which look like functions -- Note: This includes record selectors but -- also (-.->), see #11432 | oqtycon_no_varcon { $1 } -- see Note [Type constructors in export list] ----------------------------------------------------------------------------- -- Import Declarations -- importdecls and topdecls must contain at least one declaration; -- top handles the fact that these may be optional. -- One or more semicolons semis1 :: { [TrailingAnn] } semis1 : semis1 ';' { if isZeroWidthSpan (gl $2) then $1 else (AddSemiAnn (glAA $2) : $1) } | ';' { msemi $1 } -- Zero or more semicolons semis :: { [TrailingAnn] } semis : semis ';' { if isZeroWidthSpan (gl $2) then $1 else (AddSemiAnn (glAA $2) : $1) } | {- empty -} { [] } -- No trailing semicolons, non-empty importdecls :: { [LImportDecl GhcPs] } importdecls : importdecls_semi importdecl { $2 : $1 } -- May have trailing semicolons, can be empty importdecls_semi :: { [LImportDecl GhcPs] } importdecls_semi : importdecls_semi importdecl semis1 {% do { i <- amsA $2 $3 ; return (i : $1)} } | {- empty -} { [] } importdecl :: { LImportDecl GhcPs } : 'import' maybe_src maybe_safe optqualified maybe_pkg modid optqualified maybeas maybeimpspec {% do { ; let { ; mPreQual = unLoc $4 ; mPostQual = unLoc $7 } ; checkImportDecl mPreQual mPostQual ; let anns = EpAnnImportDecl { importDeclAnnImport = glAA $1 , importDeclAnnPragma = fst $ fst $2 , importDeclAnnSafe = fst $3 , importDeclAnnQualified = fst $ importDeclQualifiedStyle mPreQual mPostQual , importDeclAnnPackage = fst $5 , importDeclAnnAs = fst $8 } ; fmap reLocA $ acs (\cs -> L (comb5 $1 $6 $7 (snd $8) $9) $ ImportDecl { ideclExt = EpAnn (glR $1) anns cs , ideclSourceSrc = snd $ fst $2 , ideclName = $6, ideclPkgQual = snd $5 , ideclSource = snd $2, ideclSafe = snd $3 , ideclQualified = snd $ importDeclQualifiedStyle mPreQual mPostQual , ideclImplicit = False , ideclAs = unLoc (snd $8) , ideclHiding = unLoc $9 }) } } maybe_src :: { ((Maybe (EpaLocation,EpaLocation),SourceText),IsBootInterface) } : '{-# SOURCE' '#-}' { ((Just (glAA $1,glAA $2),getSOURCE_PRAGs $1) , IsBoot) } | {- empty -} { ((Nothing,NoSourceText),NotBoot) } maybe_safe :: { (Maybe EpaLocation,Bool) } : 'safe' { (Just (glAA $1),True) } | {- empty -} { (Nothing, False) } maybe_pkg :: { (Maybe EpaLocation,Maybe StringLiteral) } : STRING {% do { let { pkgFS = getSTRING $1 } ; unless (looksLikePackageName (unpackFS pkgFS)) $ addError $ PsError (PsErrInvalidPackageName pkgFS) [] (getLoc $1) ; return (Just (glAA $1), Just (StringLiteral (getSTRINGs $1) pkgFS Nothing)) } } | {- empty -} { (Nothing,Nothing) } optqualified :: { Located (Maybe EpaLocation) } : 'qualified' { sL1 $1 (Just (glAA $1)) } | {- empty -} { noLoc Nothing } maybeas :: { (Maybe EpaLocation,Located (Maybe (Located ModuleName))) } : 'as' modid { (Just (glAA $1) ,sLL $1 $> (Just $2)) } | {- empty -} { (Nothing,noLoc Nothing) } maybeimpspec :: { Located (Maybe (Bool, LocatedL [LIE GhcPs])) } : impspec {% let (b, ie) = unLoc $1 in checkImportSpec ie >>= \checkedIe -> return (L (gl $1) (Just (b, checkedIe))) } | {- empty -} { noLoc Nothing } impspec :: { Located (Bool, LocatedL [LIE GhcPs]) } : '(' exportlist ')' {% do { es <- amsrl (sLL $1 $> $ fromOL $ snd $2) (AnnList Nothing (Just $ mop $1) (Just $ mcp $3) (fst $2) []) ; return $ sLL $1 $> (False, es)} } | 'hiding' '(' exportlist ')' {% do { es <- amsrl (sLL $1 $> $ fromOL $ snd $3) (AnnList Nothing (Just $ mop $2) (Just $ mcp $4) (mj AnnHiding $1:fst $3) []) ; return $ sLL $1 $> (True, es)} } ----------------------------------------------------------------------------- -- Fixity Declarations prec :: { Located (SourceText,Int) } : {- empty -} { noLoc (NoSourceText,9) } | INTEGER { sL1 $1 (getINTEGERs $1,fromInteger (il_value (getINTEGER $1))) } infix :: { Located FixityDirection } : 'infix' { sL1 $1 InfixN } | 'infixl' { sL1 $1 InfixL } | 'infixr' { sL1 $1 InfixR } ops :: { Located (OrdList (LocatedN RdrName)) } : ops ',' op {% case (unLoc $1) of SnocOL hs t -> do t' <- addTrailingCommaN t (gl $2) return (sLL $1 (reLocN $>) (snocOL hs t' `appOL` unitOL $3)) } | op { sL1N $1 (unitOL $1) } ----------------------------------------------------------------------------- -- Top-Level Declarations -- No trailing semicolons, non-empty topdecls :: { OrdList (LHsDecl GhcPs) } : topdecls_semi topdecl { $1 `snocOL` $2 } -- May have trailing semicolons, can be empty topdecls_semi :: { OrdList (LHsDecl GhcPs) } : topdecls_semi topdecl semis1 {% do { t <- amsA $2 $3 ; return ($1 `snocOL` t) }} | {- empty -} { nilOL } ----------------------------------------------------------------------------- -- Each topdecl accumulates prior comments -- No trailing semicolons, non-empty topdecls_cs :: { OrdList (LHsDecl GhcPs) } : topdecls_cs_semi topdecl_cs { $1 `snocOL` $2 } -- May have trailing semicolons, can be empty topdecls_cs_semi :: { OrdList (LHsDecl GhcPs) } : topdecls_cs_semi topdecl_cs semis1 {% do { t <- amsA $2 $3 ; return ($1 `snocOL` t) }} | {- empty -} { nilOL } -- Each topdecl accumulates prior comments topdecl_cs :: { LHsDecl GhcPs } topdecl_cs : topdecl {% commentsPA $1 } ----------------------------------------------------------------------------- topdecl :: { LHsDecl GhcPs } : cl_decl { sL1 $1 (TyClD noExtField (unLoc $1)) } | ty_decl { sL1 $1 (TyClD noExtField (unLoc $1)) } | standalone_kind_sig { sL1 $1 (KindSigD noExtField (unLoc $1)) } | inst_decl { sL1 $1 (InstD noExtField (unLoc $1)) } | stand_alone_deriving { sL1 $1 (DerivD noExtField (unLoc $1)) } | role_annot { sL1 $1 (RoleAnnotD noExtField (unLoc $1)) } | 'default' '(' comma_types0 ')' {% acsA (\cs -> sLL $1 $> (DefD noExtField (DefaultDecl (EpAnn (glR $1) [mj AnnDefault $1,mop $2,mcp $4] cs) $3))) } | 'foreign' fdecl {% acsA (\cs -> sLL $1 $> ((snd $ unLoc $2) (EpAnn (glR $1) (mj AnnForeign $1:(fst $ unLoc $2)) cs))) } | '{-# DEPRECATED' deprecations '#-}' {% acsA (\cs -> sLL $1 $> $ WarningD noExtField (Warnings (EpAnn (glR $1) [mo $1,mc $3] cs) (getDEPRECATED_PRAGs $1) (fromOL $2))) } | '{-# WARNING' warnings '#-}' {% acsA (\cs -> sLL $1 $> $ WarningD noExtField (Warnings (EpAnn (glR $1) [mo $1,mc $3] cs) (getWARNING_PRAGs $1) (fromOL $2))) } | '{-# RULES' rules '#-}' {% acsA (\cs -> sLL $1 $> $ RuleD noExtField (HsRules (EpAnn (glR $1) [mo $1,mc $3] cs) (getRULES_PRAGs $1) (reverse $2))) } | annotation { $1 } | decl_no_th { $1 } -- Template Haskell Extension -- The $(..) form is one possible form of infixexp -- but we treat an arbitrary expression just as if -- it had a $(..) wrapped around it | infixexp {% runPV (unECP $1) >>= \ $1 -> do { d <- mkSpliceDecl $1 ; commentsPA d }} -- Type classes -- cl_decl :: { LTyClDecl GhcPs } : 'class' tycl_hdr fds where_cls {% (mkClassDecl (comb4 $1 $2 $3 $4) $2 $3 (sndOf3 $ unLoc $4) (thdOf3 $ unLoc $4)) (mj AnnClass $1:(fst $ unLoc $3)++(fstOf3 $ unLoc $4)) } -- Type declarations (toplevel) -- ty_decl :: { LTyClDecl GhcPs } -- ordinary type synonyms : 'type' type '=' ktype -- Note ktype, not sigtype, on the right of '=' -- We allow an explicit for-all but we don't insert one -- in type Foo a = (b,b) -- Instead we just say b is out of scope -- -- Note the use of type for the head; this allows -- infix type constructors to be declared {% mkTySynonym (comb2A $1 $4) $2 $4 [mj AnnType $1,mj AnnEqual $3] } -- type family declarations | 'type' 'family' type opt_tyfam_kind_sig opt_injective_info where_type_family -- Note the use of type for the head; this allows -- infix type constructors to be declared {% mkFamDecl (comb4 $1 (reLoc $3) $4 $5) (snd $ unLoc $6) TopLevel $3 (snd $ unLoc $4) (snd $ unLoc $5) (mj AnnType $1:mj AnnFamily $2:(fst $ unLoc $4) ++ (fst $ unLoc $5) ++ (fst $ unLoc $6)) } -- ordinary data type or newtype declaration | data_or_newtype capi_ctype tycl_hdr constrs maybe_derivings {% mkTyData (comb4 $1 $3 $4 $5) (snd $ unLoc $1) $2 $3 Nothing (reverse (snd $ unLoc $4)) (fmap reverse $5) ((fst $ unLoc $1):(fst $ unLoc $4)) } -- We need the location on tycl_hdr in case -- constrs and deriving are both empty -- ordinary GADT declaration | data_or_newtype capi_ctype tycl_hdr opt_kind_sig gadt_constrlist maybe_derivings {% mkTyData (comb4 $1 $3 $5 $6) (snd $ unLoc $1) $2 $3 (snd $ unLoc $4) (snd $ unLoc $5) (fmap reverse $6) ((fst $ unLoc $1):(fst $ unLoc $4)++(fst $ unLoc $5)) } -- We need the location on tycl_hdr in case -- constrs and deriving are both empty -- data/newtype family | 'data' 'family' type opt_datafam_kind_sig {% mkFamDecl (comb3 $1 $2 $4) DataFamily TopLevel $3 (snd $ unLoc $4) Nothing (mj AnnData $1:mj AnnFamily $2:(fst $ unLoc $4)) } -- standalone kind signature standalone_kind_sig :: { LStandaloneKindSig GhcPs } : 'type' sks_vars '::' sigktype {% mkStandaloneKindSig (comb2A $1 $4) (L (gl $2) $ unLoc $2) $4 [mj AnnType $1,mu AnnDcolon $3]} -- See also: sig_vars sks_vars :: { Located [LocatedN RdrName] } -- Returned in reverse order : sks_vars ',' oqtycon {% case unLoc $1 of (h:t) -> do h' <- addTrailingCommaN h (gl $2) return (sLL $1 (reLocN $>) ($3 : h' : t)) } | oqtycon { sL1N $1 [$1] } inst_decl :: { LInstDecl GhcPs } : 'instance' overlap_pragma inst_type where_inst {% do { (binds, sigs, _, ats, adts, _) <- cvBindsAndSigs (snd $ unLoc $4) ; let anns = (mj AnnInstance $1 : (fst $ unLoc $4)) ; let cid cs = ClsInstDecl { cid_ext = (EpAnn (glR $1) anns cs, NoAnnSortKey) , cid_poly_ty = $3, cid_binds = binds , cid_sigs = mkClassOpSigs sigs , cid_tyfam_insts = ats , cid_overlap_mode = $2 , cid_datafam_insts = adts } ; acsA (\cs -> L (comb3 $1 (reLoc $3) $4) (ClsInstD { cid_d_ext = noExtField, cid_inst = cid cs })) } } -- type instance declarations | 'type' 'instance' ty_fam_inst_eqn {% mkTyFamInst (comb2A $1 $3) (unLoc $3) (mj AnnType $1:mj AnnInstance $2:[]) } -- data/newtype instance declaration | data_or_newtype 'instance' capi_ctype datafam_inst_hdr constrs maybe_derivings {% mkDataFamInst (comb4 $1 $4 $5 $6) (snd $ unLoc $1) $3 (unLoc $4) Nothing (reverse (snd $ unLoc $5)) (fmap reverse $6) ((fst $ unLoc $1):mj AnnInstance $2:(fst $ unLoc $5)) } -- GADT instance declaration | data_or_newtype 'instance' capi_ctype datafam_inst_hdr opt_kind_sig gadt_constrlist maybe_derivings {% mkDataFamInst (comb4 $1 $4 $6 $7) (snd $ unLoc $1) $3 (unLoc $4) (snd $ unLoc $5) (snd $ unLoc $6) (fmap reverse $7) ((fst $ unLoc $1):mj AnnInstance $2 :(fst $ unLoc $5)++(fst $ unLoc $6)) } overlap_pragma :: { Maybe (LocatedP OverlapMode) } : '{-# OVERLAPPABLE' '#-}' {% fmap Just $ amsrp (sLL $1 $> (Overlappable (getOVERLAPPABLE_PRAGs $1))) (AnnPragma (mo $1) (mc $2) []) } | '{-# OVERLAPPING' '#-}' {% fmap Just $ amsrp (sLL $1 $> (Overlapping (getOVERLAPPING_PRAGs $1))) (AnnPragma (mo $1) (mc $2) []) } | '{-# OVERLAPS' '#-}' {% fmap Just $ amsrp (sLL $1 $> (Overlaps (getOVERLAPS_PRAGs $1))) (AnnPragma (mo $1) (mc $2) []) } | '{-# INCOHERENT' '#-}' {% fmap Just $ amsrp (sLL $1 $> (Incoherent (getINCOHERENT_PRAGs $1))) (AnnPragma (mo $1) (mc $2) []) } | {- empty -} { Nothing } deriv_strategy_no_via :: { LDerivStrategy GhcPs } : 'stock' {% acs (\cs -> sL1 $1 (StockStrategy (EpAnn (glR $1) [mj AnnStock $1] cs))) } | 'anyclass' {% acs (\cs -> sL1 $1 (AnyclassStrategy (EpAnn (glR $1) [mj AnnAnyclass $1] cs))) } | 'newtype' {% acs (\cs -> sL1 $1 (NewtypeStrategy (EpAnn (glR $1) [mj AnnNewtype $1] cs))) } deriv_strategy_via :: { LDerivStrategy GhcPs } : 'via' sigktype {% acs (\cs -> sLLlA $1 $> (ViaStrategy (XViaStrategyPs (EpAnn (glR $1) [mj AnnVia $1] cs) $2))) } deriv_standalone_strategy :: { Maybe (LDerivStrategy GhcPs) } : 'stock' {% fmap Just $ acs (\cs -> sL1 $1 (StockStrategy (EpAnn (glR $1) [mj AnnStock $1] cs))) } | 'anyclass' {% fmap Just $ acs (\cs -> sL1 $1 (AnyclassStrategy (EpAnn (glR $1) [mj AnnAnyclass $1] cs))) } | 'newtype' {% fmap Just $ acs (\cs -> sL1 $1 (NewtypeStrategy (EpAnn (glR $1) [mj AnnNewtype $1] cs))) } | deriv_strategy_via { Just $1 } | {- empty -} { Nothing } -- Injective type families opt_injective_info :: { Located ([AddEpAnn], Maybe (LInjectivityAnn GhcPs)) } : {- empty -} { noLoc ([], Nothing) } | '|' injectivity_cond { sLL $1 $> ([mj AnnVbar $1] , Just ($2)) } injectivity_cond :: { LInjectivityAnn GhcPs } : tyvarid '->' inj_varids {% acs (\cs -> sLL (reLocN $1) $> (InjectivityAnn (EpAnn (glNR $1) [mu AnnRarrow $2] cs) $1 (reverse (unLoc $3)))) } inj_varids :: { Located [LocatedN RdrName] } : inj_varids tyvarid { sLL $1 (reLocN $>) ($2 : unLoc $1) } | tyvarid { sL1N $1 [$1] } -- Closed type families where_type_family :: { Located ([AddEpAnn],FamilyInfo GhcPs) } : {- empty -} { noLoc ([],OpenTypeFamily) } | 'where' ty_fam_inst_eqn_list { sLL $1 $> (mj AnnWhere $1:(fst $ unLoc $2) ,ClosedTypeFamily (fmap reverse $ snd $ unLoc $2)) } ty_fam_inst_eqn_list :: { Located ([AddEpAnn],Maybe [LTyFamInstEqn GhcPs]) } : '{' ty_fam_inst_eqns '}' { sLL $1 $> ([moc $1,mcc $3] ,Just (unLoc $2)) } | vocurly ty_fam_inst_eqns close { let (L loc _) = $2 in L loc ([],Just (unLoc $2)) } | '{' '..' '}' { sLL $1 $> ([moc $1,mj AnnDotdot $2 ,mcc $3],Nothing) } | vocurly '..' close { let (L loc _) = $2 in L loc ([mj AnnDotdot $2],Nothing) } ty_fam_inst_eqns :: { Located [LTyFamInstEqn GhcPs] } : ty_fam_inst_eqns ';' ty_fam_inst_eqn {% let (L loc eqn) = $3 in case unLoc $1 of [] -> return (sLLlA $1 $> (L loc eqn : unLoc $1)) (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (sLLlA $1 $> ($3 : h' : t)) } | ty_fam_inst_eqns ';' {% case unLoc $1 of [] -> return (sLL $1 $> (unLoc $1)) (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (sLL $1 $> (h':t)) } | ty_fam_inst_eqn { sLLAA $1 $> [$1] } | {- empty -} { noLoc [] } ty_fam_inst_eqn :: { LTyFamInstEqn GhcPs } : 'forall' tv_bndrs '.' type '=' ktype {% do { hintExplicitForall $1 ; tvbs <- fromSpecTyVarBndrs $2 ; let loc = comb2A $1 $> ; cs <- getCommentsFor loc ; mkTyFamInstEqn loc (mkHsOuterExplicit (EpAnn (glR $1) (mu AnnForall $1, mj AnnDot $3) cs) tvbs) $4 $6 [mj AnnEqual $5] }} | type '=' ktype {% mkTyFamInstEqn (comb2A (reLoc $1) $>) mkHsOuterImplicit $1 $3 (mj AnnEqual $2:[]) } -- Note the use of type for the head; this allows -- infix type constructors and type patterns -- Associated type family declarations -- -- * They have a different syntax than on the toplevel (no family special -- identifier). -- -- * They also need to be separate from instances; otherwise, data family -- declarations without a kind signature cause parsing conflicts with empty -- data declarations. -- at_decl_cls :: { LHsDecl GhcPs } : -- data family declarations, with optional 'family' keyword 'data' opt_family type opt_datafam_kind_sig {% liftM mkTyClD (mkFamDecl (comb3 $1 (reLoc $3) $4) DataFamily NotTopLevel $3 (snd $ unLoc $4) Nothing (mj AnnData $1:$2++(fst $ unLoc $4))) } -- type family declarations, with optional 'family' keyword -- (can't use opt_instance because you get shift/reduce errors | 'type' type opt_at_kind_inj_sig {% liftM mkTyClD (mkFamDecl (comb3 $1 (reLoc $2) $3) OpenTypeFamily NotTopLevel $2 (fst . snd $ unLoc $3) (snd . snd $ unLoc $3) (mj AnnType $1:(fst $ unLoc $3)) )} | 'type' 'family' type opt_at_kind_inj_sig {% liftM mkTyClD (mkFamDecl (comb3 $1 (reLoc $3) $4) OpenTypeFamily NotTopLevel $3 (fst . snd $ unLoc $4) (snd . snd $ unLoc $4) (mj AnnType $1:mj AnnFamily $2:(fst $ unLoc $4)))} -- default type instances, with optional 'instance' keyword | 'type' ty_fam_inst_eqn {% liftM mkInstD (mkTyFamInst (comb2A $1 $2) (unLoc $2) [mj AnnType $1]) } | 'type' 'instance' ty_fam_inst_eqn {% liftM mkInstD (mkTyFamInst (comb2A $1 $3) (unLoc $3) (mj AnnType $1:mj AnnInstance $2:[]) )} opt_family :: { [AddEpAnn] } : {- empty -} { [] } | 'family' { [mj AnnFamily $1] } opt_instance :: { [AddEpAnn] } : {- empty -} { [] } | 'instance' { [mj AnnInstance $1] } -- Associated type instances -- at_decl_inst :: { LInstDecl GhcPs } -- type instance declarations, with optional 'instance' keyword : 'type' opt_instance ty_fam_inst_eqn -- Note the use of type for the head; this allows -- infix type constructors and type patterns {% mkTyFamInst (comb2A $1 $3) (unLoc $3) (mj AnnType $1:$2) } -- data/newtype instance declaration, with optional 'instance' keyword | data_or_newtype opt_instance capi_ctype datafam_inst_hdr constrs maybe_derivings {% mkDataFamInst (comb4 $1 $4 $5 $6) (snd $ unLoc $1) $3 (unLoc $4) Nothing (reverse (snd $ unLoc $5)) (fmap reverse $6) ((fst $ unLoc $1):$2++(fst $ unLoc $5)) } -- GADT instance declaration, with optional 'instance' keyword | data_or_newtype opt_instance capi_ctype datafam_inst_hdr opt_kind_sig gadt_constrlist maybe_derivings {% mkDataFamInst (comb4 $1 $4 $6 $7) (snd $ unLoc $1) $3 (unLoc $4) (snd $ unLoc $5) (snd $ unLoc $6) (fmap reverse $7) ((fst $ unLoc $1):$2++(fst $ unLoc $5)++(fst $ unLoc $6)) } data_or_newtype :: { Located (AddEpAnn, NewOrData) } : 'data' { sL1 $1 (mj AnnData $1,DataType) } | 'newtype' { sL1 $1 (mj AnnNewtype $1,NewType) } -- Family result/return kind signatures opt_kind_sig :: { Located ([AddEpAnn], Maybe (LHsKind GhcPs)) } : { noLoc ([] , Nothing) } | '::' kind { sLL $1 (reLoc $>) ([mu AnnDcolon $1], Just $2) } opt_datafam_kind_sig :: { Located ([AddEpAnn], LFamilyResultSig GhcPs) } : { noLoc ([] , noLoc (NoSig noExtField) )} | '::' kind { sLL $1 (reLoc $>) ([mu AnnDcolon $1], sLL $1 (reLoc $>) (KindSig noExtField $2))} opt_tyfam_kind_sig :: { Located ([AddEpAnn], LFamilyResultSig GhcPs) } : { noLoc ([] , noLoc (NoSig noExtField) )} | '::' kind { sLL $1 (reLoc $>) ([mu AnnDcolon $1], sLL $1 (reLoc $>) (KindSig noExtField $2))} | '=' tv_bndr {% do { tvb <- fromSpecTyVarBndr $2 ; return $ sLL $1 (reLoc $>) ([mj AnnEqual $1], sLL $1 (reLoc $>) (TyVarSig noExtField tvb))} } opt_at_kind_inj_sig :: { Located ([AddEpAnn], ( LFamilyResultSig GhcPs , Maybe (LInjectivityAnn GhcPs)))} : { noLoc ([], (noLoc (NoSig noExtField), Nothing)) } | '::' kind { sLL $1 (reLoc $>) ( [mu AnnDcolon $1] , (sL1A $> (KindSig noExtField $2), Nothing)) } | '=' tv_bndr_no_braces '|' injectivity_cond {% do { tvb <- fromSpecTyVarBndr $2 ; return $ sLL $1 $> ([mj AnnEqual $1, mj AnnVbar $3] , (sLL $1 (reLoc $2) (TyVarSig noExtField tvb), Just $4))} } -- tycl_hdr parses the header of a class or data type decl, -- which takes the form -- T a b -- Eq a => T a -- (Eq a, Ord b) => T a b -- T Int [a] -- for associated types -- Rather a lot of inlining here, else we get reduce/reduce errors tycl_hdr :: { Located (Maybe (LHsContext GhcPs), LHsType GhcPs) } : context '=>' type {% acs (\cs -> (sLLAA $1 $> (Just (addTrailingDarrowC $1 $2 cs), $3))) } | type { sL1A $1 (Nothing, $1) } datafam_inst_hdr :: { Located (Maybe (LHsContext GhcPs), HsOuterFamEqnTyVarBndrs GhcPs, LHsType GhcPs) } : 'forall' tv_bndrs '.' context '=>' type {% hintExplicitForall $1 >> fromSpecTyVarBndrs $2 >>= \tvbs -> (acs (\cs -> (sLL $1 (reLoc $>) (Just ( addTrailingDarrowC $4 $5 cs) , mkHsOuterExplicit (EpAnn (glR $1) (mu AnnForall $1, mj AnnDot $3) emptyComments) tvbs, $6)))) } | 'forall' tv_bndrs '.' type {% do { hintExplicitForall $1 ; tvbs <- fromSpecTyVarBndrs $2 ; let loc = comb2 $1 (reLoc $>) ; cs <- getCommentsFor loc ; return (sL loc (Nothing, mkHsOuterExplicit (EpAnn (glR $1) (mu AnnForall $1, mj AnnDot $3) cs) tvbs, $4)) } } | context '=>' type {% acs (\cs -> (sLLAA $1 $>(Just (addTrailingDarrowC $1 $2 cs), mkHsOuterImplicit, $3))) } | type { sL1A $1 (Nothing, mkHsOuterImplicit, $1) } capi_ctype :: { Maybe (LocatedP CType) } capi_ctype : '{-# CTYPE' STRING STRING '#-}' {% fmap Just $ amsrp (sLL $1 $> (CType (getCTYPEs $1) (Just (Header (getSTRINGs $2) (getSTRING $2))) (getSTRINGs $3,getSTRING $3))) (AnnPragma (mo $1) (mc $4) [mj AnnHeader $2,mj AnnVal $3]) } | '{-# CTYPE' STRING '#-}' {% fmap Just $ amsrp (sLL $1 $> (CType (getCTYPEs $1) Nothing (getSTRINGs $2, getSTRING $2))) (AnnPragma (mo $1) (mc $3) [mj AnnVal $2]) } | { Nothing } ----------------------------------------------------------------------------- -- Stand-alone deriving -- Glasgow extension: stand-alone deriving declarations stand_alone_deriving :: { LDerivDecl GhcPs } : 'deriving' deriv_standalone_strategy 'instance' overlap_pragma inst_type {% do { let { err = text "in the stand-alone deriving instance" <> colon <+> quotes (ppr $5) } ; acsA (\cs -> sLL $1 (reLoc $>) (DerivDecl (EpAnn (glR $1) [mj AnnDeriving $1, mj AnnInstance $3] cs) (mkHsWildCardBndrs $5) $2 $4)) }} ----------------------------------------------------------------------------- -- Role annotations role_annot :: { LRoleAnnotDecl GhcPs } role_annot : 'type' 'role' oqtycon maybe_roles {% mkRoleAnnotDecl (comb3N $1 $4 $3) $3 (reverse (unLoc $4)) [mj AnnType $1,mj AnnRole $2] } -- Reversed! maybe_roles :: { Located [Located (Maybe FastString)] } maybe_roles : {- empty -} { noLoc [] } | roles { $1 } roles :: { Located [Located (Maybe FastString)] } roles : role { sLL $1 $> [$1] } | roles role { sLL $1 $> $ $2 : unLoc $1 } -- read it in as a varid for better error messages role :: { Located (Maybe FastString) } role : VARID { sL1 $1 $ Just $ getVARID $1 } | '_' { sL1 $1 Nothing } -- Pattern synonyms -- Glasgow extension: pattern synonyms pattern_synonym_decl :: { LHsDecl GhcPs } : 'pattern' pattern_synonym_lhs '=' pat {% let (name, args, as ) = $2 in acsA (\cs -> sLL $1 (reLoc $>) . ValD noExtField $ mkPatSynBind name args $4 ImplicitBidirectional (EpAnn (glR $1) (as ++ [mj AnnPattern $1, mj AnnEqual $3]) cs)) } | 'pattern' pattern_synonym_lhs '<-' pat {% let (name, args, as) = $2 in acsA (\cs -> sLL $1 (reLoc $>) . ValD noExtField $ mkPatSynBind name args $4 Unidirectional (EpAnn (glR $1) (as ++ [mj AnnPattern $1,mu AnnLarrow $3]) cs)) } | 'pattern' pattern_synonym_lhs '<-' pat where_decls {% do { let (name, args, as) = $2 ; mg <- mkPatSynMatchGroup name $5 ; acsA (\cs -> sLL $1 (reLoc $>) . ValD noExtField $ mkPatSynBind name args $4 (ExplicitBidirectional mg) (EpAnn (glR $1) (as ++ [mj AnnPattern $1,mu AnnLarrow $3]) cs)) }} pattern_synonym_lhs :: { (LocatedN RdrName, HsPatSynDetails GhcPs, [AddEpAnn]) } : con vars0 { ($1, PrefixCon noTypeArgs $2, []) } | varid conop varid { ($2, InfixCon $1 $3, []) } | con '{' cvars1 '}' { ($1, RecCon $3, [moc $2, mcc $4] ) } vars0 :: { [LocatedN RdrName] } : {- empty -} { [] } | varid vars0 { $1 : $2 } cvars1 :: { [RecordPatSynField GhcPs] } : var { [RecordPatSynField (mkFieldOcc $1) $1] } | var ',' cvars1 {% do { h <- addTrailingCommaN $1 (gl $2) ; return ((RecordPatSynField (mkFieldOcc h) h) : $3 )}} where_decls :: { LocatedL (OrdList (LHsDecl GhcPs)) } : 'where' '{' decls '}' {% amsrl (sLL $1 $> (snd $ unLoc $3)) (AnnList (Just $ glR $3) (Just $ moc $2) (Just $ mcc $4) [mj AnnWhere $1] (fst $ unLoc $3)) } | 'where' vocurly decls close {% amsrl (sLL $1 $3 (snd $ unLoc $3)) (AnnList (Just $ glR $3) Nothing Nothing [mj AnnWhere $1] (fst $ unLoc $3))} pattern_synonym_sig :: { LSig GhcPs } : 'pattern' con_list '::' sigtype {% acsA (\cs -> sLL $1 (reLoc $>) $ PatSynSig (EpAnn (glR $1) (AnnSig (mu AnnDcolon $3) [mj AnnPattern $1]) cs) (unLoc $2) $4) } qvarcon :: { LocatedN RdrName } : qvar { $1 } | qcon { $1 } ----------------------------------------------------------------------------- -- Nested declarations -- Declaration in class bodies -- decl_cls :: { LHsDecl GhcPs } decl_cls : at_decl_cls { $1 } | decl { $1 } -- A 'default' signature used with the generic-programming extension | 'default' infixexp '::' sigtype {% runPV (unECP $2) >>= \ $2 -> do { v <- checkValSigLhs $2 ; let err = text "in default signature" <> colon <+> quotes (ppr $2) ; acsA (\cs -> sLL $1 (reLoc $>) $ SigD noExtField $ ClassOpSig (EpAnn (glR $1) (AnnSig (mu AnnDcolon $3) [mj AnnDefault $1]) cs) True [v] $4) }} decls_cls :: { Located ([AddEpAnn],OrdList (LHsDecl GhcPs)) } -- Reversed : decls_cls ';' decl_cls {% if isNilOL (snd $ unLoc $1) then return (sLLlA $1 $> ((mz AnnSemi $2) ++ (fst $ unLoc $1) , unitOL $3)) else case (snd $ unLoc $1) of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (sLLlA $1 $> (fst $ unLoc $1 , snocOL hs t' `appOL` unitOL $3)) } | decls_cls ';' {% if isNilOL (snd $ unLoc $1) then return (sLL $1 $> ((mz AnnSemi $2) ++ (fst $ unLoc $1) ,snd $ unLoc $1)) else case (snd $ unLoc $1) of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (sLL $1 $> (fst $ unLoc $1 , snocOL hs t')) } | decl_cls { sL1A $1 ([], unitOL $1) } | {- empty -} { noLoc ([],nilOL) } decllist_cls :: { Located ([AddEpAnn] , OrdList (LHsDecl GhcPs) , LayoutInfo) } -- Reversed : '{' decls_cls '}' { sLL $1 $> (moc $1:mcc $3:(fst $ unLoc $2) ,snd $ unLoc $2, ExplicitBraces) } | vocurly decls_cls close { let { L l (anns, decls) = $2 } in L l (anns, decls, VirtualBraces (getVOCURLY $1)) } -- Class body -- where_cls :: { Located ([AddEpAnn] ,(OrdList (LHsDecl GhcPs)) -- Reversed ,LayoutInfo) } -- No implicit parameters -- May have type declarations : 'where' decllist_cls { sLL $1 $> (mj AnnWhere $1:(fstOf3 $ unLoc $2) ,sndOf3 $ unLoc $2,thdOf3 $ unLoc $2) } | {- empty -} { noLoc ([],nilOL,NoLayoutInfo) } -- Declarations in instance bodies -- decl_inst :: { Located (OrdList (LHsDecl GhcPs)) } decl_inst : at_decl_inst { sL1A $1 (unitOL (sL1 $1 (InstD noExtField (unLoc $1)))) } | decl { sL1A $1 (unitOL $1) } decls_inst :: { Located ([AddEpAnn],OrdList (LHsDecl GhcPs)) } -- Reversed : decls_inst ';' decl_inst {% if isNilOL (snd $ unLoc $1) then return (sLL $1 $> ((mz AnnSemi $2) ++ (fst $ unLoc $1) , unLoc $3)) else case (snd $ unLoc $1) of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (sLL $1 $> (fst $ unLoc $1 , snocOL hs t' `appOL` unLoc $3)) } | decls_inst ';' {% if isNilOL (snd $ unLoc $1) then return (sLL $1 $> ((mz AnnSemi $2) ++ (fst $ unLoc $1) ,snd $ unLoc $1)) else case (snd $ unLoc $1) of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (sLL $1 $> (fst $ unLoc $1 , snocOL hs t')) } | decl_inst { sL1 $1 ([],unLoc $1) } | {- empty -} { noLoc ([],nilOL) } decllist_inst :: { Located ([AddEpAnn] , OrdList (LHsDecl GhcPs)) } -- Reversed : '{' decls_inst '}' { sLL $1 $> (moc $1:mcc $3:(fst $ unLoc $2),snd $ unLoc $2) } | vocurly decls_inst close { L (gl $2) (unLoc $2) } -- Instance body -- where_inst :: { Located ([AddEpAnn] , OrdList (LHsDecl GhcPs)) } -- Reversed -- No implicit parameters -- May have type declarations : 'where' decllist_inst { sLL $1 $> (mj AnnWhere $1:(fst $ unLoc $2) ,(snd $ unLoc $2)) } | {- empty -} { noLoc ([],nilOL) } -- Declarations in binding groups other than classes and instances -- decls :: { Located ([TrailingAnn], OrdList (LHsDecl GhcPs)) } : decls ';' decl {% if isNilOL (snd $ unLoc $1) then return (sLLlA $1 $> ((msemi $2) ++ (fst $ unLoc $1) , unitOL $3)) else case (snd $ unLoc $1) of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) let { this = unitOL $3; rest = snocOL hs t'; these = rest `appOL` this } return (rest `seq` this `seq` these `seq` (sLLlA $1 $> (fst $ unLoc $1, these))) } | decls ';' {% if isNilOL (snd $ unLoc $1) then return (sLL $1 $> (((msemi $2) ++ (fst $ unLoc $1) ,snd $ unLoc $1))) else case (snd $ unLoc $1) of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (sLL $1 $> (fst $ unLoc $1 , snocOL hs t')) } | decl { sL1A $1 ([], unitOL $1) } | {- empty -} { noLoc ([],nilOL) } decllist :: { Located (AnnList,Located (OrdList (LHsDecl GhcPs))) } : '{' decls '}' { sLL $1 $> (AnnList (Just $ glR $2) (Just $ moc $1) (Just $ mcc $3) [] (fst $ unLoc $2) ,sL1 $2 $ snd $ unLoc $2) } | vocurly decls close { L (gl $2) (AnnList (Just $ glR $2) Nothing Nothing [] (fst $ unLoc $2) ,sL1 $2 $ snd $ unLoc $2) } -- Binding groups other than those of class and instance declarations -- binds :: { Located (HsLocalBinds GhcPs) } -- May have implicit parameters -- No type declarations : decllist {% do { val_binds <- cvBindGroup (unLoc $ snd $ unLoc $1) ; cs <- getCommentsFor (gl $1) ; if (isNilOL (unLoc $ snd $ unLoc $1)) then return (sL1 $1 $ HsValBinds (EpAnn (glR $1) (AnnList (Just $ glR $1) Nothing Nothing [] []) cs) val_binds) else return (sL1 $1 $ HsValBinds (EpAnn (glR $1) (fst $ unLoc $1) cs) val_binds) } } | '{' dbinds '}' {% acs (\cs -> (L (comb3 $1 $2 $3) $ HsIPBinds (EpAnn (glR $1) (AnnList (Just$ glR $2) (Just $ moc $1) (Just $ mcc $3) [] []) cs) (IPBinds noExtField (reverse $ unLoc $2)))) } | vocurly dbinds close {% acs (\cs -> (L (gl $2) $ HsIPBinds (EpAnn (glR $1) (AnnList (Just $ glR $2) Nothing Nothing [] []) cs) (IPBinds noExtField (reverse $ unLoc $2)))) } wherebinds :: { Maybe (Located (HsLocalBinds GhcPs)) } -- May have implicit parameters -- No type declarations : 'where' binds { Just (sLL $1 $> (annBinds (mj AnnWhere $1) (unLoc $2))) } | {- empty -} { Nothing } ----------------------------------------------------------------------------- -- Transformation Rules rules :: { [LRuleDecl GhcPs] } -- Reversed : rules ';' rule {% case $1 of [] -> return ($3:$1) (h:t) -> do h' <- addTrailingSemiA h (gl $2) return ($3:h':t) } | rules ';' {% case $1 of [] -> return $1 (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (h':t) } | rule { [$1] } | {- empty -} { [] } rule :: { LRuleDecl GhcPs } : STRING rule_activation rule_foralls infixexp '=' exp {%runPV (unECP $4) >>= \ $4 -> runPV (unECP $6) >>= \ $6 -> acsA (\cs -> (sLLlA $1 $> $ HsRule { rd_ext = EpAnn (glR $1) ((fstOf3 $3) (mj AnnEqual $5 : (fst $2))) cs , rd_name = L (gl $1) (getSTRINGs $1, getSTRING $1) , rd_act = (snd $2) `orElse` AlwaysActive , rd_tyvs = sndOf3 $3, rd_tmvs = thdOf3 $3 , rd_lhs = $4, rd_rhs = $6 })) } -- Rules can be specified to be NeverActive, unlike inline/specialize pragmas rule_activation :: { ([AddEpAnn],Maybe Activation) } -- See Note [%shift: rule_activation -> {- empty -}] : {- empty -} %shift { ([],Nothing) } | rule_explicit_activation { (fst $1,Just (snd $1)) } -- This production is used to parse the tilde syntax in pragmas such as -- * {-# INLINE[~2] ... #-} -- * {-# SPECIALISE [~ 001] ... #-} -- * {-# RULES ... [~0] ... g #-} -- Note that it can be written either -- without a space [~1] (the PREFIX_TILDE case), or -- with a space [~ 1] (the VARSYM case). -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer rule_activation_marker :: { [AddEpAnn] } : PREFIX_TILDE { [mj AnnTilde $1] } | VARSYM {% if (getVARSYM $1 == fsLit "~") then return [mj AnnTilde $1] else do { addError $ PsError PsErrInvalidRuleActivationMarker [] (getLoc $1) ; return [] } } rule_explicit_activation :: { ([AddEpAnn] ,Activation) } -- In brackets : '[' INTEGER ']' { ([mos $1,mj AnnVal $2,mcs $3] ,ActiveAfter (getINTEGERs $2) (fromInteger (il_value (getINTEGER $2)))) } | '[' rule_activation_marker INTEGER ']' { ($2++[mos $1,mj AnnVal $3,mcs $4] ,ActiveBefore (getINTEGERs $3) (fromInteger (il_value (getINTEGER $3)))) } | '[' rule_activation_marker ']' { ($2++[mos $1,mcs $3] ,NeverActive) } rule_foralls :: { ([AddEpAnn] -> HsRuleAnn, Maybe [LHsTyVarBndr () GhcPs], [LRuleBndr GhcPs]) } : 'forall' rule_vars '.' 'forall' rule_vars '.' {% let tyvs = mkRuleTyVarBndrs $2 in hintExplicitForall $1 >> checkRuleTyVarBndrNames (mkRuleTyVarBndrs $2) >> return (\anns -> HsRuleAnn (Just (mu AnnForall $1,mj AnnDot $3)) (Just (mu AnnForall $4,mj AnnDot $6)) anns, Just (mkRuleTyVarBndrs $2), mkRuleBndrs $5) } -- See Note [%shift: rule_foralls -> 'forall' rule_vars '.'] | 'forall' rule_vars '.' %shift { (\anns -> HsRuleAnn Nothing (Just (mu AnnForall $1,mj AnnDot $3)) anns, Nothing, mkRuleBndrs $2) } -- See Note [%shift: rule_foralls -> {- empty -}] | {- empty -} %shift { (\anns -> HsRuleAnn Nothing Nothing anns, Nothing, []) } rule_vars :: { [LRuleTyTmVar] } : rule_var rule_vars { $1 : $2 } | {- empty -} { [] } rule_var :: { LRuleTyTmVar } : varid { sL1N $1 (RuleTyTmVar noAnn $1 Nothing) } | '(' varid '::' ctype ')' {% acs (\cs -> sLL $1 $> (RuleTyTmVar (EpAnn (glR $1) [mop $1,mu AnnDcolon $3,mcp $5] cs) $2 (Just $4))) } {- Note [Parsing explicit foralls in Rules] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We really want the above definition of rule_foralls to be: rule_foralls : 'forall' tv_bndrs '.' 'forall' rule_vars '.' | 'forall' rule_vars '.' | {- empty -} where rule_vars (term variables) can be named "forall", "family", or "role", but tv_vars (type variables) cannot be. However, such a definition results in a reduce/reduce conflict. For example, when parsing: > {-# RULE "name" forall a ... #-} before the '...' it is impossible to determine whether we should be in the first or second case of the above. This is resolved by using rule_vars (which is more general) for both, and ensuring that type-level quantified variables do not have the names "forall", "family", or "role" in the function 'checkRuleTyVarBndrNames' in GHC.Parser.PostProcess. Thus, whenever the definition of tyvarid (used for tv_bndrs) is changed relative to varid (used for rule_vars), 'checkRuleTyVarBndrNames' must be updated. -} ----------------------------------------------------------------------------- -- Warnings and deprecations (c.f. rules) warnings :: { OrdList (LWarnDecl GhcPs) } : warnings ';' warning {% if isNilOL $1 then return ($1 `appOL` $3) else case $1 of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (snocOL hs t' `appOL` $3) } | warnings ';' {% if isNilOL $1 then return $1 else case $1 of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (snocOL hs t') } | warning { $1 } | {- empty -} { nilOL } -- SUP: TEMPORARY HACK, not checking for `module Foo' warning :: { OrdList (LWarnDecl GhcPs) } : namelist strings {% fmap unitOL $ acsA (\cs -> sLL $1 $> (Warning (EpAnn (glR $1) (fst $ unLoc $2) cs) (unLoc $1) (WarningTxt (noLoc NoSourceText) $ snd $ unLoc $2))) } deprecations :: { OrdList (LWarnDecl GhcPs) } : deprecations ';' deprecation {% if isNilOL $1 then return ($1 `appOL` $3) else case $1 of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (snocOL hs t' `appOL` $3) } | deprecations ';' {% if isNilOL $1 then return $1 else case $1 of SnocOL hs t -> do t' <- addTrailingSemiA t (gl $2) return (snocOL hs t') } | deprecation { $1 } | {- empty -} { nilOL } -- SUP: TEMPORARY HACK, not checking for `module Foo' deprecation :: { OrdList (LWarnDecl GhcPs) } : namelist strings {% fmap unitOL $ acsA (\cs -> sLL $1 $> $ (Warning (EpAnn (glR $1) (fst $ unLoc $2) cs) (unLoc $1) (DeprecatedTxt (noLoc NoSourceText) $ snd $ unLoc $2))) } strings :: { Located ([AddEpAnn],[Located StringLiteral]) } : STRING { sL1 $1 ([],[L (gl $1) (getStringLiteral $1)]) } | '[' stringlist ']' { sLL $1 $> $ ([mos $1,mcs $3],fromOL (unLoc $2)) } stringlist :: { Located (OrdList (Located StringLiteral)) } : stringlist ',' STRING {% if isNilOL (unLoc $1) then return (sLL $1 $> (unLoc $1 `snocOL` (L (gl $3) (getStringLiteral $3)))) else case (unLoc $1) of SnocOL hs t -> do let { t' = addTrailingCommaS t (glAA $2) } return (sLL $1 $> (snocOL hs t' `snocOL` (L (gl $3) (getStringLiteral $3)))) } | STRING { sLL $1 $> (unitOL (L (gl $1) (getStringLiteral $1))) } | {- empty -} { noLoc nilOL } ----------------------------------------------------------------------------- -- Annotations annotation :: { LHsDecl GhcPs } : '{-# ANN' name_var aexp '#-}' {% runPV (unECP $3) >>= \ $3 -> acsA (\cs -> sLL $1 $> (AnnD noExtField $ HsAnnotation (EpAnn (glR $1) (AnnPragma (mo $1) (mc $4) []) cs) (getANN_PRAGs $1) (ValueAnnProvenance $2) $3)) } | '{-# ANN' 'type' otycon aexp '#-}' {% runPV (unECP $4) >>= \ $4 -> acsA (\cs -> sLL $1 $> (AnnD noExtField $ HsAnnotation (EpAnn (glR $1) (AnnPragma (mo $1) (mc $5) [mj AnnType $2]) cs) (getANN_PRAGs $1) (TypeAnnProvenance $3) $4)) } | '{-# ANN' 'module' aexp '#-}' {% runPV (unECP $3) >>= \ $3 -> acsA (\cs -> sLL $1 $> (AnnD noExtField $ HsAnnotation (EpAnn (glR $1) (AnnPragma (mo $1) (mc $4) [mj AnnModule $2]) cs) (getANN_PRAGs $1) ModuleAnnProvenance $3)) } ----------------------------------------------------------------------------- -- Foreign import and export declarations fdecl :: { Located ([AddEpAnn],EpAnn [AddEpAnn] -> HsDecl GhcPs) } fdecl : 'import' callconv safety fspec {% mkImport $2 $3 (snd $ unLoc $4) >>= \i -> return (sLL $1 $> (mj AnnImport $1 : (fst $ unLoc $4),i)) } | 'import' callconv fspec {% do { d <- mkImport $2 (noLoc PlaySafe) (snd $ unLoc $3); return (sLL $1 $> (mj AnnImport $1 : (fst $ unLoc $3),d)) }} | 'export' callconv fspec {% mkExport $2 (snd $ unLoc $3) >>= \i -> return (sLL $1 $> (mj AnnExport $1 : (fst $ unLoc $3),i) ) } callconv :: { Located CCallConv } : 'stdcall' { sLL $1 $> StdCallConv } | 'ccall' { sLL $1 $> CCallConv } | 'capi' { sLL $1 $> CApiConv } | 'prim' { sLL $1 $> PrimCallConv} | 'javascript' { sLL $1 $> JavaScriptCallConv } safety :: { Located Safety } : 'unsafe' { sLL $1 $> PlayRisky } | 'safe' { sLL $1 $> PlaySafe } | 'interruptible' { sLL $1 $> PlayInterruptible } fspec :: { Located ([AddEpAnn] ,(Located StringLiteral, LocatedN RdrName, LHsSigType GhcPs)) } : STRING var '::' sigtype { sLL $1 (reLoc $>) ([mu AnnDcolon $3] ,(L (getLoc $1) (getStringLiteral $1), $2, $4)) } | var '::' sigtype { sLL (reLocN $1) (reLoc $>) ([mu AnnDcolon $2] ,(noLoc (StringLiteral NoSourceText nilFS Nothing), $1, $3)) } -- if the entity string is missing, it defaults to the empty string; -- the meaning of an empty entity string depends on the calling -- convention ----------------------------------------------------------------------------- -- Type signatures opt_sig :: { Maybe (AddEpAnn, LHsType GhcPs) } : {- empty -} { Nothing } | '::' ctype { Just (mu AnnDcolon $1, $2) } opt_tyconsig :: { ([AddEpAnn], Maybe (LocatedN RdrName)) } : {- empty -} { ([], Nothing) } | '::' gtycon { ([mu AnnDcolon $1], Just $2) } -- Like ktype, but for types that obey the forall-or-nothing rule. -- See Note [forall-or-nothing rule] in GHC.Hs.Type. sigktype :: { LHsSigType GhcPs } : sigtype { $1 } | ctype '::' kind {% acsA (\cs -> sLLAA $1 $> $ mkHsImplicitSigType $ sLLa (reLoc $1) (reLoc $>) $ HsKindSig (EpAnn (glAR $1) [mu AnnDcolon $2] cs) $1 $3) } -- Like ctype, but for types that obey the forall-or-nothing rule. -- See Note [forall-or-nothing rule] in GHC.Hs.Type. To avoid duplicating the -- logic in ctype here, we simply reuse the ctype production and perform -- surgery on the LHsType it returns to turn it into an LHsSigType. sigtype :: { LHsSigType GhcPs } : ctype { hsTypeToHsSigType $1 } sig_vars :: { Located [LocatedN RdrName] } -- Returned in reversed order : sig_vars ',' var {% case unLoc $1 of [] -> return (sLL $1 (reLocN $>) ($3 : unLoc $1)) (h:t) -> do h' <- addTrailingCommaN h (gl $2) return (sLL $1 (reLocN $>) ($3 : h' : t)) } | var { sL1N $1 [$1] } sigtypes1 :: { OrdList (LHsSigType GhcPs) } : sigtype { unitOL $1 } | sigtype ',' sigtypes1 {% do { st <- addTrailingCommaA $1 (gl $2) ; return $ unitOL st `appOL` $3 } } ----------------------------------------------------------------------------- -- Types unpackedness :: { Located UnpackednessPragma } : '{-# UNPACK' '#-}' { sLL $1 $> (UnpackednessPragma [mo $1, mc $2] (getUNPACK_PRAGs $1) SrcUnpack) } | '{-# NOUNPACK' '#-}' { sLL $1 $> (UnpackednessPragma [mo $1, mc $2] (getNOUNPACK_PRAGs $1) SrcNoUnpack) } forall_telescope :: { Located (HsForAllTelescope GhcPs) } : 'forall' tv_bndrs '.' {% do { hintExplicitForall $1 ; acs (\cs -> (sLL $1 $> $ mkHsForAllInvisTele (EpAnn (glR $1) (mu AnnForall $1,mu AnnDot $3) cs) $2 )) }} | 'forall' tv_bndrs '->' {% do { hintExplicitForall $1 ; req_tvbs <- fromSpecTyVarBndrs $2 ; acs (\cs -> (sLL $1 $> $ mkHsForAllVisTele (EpAnn (glR $1) (mu AnnForall $1,mu AnnRarrow $3) cs) req_tvbs )) }} -- A ktype is a ctype, possibly with a kind annotation ktype :: { LHsType GhcPs } : ctype { $1 } | ctype '::' kind {% acsA (\cs -> sLLAA $1 $> $ HsKindSig (EpAnn (glAR $1) [mu AnnDcolon $2] cs) $1 $3) } -- A ctype is a for-all type ctype :: { LHsType GhcPs } : forall_telescope ctype { reLocA $ sLL $1 (reLoc $>) $ HsForAllTy { hst_tele = unLoc $1 , hst_xforall = noExtField , hst_body = $2 } } | context '=>' ctype {% acsA (\cs -> (sLL (reLoc $1) (reLoc $>) $ HsQualTy { hst_ctxt = Just (addTrailingDarrowC $1 $2 cs) , hst_xqual = NoExtField , hst_body = $3 })) } | ipvar '::' type {% acsA (\cs -> sLL $1 (reLoc $>) (HsIParamTy (EpAnn (glR $1) [mu AnnDcolon $2] cs) $1 $3)) } | type { $1 } ---------------------- -- Notes for 'context' -- We parse a context as a btype so that we don't get reduce/reduce -- errors in ctype. The basic problem is that -- (Eq a, Ord a) -- looks so much like a tuple type. We can't tell until we find the => context :: { LHsContext GhcPs } : btype {% checkContext $1 } {- Note [GADT decl discards annotations] ~~~~~~~~~~~~~~~~~~~~~ The type production for btype `->` ctype add the AnnRarrow annotation twice, in different places. This is because if the type is processed as usual, it belongs on the annotations for the type as a whole. But if the type is passed to mkGadtDecl, it discards the top level SrcSpan, and the top-level annotation will be disconnected. Hence for this specific case it is connected to the first type too. -} type :: { LHsType GhcPs } -- See Note [%shift: type -> btype] : btype %shift { $1 } | btype '->' ctype {% acsA (\cs -> sLL (reLoc $1) (reLoc $>) $ HsFunTy (EpAnn (glAR $1) (mau $2) cs) (HsUnrestrictedArrow (toUnicode $2)) $1 $3) } | btype mult '->' ctype {% hintLinear (getLoc $2) >> let arr = (unLoc $2) (toUnicode $3) in acsA (\cs -> sLL (reLoc $1) (reLoc $>) $ HsFunTy (EpAnn (glAR $1) (mau $3) cs) arr $1 $4) } | btype '->.' ctype {% hintLinear (getLoc $2) >> acsA (\cs -> sLL (reLoc $1) (reLoc $>) $ HsFunTy (EpAnn (glAR $1) (mau $2) cs) (HsLinearArrow UnicodeSyntax Nothing) $1 $3) } -- [mu AnnLollyU $2] } mult :: { Located (IsUnicodeSyntax -> HsArrow GhcPs) } : PREFIX_PERCENT atype { sLL $1 (reLoc $>) (\u -> mkMultTy u $1 $2) } btype :: { LHsType GhcPs } : infixtype {% runPV $1 } infixtype :: { forall b. DisambTD b => PV (LocatedA b) } -- See Note [%shift: infixtype -> ftype] : ftype %shift { $1 } | ftype tyop infixtype { $1 >>= \ $1 -> $3 >>= \ $3 -> do { when (looksLikeMult $1 $2 $3) $ hintLinear (getLocA $2) ; mkHsOpTyPV $1 $2 $3 } } | unpackedness infixtype { $2 >>= \ $2 -> mkUnpackednessPV $1 $2 } ftype :: { forall b. DisambTD b => PV (LocatedA b) } : atype { mkHsAppTyHeadPV $1 } | tyop { failOpFewArgs $1 } | ftype tyarg { $1 >>= \ $1 -> mkHsAppTyPV $1 $2 } | ftype PREFIX_AT atype { $1 >>= \ $1 -> mkHsAppKindTyPV $1 (getLoc $2) $3 } tyarg :: { LHsType GhcPs } : atype { $1 } | unpackedness atype {% addUnpackednessP $1 $2 } tyop :: { LocatedN RdrName } : qtyconop { $1 } | tyvarop { $1 } | SIMPLEQUOTE qconop {% amsrn (sLL $1 (reLoc $>) (unLoc $2)) (NameAnnQuote (glAA $1) (gl $2) []) } | SIMPLEQUOTE varop {% amsrn (sLL $1 (reLoc $>) (unLoc $2)) (NameAnnQuote (glAA $1) (gl $2) []) } atype :: { LHsType GhcPs } : ntgtycon {% acsa (\cs -> sL1a (reLocN $1) (HsTyVar (EpAnn (glNR $1) [] cs) NotPromoted $1)) } -- Not including unit tuples -- See Note [%shift: atype -> tyvar] | tyvar %shift {% acsa (\cs -> sL1a (reLocN $1) (HsTyVar (EpAnn (glNR $1) [] cs) NotPromoted $1)) } -- (See Note [Unit tuples]) | '*' {% do { warnStarIsType (getLoc $1) ; return $ reLocA $ sL1 $1 (HsStarTy noExtField (isUnicode $1)) } } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer | PREFIX_TILDE atype {% acsA (\cs -> sLLlA $1 $> (mkBangTy (EpAnn (glR $1) [mj AnnTilde $1] cs) SrcLazy $2)) } | PREFIX_BANG atype {% acsA (\cs -> sLLlA $1 $> (mkBangTy (EpAnn (glR $1) [mj AnnBang $1] cs) SrcStrict $2)) } | '{' fielddecls '}' {% do { decls <- acsA (\cs -> (sLL $1 $> $ HsRecTy (EpAnn (glR $1) (AnnList (Just $ listAsAnchor $2) (Just $ moc $1) (Just $ mcc $3) [] []) cs) $2)) ; checkRecordSyntax decls }} -- Constructor sigs only | '(' ')' {% acsA (\cs -> sLL $1 $> $ HsTupleTy (EpAnn (glR $1) (AnnParen AnnParens (glAA $1) (glAA $2)) cs) HsBoxedOrConstraintTuple []) } | '(' ktype ',' comma_types1 ')' {% do { h <- addTrailingCommaA $2 (gl $3) ; acsA (\cs -> sLL $1 $> $ HsTupleTy (EpAnn (glR $1) (AnnParen AnnParens (glAA $1) (glAA $5)) cs) HsBoxedOrConstraintTuple (h : $4)) }} | '(#' '#)' {% acsA (\cs -> sLL $1 $> $ HsTupleTy (EpAnn (glR $1) (AnnParen AnnParensHash (glAA $1) (glAA $2)) cs) HsUnboxedTuple []) } | '(#' comma_types1 '#)' {% acsA (\cs -> sLL $1 $> $ HsTupleTy (EpAnn (glR $1) (AnnParen AnnParensHash (glAA $1) (glAA $3)) cs) HsUnboxedTuple $2) } | '(#' bar_types2 '#)' {% acsA (\cs -> sLL $1 $> $ HsSumTy (EpAnn (glR $1) (AnnParen AnnParensHash (glAA $1) (glAA $3)) cs) $2) } | '[' ktype ']' {% acsA (\cs -> sLL $1 $> $ HsListTy (EpAnn (glR $1) (AnnParen AnnParensSquare (glAA $1) (glAA $3)) cs) $2) } | '(' ktype ')' {% acsA (\cs -> sLL $1 $> $ HsParTy (EpAnn (glR $1) (AnnParen AnnParens (glAA $1) (glAA $3)) cs) $2) } | quasiquote { mapLocA (HsSpliceTy noExtField) $1 } | splice_untyped { mapLocA (HsSpliceTy noExtField) $1 } -- see Note [Promotion] for the followings | SIMPLEQUOTE qcon_nowiredlist {% acsA (\cs -> sLL $1 (reLocN $>) $ HsTyVar (EpAnn (glR $1) [mj AnnSimpleQuote $1,mjN AnnName $2] cs) IsPromoted $2) } | SIMPLEQUOTE '(' ktype ',' comma_types1 ')' {% do { h <- addTrailingCommaA $3 (gl $4) ; acsA (\cs -> sLL $1 $> $ HsExplicitTupleTy (EpAnn (glR $1) [mj AnnSimpleQuote $1,mop $2,mcp $6] cs) (h : $5)) }} | SIMPLEQUOTE '[' comma_types0 ']' {% acsA (\cs -> sLL $1 $> $ HsExplicitListTy (EpAnn (glR $1) [mj AnnSimpleQuote $1,mos $2,mcs $4] cs) IsPromoted $3) } | SIMPLEQUOTE var {% acsA (\cs -> sLL $1 (reLocN $>) $ HsTyVar (EpAnn (glR $1) [mj AnnSimpleQuote $1,mjN AnnName $2] cs) IsPromoted $2) } -- Two or more [ty, ty, ty] must be a promoted list type, just as -- if you had written '[ty, ty, ty] -- (One means a list type, zero means the list type constructor, -- so you have to quote those.) | '[' ktype ',' comma_types1 ']' {% do { h <- addTrailingCommaA $2 (gl $3) ; acsA (\cs -> sLL $1 $> $ HsExplicitListTy (EpAnn (glR $1) [mos $1,mcs $5] cs) NotPromoted (h:$4)) }} | INTEGER { reLocA $ sLL $1 $> $ HsTyLit noExtField $ HsNumTy (getINTEGERs $1) (il_value (getINTEGER $1)) } | CHAR { reLocA $ sLL $1 $> $ HsTyLit noExtField $ HsCharTy (getCHARs $1) (getCHAR $1) } | STRING { reLocA $ sLL $1 $> $ HsTyLit noExtField $ HsStrTy (getSTRINGs $1) (getSTRING $1) } | '_' { reLocA $ sL1 $1 $ mkAnonWildCardTy } -- An inst_type is what occurs in the head of an instance decl -- e.g. (Foo a, Gaz b) => Wibble a b -- It's kept as a single type for convenience. inst_type :: { LHsSigType GhcPs } : sigtype { $1 } deriv_types :: { [LHsSigType GhcPs] } : sigktype { [$1] } | sigktype ',' deriv_types {% do { h <- addTrailingCommaA $1 (gl $2) ; return (h : $3) } } comma_types0 :: { [LHsType GhcPs] } -- Zero or more: ty,ty,ty : comma_types1 { $1 } | {- empty -} { [] } comma_types1 :: { [LHsType GhcPs] } -- One or more: ty,ty,ty : ktype { [$1] } | ktype ',' comma_types1 {% do { h <- addTrailingCommaA $1 (gl $2) ; return (h : $3) }} bar_types2 :: { [LHsType GhcPs] } -- Two or more: ty|ty|ty : ktype '|' ktype {% do { h <- addTrailingVbarA $1 (gl $2) ; return [h,$3] }} | ktype '|' bar_types2 {% do { h <- addTrailingVbarA $1 (gl $2) ; return (h : $3) }} tv_bndrs :: { [LHsTyVarBndr Specificity GhcPs] } : tv_bndr tv_bndrs { $1 : $2 } | {- empty -} { [] } tv_bndr :: { LHsTyVarBndr Specificity GhcPs } : tv_bndr_no_braces { $1 } | '{' tyvar '}' {% acsA (\cs -> sLL $1 $> (UserTyVar (EpAnn (glR $1) [mop $1, mcp $3] cs) InferredSpec $2)) } | '{' tyvar '::' kind '}' {% acsA (\cs -> sLL $1 $> (KindedTyVar (EpAnn (glR $1) [mop $1,mu AnnDcolon $3 ,mcp $5] cs) InferredSpec $2 $4)) } tv_bndr_no_braces :: { LHsTyVarBndr Specificity GhcPs } : tyvar {% acsA (\cs -> (sL1 (reLocN $1) (UserTyVar (EpAnn (glNR $1) [] cs) SpecifiedSpec $1))) } | '(' tyvar '::' kind ')' {% acsA (\cs -> (sLL $1 $> (KindedTyVar (EpAnn (glR $1) [mop $1,mu AnnDcolon $3 ,mcp $5] cs) SpecifiedSpec $2 $4))) } fds :: { Located ([AddEpAnn],[LHsFunDep GhcPs]) } : {- empty -} { noLoc ([],[]) } | '|' fds1 { (sLL $1 $> ([mj AnnVbar $1] ,reverse (unLoc $2))) } fds1 :: { Located [LHsFunDep GhcPs] } : fds1 ',' fd {% do { let (h:t) = unLoc $1 -- Safe from fds1 rules ; h' <- addTrailingCommaA h (gl $2) ; return (sLLlA $1 $> ($3 : h' : t)) }} | fd { sL1A $1 [$1] } fd :: { LHsFunDep GhcPs } : varids0 '->' varids0 {% acsA (\cs -> L (comb3 $1 $2 $3) (FunDep (EpAnn (glR $1) [mu AnnRarrow $2] cs) (reverse (unLoc $1)) (reverse (unLoc $3)))) } varids0 :: { Located [LocatedN RdrName] } : {- empty -} { noLoc [] } | varids0 tyvar { sLL $1 (reLocN $>) ($2 : (unLoc $1)) } ----------------------------------------------------------------------------- -- Kinds kind :: { LHsKind GhcPs } : ctype { $1 } {- Note [Promotion] ~~~~~~~~~~~~~~~~ - Syntax of promoted qualified names We write 'Nat.Zero instead of Nat.'Zero when dealing with qualified names. Moreover ticks are only allowed in types, not in kinds, for a few reasons: 1. we don't need quotes since we cannot define names in kinds 2. if one day we merge types and kinds, tick would mean look in DataName 3. we don't have a kind namespace anyway - Name resolution When the user write Zero instead of 'Zero in types, we parse it a HsTyVar ("Zero", TcClsName) instead of HsTyVar ("Zero", DataName). We deal with this in the renamer. If a HsTyVar ("Zero", TcClsName) is not bounded in the type level, then we look for it in the term level (we change its namespace to DataName, see Note [Demotion] in GHC.Types.Names.OccName). And both become a HsTyVar ("Zero", DataName) after the renamer. -} ----------------------------------------------------------------------------- -- Datatype declarations gadt_constrlist :: { Located ([AddEpAnn] ,[LConDecl GhcPs]) } -- Returned in order : 'where' '{' gadt_constrs '}' {% checkEmptyGADTs $ L (comb2 $1 $3) ([mj AnnWhere $1 ,moc $2 ,mcc $4] , unLoc $3) } | 'where' vocurly gadt_constrs close {% checkEmptyGADTs $ L (comb2 $1 $3) ([mj AnnWhere $1] , unLoc $3) } | {- empty -} { noLoc ([],[]) } gadt_constrs :: { Located [LConDecl GhcPs] } : gadt_constr ';' gadt_constrs {% do { h <- addTrailingSemiA $1 (gl $2) ; return (L (comb2 (reLoc $1) $3) (h : unLoc $3)) }} | gadt_constr { L (glA $1) [$1] } | {- empty -} { noLoc [] } -- We allow the following forms: -- C :: Eq a => a -> T a -- C :: forall a. Eq a => !a -> T a -- D { x,y :: a } :: T a -- forall a. Eq a => D { x,y :: a } :: T a gadt_constr :: { LConDecl GhcPs } -- see Note [Difference in parsing GADT and data constructors] -- Returns a list because of: C,D :: ty -- TODO:AZ capture the optSemi. Why leading? : optSemi con_list '::' sigtype {% mkGadtDecl (comb2A $2 $>) (unLoc $2) $4 [mu AnnDcolon $3] } {- Note [Difference in parsing GADT and data constructors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ GADT constructors have simpler syntax than usual data constructors: in GADTs, types cannot occur to the left of '::', so they cannot be mixed with constructor names (see Note [Parsing data constructors is hard]). Due to simplified syntax, GADT constructor names (left-hand side of '::') use simpler grammar production than usual data constructor names. As a consequence, GADT constructor names are restricted (names like '(*)' are allowed in usual data constructors, but not in GADTs). -} constrs :: { Located ([AddEpAnn],[LConDecl GhcPs]) } : '=' constrs1 { sLL $1 $2 ([mj AnnEqual $1],unLoc $2)} constrs1 :: { Located [LConDecl GhcPs] } : constrs1 '|' constr {% do { let (h:t) = unLoc $1 ; h' <- addTrailingVbarA h (gl $2) ; return (sLLlA $1 $> ($3 : h' : t)) }} | constr { sL1A $1 [$1] } constr :: { LConDecl GhcPs } : forall context '=>' constr_stuff {% acsA (\cs -> let (con,details) = unLoc $4 in (L (comb4 $1 (reLoc $2) $3 $4) (mkConDeclH98 (EpAnn (spanAsAnchor (comb4 $1 (reLoc $2) $3 $4)) (mu AnnDarrow $3:(fst $ unLoc $1)) cs) con (snd $ unLoc $1) (Just $2) details))) } | forall constr_stuff {% acsA (\cs -> let (con,details) = unLoc $2 in (L (comb2 $1 $2) (mkConDeclH98 (EpAnn (spanAsAnchor (comb2 $1 $2)) (fst $ unLoc $1) cs) con (snd $ unLoc $1) Nothing -- No context details))) } forall :: { Located ([AddEpAnn], Maybe [LHsTyVarBndr Specificity GhcPs]) } : 'forall' tv_bndrs '.' { sLL $1 $> ([mu AnnForall $1,mj AnnDot $3], Just $2) } | {- empty -} { noLoc ([], Nothing) } constr_stuff :: { Located (LocatedN RdrName, HsConDeclH98Details GhcPs) } : infixtype {% fmap (reLoc. (mapLoc (\b -> (dataConBuilderCon b, dataConBuilderDetails b)))) (runPV $1) } fielddecls :: { [LConDeclField GhcPs] } : {- empty -} { [] } | fielddecls1 { $1 } fielddecls1 :: { [LConDeclField GhcPs] } : fielddecl ',' fielddecls1 {% do { h <- addTrailingCommaA $1 (gl $2) ; return (h : $3) }} | fielddecl { [$1] } fielddecl :: { LConDeclField GhcPs } -- A list because of f,g :: Int : sig_vars '::' ctype {% acsA (\cs -> L (comb2 $1 (reLoc $3)) (ConDeclField (EpAnn (glR $1) [mu AnnDcolon $2] cs) (reverse (map (\ln@(L l n) -> L (locA l) $ FieldOcc noExtField ln) (unLoc $1))) $3 Nothing))} -- Reversed! maybe_derivings :: { Located (HsDeriving GhcPs) } : {- empty -} { noLoc [] } | derivings { $1 } -- A list of one or more deriving clauses at the end of a datatype derivings :: { Located (HsDeriving GhcPs) } : derivings deriving { sLL $1 $> ($2 : unLoc $1) } -- AZ: order? | deriving { sLL $1 $> [$1] } -- The outer Located is just to allow the caller to -- know the rightmost extremity of the 'deriving' clause deriving :: { LHsDerivingClause GhcPs } : 'deriving' deriv_clause_types {% let { full_loc = comb2A $1 $> } in acs (\cs -> L full_loc $ HsDerivingClause (EpAnn (glR $1) [mj AnnDeriving $1] cs) Nothing $2) } | 'deriving' deriv_strategy_no_via deriv_clause_types {% let { full_loc = comb2A $1 $> } in acs (\cs -> L full_loc $ HsDerivingClause (EpAnn (glR $1) [mj AnnDeriving $1] cs) (Just $2) $3) } | 'deriving' deriv_clause_types deriv_strategy_via {% let { full_loc = comb2 $1 $> } in acs (\cs -> L full_loc $ HsDerivingClause (EpAnn (glR $1) [mj AnnDeriving $1] cs) (Just $3) $2) } deriv_clause_types :: { LDerivClauseTys GhcPs } : qtycon { let { tc = sL1 (reLocL $1) $ mkHsImplicitSigType $ sL1 (reLocL $1) $ HsTyVar noAnn NotPromoted $1 } in sL1 (reLocC $1) (DctSingle noExtField tc) } | '(' ')' {% amsrc (sLL $1 $> (DctMulti noExtField [])) (AnnContext Nothing [glAA $1] [glAA $2]) } | '(' deriv_types ')' {% amsrc (sLL $1 $> (DctMulti noExtField $2)) (AnnContext Nothing [glAA $1] [glAA $3])} ----------------------------------------------------------------------------- -- Value definitions {- Note [Declaration/signature overlap] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There's an awkward overlap with a type signature. Consider f :: Int -> Int = ...rhs... Then we can't tell whether it's a type signature or a value definition with a result signature until we see the '='. So we have to inline enough to postpone reductions until we know. -} {- ATTENTION: Dirty Hackery Ahead! If the second alternative of vars is var instead of qvar, we get another shift/reduce-conflict. Consider the following programs: { (^^) :: Int->Int ; } Type signature; only var allowed { (^^) :: Int->Int = ... ; } Value defn with result signature; qvar allowed (because of instance decls) We can't tell whether to reduce var to qvar until after we've read the signatures. -} decl_no_th :: { LHsDecl GhcPs } : sigdecl { $1 } | infixexp opt_sig rhs {% runPV (unECP $1) >>= \ $1 -> do { let { l = comb2Al $1 $> } ; r <- checkValDef l $1 $2 $3; -- Depending upon what the pattern looks like we might get either -- a FunBind or PatBind back from checkValDef. See Note -- [FunBind vs PatBind] ; cs <- getCommentsFor l ; return $! (sL (commentsA l cs) $ ValD noExtField r) } } | pattern_synonym_decl { $1 } decl :: { LHsDecl GhcPs } : decl_no_th { $1 } -- Why do we only allow naked declaration splices in top-level -- declarations and not here? Short answer: because readFail009 -- fails terribly with a panic in cvBindsAndSigs otherwise. | splice_exp {% mkSpliceDecl $1 } rhs :: { Located (GRHSs GhcPs (LHsExpr GhcPs)) } : '=' exp wherebinds {% runPV (unECP $2) >>= \ $2 -> do { let loc = (comb3 $1 (reLoc $2) (adaptWhereBinds $3)) ; acs (\cs -> sL loc (GRHSs NoExtField (unguardedRHS (EpAnn (anc $ rs loc) (GrhsAnn Nothing (mj AnnEqual $1)) cs) loc $2) (unLoc $ (adaptWhereBinds $3)))) } } | gdrhs wherebinds { sL (comb2 $1 (adaptWhereBinds $>)) (GRHSs noExtField (reverse (unLoc $1)) (unLoc $ (adaptWhereBinds $2))) } gdrhs :: { Located [LGRHS GhcPs (LHsExpr GhcPs)] } : gdrhs gdrh { sLL $1 $> ($2 : unLoc $1) } | gdrh { sL1 $1 [$1] } gdrh :: { LGRHS GhcPs (LHsExpr GhcPs) } : '|' guardquals '=' exp {% runPV (unECP $4) >>= \ $4 -> acs (\cs -> sL (comb2A $1 $>) $ GRHS (EpAnn (glR $1) (GrhsAnn (Just $ glAA $1) (mj AnnEqual $3)) cs) (unLoc $2) $4) } sigdecl :: { LHsDecl GhcPs } : -- See Note [Declaration/signature overlap] for why we need infixexp here infixexp '::' sigtype {% do { $1 <- runPV (unECP $1) ; v <- checkValSigLhs $1 ; acsA (\cs -> (sLLAl $1 (reLoc $>) $ SigD noExtField $ TypeSig (EpAnn (glAR $1) (AnnSig (mu AnnDcolon $2) []) cs) [v] (mkHsWildCardBndrs $3)))} } | var ',' sig_vars '::' sigtype {% do { v <- addTrailingCommaN $1 (gl $2) ; let sig cs = TypeSig (EpAnn (glNR $1) (AnnSig (mu AnnDcolon $4) []) cs) (v : reverse (unLoc $3)) (mkHsWildCardBndrs $5) ; acsA (\cs -> sLL (reLocN $1) (reLoc $>) $ SigD noExtField (sig cs) ) }} | infix prec ops {% checkPrecP $2 $3 >> acsA (\cs -> sLL $1 $> $ SigD noExtField (FixSig (EpAnn (glR $1) [mj AnnInfix $1,mj AnnVal $2] cs) (FixitySig noExtField (fromOL $ unLoc $3) (Fixity (fst $ unLoc $2) (snd $ unLoc $2) (unLoc $1))))) } | pattern_synonym_sig { sL1 $1 . SigD noExtField . unLoc $ $1 } | '{-# COMPLETE' con_list opt_tyconsig '#-}' {% let (dcolon, tc) = $3 in acsA (\cs -> sLL $1 $> (SigD noExtField (CompleteMatchSig (EpAnn (glR $1) ([ mo $1 ] ++ dcolon ++ [mc $4]) cs) (getCOMPLETE_PRAGs $1) $2 tc))) } -- This rule is for both INLINE and INLINABLE pragmas | '{-# INLINE' activation qvarcon '#-}' {% acsA (\cs -> (sLL $1 $> $ SigD noExtField (InlineSig (EpAnn (glR $1) ((mo $1:fst $2) ++ [mc $4]) cs) $3 (mkInlinePragma (getINLINE_PRAGs $1) (getINLINE $1) (snd $2))))) } | '{-# SCC' qvar '#-}' {% acsA (\cs -> sLL $1 $> (SigD noExtField (SCCFunSig (EpAnn (glR $1) [mo $1, mc $3] cs) (getSCC_PRAGs $1) $2 Nothing))) } | '{-# SCC' qvar STRING '#-}' {% do { scc <- getSCC $3 ; let str_lit = StringLiteral (getSTRINGs $3) scc Nothing ; acsA (\cs -> sLL $1 $> (SigD noExtField (SCCFunSig (EpAnn (glR $1) [mo $1, mc $4] cs) (getSCC_PRAGs $1) $2 (Just ( sL1 $3 str_lit))))) }} | '{-# SPECIALISE' activation qvar '::' sigtypes1 '#-}' {% acsA (\cs -> let inl_prag = mkInlinePragma (getSPEC_PRAGs $1) (NoUserInlinePrag, FunLike) (snd $2) in sLL $1 $> $ SigD noExtField (SpecSig (EpAnn (glR $1) (mo $1:mu AnnDcolon $4:mc $6:(fst $2)) cs) $3 (fromOL $5) inl_prag)) } | '{-# SPECIALISE_INLINE' activation qvar '::' sigtypes1 '#-}' {% acsA (\cs -> sLL $1 $> $ SigD noExtField (SpecSig (EpAnn (glR $1) (mo $1:mu AnnDcolon $4:mc $6:(fst $2)) cs) $3 (fromOL $5) (mkInlinePragma (getSPEC_INLINE_PRAGs $1) (getSPEC_INLINE $1) (snd $2)))) } | '{-# SPECIALISE' 'instance' inst_type '#-}' {% acsA (\cs -> sLL $1 $> $ SigD noExtField (SpecInstSig (EpAnn (glR $1) [mo $1,mj AnnInstance $2,mc $4] cs) (getSPEC_PRAGs $1) $3)) } -- A minimal complete definition | '{-# MINIMAL' name_boolformula_opt '#-}' {% acsA (\cs -> sLL $1 $> $ SigD noExtField (MinimalSig (EpAnn (glR $1) [mo $1,mc $3] cs) (getMINIMAL_PRAGs $1) $2)) } activation :: { ([AddEpAnn],Maybe Activation) } -- See Note [%shift: activation -> {- empty -}] : {- empty -} %shift { ([],Nothing) } | explicit_activation { (fst $1,Just (snd $1)) } explicit_activation :: { ([AddEpAnn],Activation) } -- In brackets : '[' INTEGER ']' { ([mj AnnOpenS $1,mj AnnVal $2,mj AnnCloseS $3] ,ActiveAfter (getINTEGERs $2) (fromInteger (il_value (getINTEGER $2)))) } | '[' rule_activation_marker INTEGER ']' { ($2++[mj AnnOpenS $1,mj AnnVal $3,mj AnnCloseS $4] ,ActiveBefore (getINTEGERs $3) (fromInteger (il_value (getINTEGER $3)))) } ----------------------------------------------------------------------------- -- Expressions quasiquote :: { Located (HsSplice GhcPs) } : TH_QUASIQUOTE { let { loc = getLoc $1 ; ITquasiQuote (quoter, quote, quoteSpan) = unLoc $1 ; quoterId = mkUnqual varName quoter } in sL1 $1 (mkHsQuasiQuote quoterId (mkSrcSpanPs quoteSpan) quote) } | TH_QQUASIQUOTE { let { loc = getLoc $1 ; ITqQuasiQuote (qual, quoter, quote, quoteSpan) = unLoc $1 ; quoterId = mkQual varName (qual, quoter) } in sL1 $1 (mkHsQuasiQuote quoterId (mkSrcSpanPs quoteSpan) quote) } exp :: { ECP } : infixexp '::' ctype { ECP $ unECP $1 >>= \ $1 -> rejectPragmaPV $1 >> mkHsTySigPV (noAnnSrcSpan $ comb2Al $1 (reLoc $>)) $1 $3 [(mu AnnDcolon $2)] } | infixexp '-<' exp {% runPV (unECP $1) >>= \ $1 -> runPV (unECP $3) >>= \ $3 -> fmap ecpFromCmd $ acsA (\cs -> sLLAA $1 $> $ HsCmdArrApp (EpAnn (glAR $1) (mu Annlarrowtail $2) cs) $1 $3 HsFirstOrderApp True) } | infixexp '>-' exp {% runPV (unECP $1) >>= \ $1 -> runPV (unECP $3) >>= \ $3 -> fmap ecpFromCmd $ acsA (\cs -> sLLAA $1 $> $ HsCmdArrApp (EpAnn (glAR $1) (mu Annrarrowtail $2) cs) $3 $1 HsFirstOrderApp False) } | infixexp '-<<' exp {% runPV (unECP $1) >>= \ $1 -> runPV (unECP $3) >>= \ $3 -> fmap ecpFromCmd $ acsA (\cs -> sLLAA $1 $> $ HsCmdArrApp (EpAnn (glAR $1) (mu AnnLarrowtail $2) cs) $1 $3 HsHigherOrderApp True) } | infixexp '>>-' exp {% runPV (unECP $1) >>= \ $1 -> runPV (unECP $3) >>= \ $3 -> fmap ecpFromCmd $ acsA (\cs -> sLLAA $1 $> $ HsCmdArrApp (EpAnn (glAR $1) (mu AnnRarrowtail $2) cs) $3 $1 HsHigherOrderApp False) } -- See Note [%shift: exp -> infixexp] | infixexp %shift { $1 } | exp_prag(exp) { $1 } -- See Note [Pragmas and operator fixity] infixexp :: { ECP } : exp10 { $1 } | infixexp qop exp10p -- See Note [Pragmas and operator fixity] { ECP $ superInfixOp $ $2 >>= \ $2 -> unECP $1 >>= \ $1 -> unECP $3 >>= \ $3 -> rejectPragmaPV $1 >> (mkHsOpAppPV (comb2A (reLoc $1) $3) $1 $2 $3) } -- AnnVal annotation for NPlusKPat, which discards the operator exp10p :: { ECP } : exp10 { $1 } | exp_prag(exp10p) { $1 } -- See Note [Pragmas and operator fixity] exp_prag(e) :: { ECP } : prag_e e -- See Note [Pragmas and operator fixity] {% runPV (unECP $2) >>= \ $2 -> fmap ecpFromExp $ return $ (reLocA $ sLLlA $1 $> $ HsPragE noExtField (unLoc $1) $2) } exp10 :: { ECP } -- See Note [%shift: exp10 -> '-' fexp] : '-' fexp %shift { ECP $ unECP $2 >>= \ $2 -> mkHsNegAppPV (comb2A $1 $>) $2 [mj AnnMinus $1] } -- See Note [%shift: exp10 -> fexp] | fexp %shift { $1 } optSemi :: { ([Located Token],Bool) } : ';' { ([$1],True) } | {- empty -} { ([],False) } {- Note [Pragmas and operator fixity] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 'prag_e' is an expression pragma, such as {-# SCC ... #-}. It must be used with care, or else #15730 happens. Consider this infix expression: 1 / 2 / 2 There are two ways to parse it: 1. (1 / 2) / 2 = 0.25 2. 1 / (2 / 2) = 1.0 Due to the fixity of the (/) operator (assuming it comes from Prelude), option 1 is the correct parse. However, in the past GHC's parser used to get confused by the SCC annotation when it occurred in the middle of an infix expression: 1 / {-# SCC ann #-} 2 / 2 -- used to get parsed as option 2 There are several ways to address this issue, see GHC Proposal #176 for a detailed exposition: https://github.com/ghc-proposals/ghc-proposals/blob/master/proposals/0176-scc-parsing.rst The accepted fix is to disallow pragmas that occur within infix expressions. Infix expressions are assembled out of 'exp10', so 'exp10' must not accept pragmas. Instead, we accept them in exactly two places: * at the start of an expression or a parenthesized subexpression: f = {-# SCC ann #-} 1 / 2 / 2 -- at the start of the expression g = 5 + ({-# SCC ann #-} 1 / 2 / 2) -- at the start of a parenthesized subexpression * immediately after the last operator: f = 1 / 2 / {-# SCC ann #-} 2 In both cases, the parse does not depend on operator fixity. The second case may sound unnecessary, but it's actually needed to support a common idiom: f $ {-# SCC ann $-} ... -} prag_e :: { Located (HsPragE GhcPs) } : '{-# SCC' STRING '#-}' {% do { scc <- getSCC $2 ; acs (\cs -> (sLL $1 $> (HsPragSCC (EpAnn (glR $1) (AnnPragma (mo $1) (mc $3) [mj AnnValStr $2]) cs) (getSCC_PRAGs $1) (StringLiteral (getSTRINGs $2) scc Nothing))))} } | '{-# SCC' VARID '#-}' {% acs (\cs -> (sLL $1 $> (HsPragSCC (EpAnn (glR $1) (AnnPragma (mo $1) (mc $3) [mj AnnVal $2]) cs) (getSCC_PRAGs $1) (StringLiteral NoSourceText (getVARID $2) Nothing)))) } fexp :: { ECP } : fexp aexp { ECP $ superFunArg $ unECP $1 >>= \ $1 -> unECP $2 >>= \ $2 -> mkHsAppPV (noAnnSrcSpan $ comb2A (reLoc $1) $>) $1 $2 } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer | fexp PREFIX_AT atype { ECP $ unECP $1 >>= \ $1 -> mkHsAppTypePV (noAnnSrcSpan $ comb2 (reLoc $1) (reLoc $>)) $1 (getLoc $2) $3 } | 'static' aexp {% runPV (unECP $2) >>= \ $2 -> fmap ecpFromExp $ acsA (\cs -> sLL $1 (reLoc $>) $ HsStatic (EpAnn (glR $1) [mj AnnStatic $1] cs) $2) } | aexp { $1 } aexp :: { ECP } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer : qvar TIGHT_INFIX_AT aexp { ECP $ unECP $3 >>= \ $3 -> mkHsAsPatPV (comb2 (reLocN $1) (reLoc $>)) $1 $3 [mj AnnAt $2] } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer | PREFIX_TILDE aexp { ECP $ unECP $2 >>= \ $2 -> mkHsLazyPatPV (comb2 $1 (reLoc $>)) $2 [mj AnnTilde $1] } | PREFIX_BANG aexp { ECP $ unECP $2 >>= \ $2 -> mkHsBangPatPV (comb2 $1 (reLoc $>)) $2 [mj AnnBang $1] } | PREFIX_MINUS aexp { ECP $ unECP $2 >>= \ $2 -> mkHsNegAppPV (comb2A $1 $>) $2 [mj AnnMinus $1] } | '\\' apat apats '->' exp { ECP $ unECP $5 >>= \ $5 -> mkHsLamPV (comb2 $1 (reLoc $>)) (\cs -> mkMatchGroup FromSource (reLocA $ sLLlA $1 $> [reLocA $ sLLlA $1 $> $ Match { m_ext = EpAnn (glR $1) [mj AnnLam $1] cs , m_ctxt = LambdaExpr , m_pats = $2:$3 , m_grhss = unguardedGRHSs (comb2 $4 (reLoc $5)) $5 (EpAnn (glR $4) (GrhsAnn Nothing (mu AnnRarrow $4)) emptyComments) }])) } | 'let' binds 'in' exp { ECP $ unECP $4 >>= \ $4 -> mkHsLetPV (comb2A $1 $>) (unLoc $2) $4 (AnnsLet (glAA $1) (glAA $3)) } | '\\' 'lcase' altslist { ECP $ $3 >>= \ $3 -> mkHsLamCasePV (comb2 $1 (reLoc $>)) $3 [mj AnnLam $1,mj AnnCase $2] } | 'if' exp optSemi 'then' exp optSemi 'else' exp {% runPV (unECP $2) >>= \ ($2 :: LHsExpr GhcPs) -> return $ ECP $ unECP $5 >>= \ $5 -> unECP $8 >>= \ $8 -> mkHsIfPV (comb2A $1 $>) $2 (snd $3) $5 (snd $6) $8 (mj AnnIf $1:mj AnnThen $4 :mj AnnElse $7 :(concatMap (\l -> mz AnnSemi l) (fst $3)) ++(concatMap (\l -> mz AnnSemi l) (fst $6))) } | 'if' ifgdpats {% hintMultiWayIf (getLoc $1) >>= \_ -> fmap ecpFromExp $ acsA (\cs -> sLL $1 $> $ HsMultiIf (EpAnn (glR $1) (mj AnnIf $1:(fst $ unLoc $2)) cs) (reverse $ snd $ unLoc $2)) } | 'case' exp 'of' altslist {% runPV (unECP $2) >>= \ ($2 :: LHsExpr GhcPs) -> return $ ECP $ $4 >>= \ $4 -> mkHsCasePV (comb3 $1 $3 (reLoc $4)) $2 $4 (EpAnnHsCase (glAA $1) (glAA $3) []) } -- QualifiedDo. | DO stmtlist {% do hintQualifiedDo $1 return $ ECP $ $2 >>= \ $2 -> mkHsDoPV (comb2A $1 $2) (fmap mkModuleNameFS (getDO $1)) $2 (AnnList (Just $ glAR $2) Nothing Nothing [mj AnnDo $1] []) } | MDO stmtlist {% hintQualifiedDo $1 >> runPV $2 >>= \ $2 -> fmap ecpFromExp $ acsA (\cs -> L (comb2A $1 $2) (mkHsDoAnns (MDoExpr $ fmap mkModuleNameFS (getMDO $1)) $2 (EpAnn (glR $1) (AnnList (Just $ glAR $2) Nothing Nothing [mj AnnMdo $1] []) cs) )) } | 'proc' aexp '->' exp {% (checkPattern <=< runPV) (unECP $2) >>= \ p -> runPV (unECP $4) >>= \ $4@cmd -> fmap ecpFromExp $ acsA (\cs -> sLLlA $1 $> $ HsProc (EpAnn (glR $1) [mj AnnProc $1,mu AnnRarrow $3] cs) p (sLLlA $1 $> $ HsCmdTop noExtField cmd)) } | aexp1 { $1 } aexp1 :: { ECP } : aexp1 '{' fbinds '}' { ECP $ getBit OverloadedRecordUpdateBit >>= \ overloaded -> unECP $1 >>= \ $1 -> $3 >>= \ $3 -> mkHsRecordPV overloaded (comb2 (reLoc $1) $>) (comb2 $2 $4) $1 $3 [moc $2,mcc $4] } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer | aexp1 TIGHT_INFIX_PROJ field {% runPV (unECP $1) >>= \ $1 -> fmap ecpFromExp $ acsa (\cs -> let fl = sLL $2 $> (HsFieldLabel ((EpAnn (glR $2) (AnnFieldLabel (Just $ glAA $2)) emptyComments)) $3) in mkRdrGetField (noAnnSrcSpan $ comb2 (reLoc $1) $>) $1 fl (EpAnn (glAR $1) NoEpAnns cs)) } | aexp2 { $1 } aexp2 :: { ECP } : qvar { ECP $ mkHsVarPV $! $1 } | qcon { ECP $ mkHsVarPV $! $1 } -- See Note [%shift: aexp2 -> ipvar] | ipvar %shift {% acsExpr (\cs -> sL1a $1 (HsIPVar (comment (glRR $1) cs) $! unLoc $1)) } | overloaded_label {% acsExpr (\cs -> sL1a $1 (HsOverLabel (comment (glRR $1) cs) $! unLoc $1)) } | literal { ECP $ pvA (mkHsLitPV $! $1) } -- This will enable overloaded strings permanently. Normally the renamer turns HsString -- into HsOverLit when -foverloaded-strings is on. -- | STRING { sL (getLoc $1) (HsOverLit $! mkHsIsString (getSTRINGs $1) -- (getSTRING $1) noExtField) } | INTEGER { ECP $ pvA $ mkHsOverLitPV (sL1 $1 $ mkHsIntegral (getINTEGER $1)) } | RATIONAL { ECP $ pvA $ mkHsOverLitPV (sL1 $1 $ mkHsFractional (getRATIONAL $1)) } -- N.B.: sections get parsed by these next two productions. -- This allows you to write, e.g., '(+ 3, 4 -)', which isn't -- correct Haskell (you'd have to write '((+ 3), (4 -))') -- but the less cluttered version fell out of having texps. | '(' texp ')' { ECP $ unECP $2 >>= \ $2 -> mkHsParPV (comb2 $1 $>) $2 (AnnParen AnnParens (glAA $1) (glAA $3)) } | '(' tup_exprs ')' { ECP $ $2 >>= \ $2 -> mkSumOrTuplePV (noAnnSrcSpan $ comb2 $1 $>) Boxed $2 [mop $1,mcp $3]} -- This case is only possible when 'OverloadedRecordDotBit' is enabled. | '(' projection ')' { ECP $ acsA (\cs -> sLL $1 $> $ mkRdrProjection (reverse (unLoc $2)) (EpAnn (glR $1) (AnnProjection (glAA $1) (glAA $3)) cs)) >>= ecpFromExp' } | '(#' texp '#)' { ECP $ unECP $2 >>= \ $2 -> mkSumOrTuplePV (noAnnSrcSpan $ comb2 $1 $>) Unboxed (Tuple [Right $2]) [moh $1,mch $3] } | '(#' tup_exprs '#)' { ECP $ $2 >>= \ $2 -> mkSumOrTuplePV (noAnnSrcSpan $ comb2 $1 $>) Unboxed $2 [moh $1,mch $3] } | '[' list ']' { ECP $ $2 (comb2 $1 $>) (mos $1,mcs $3) } | '_' { ECP $ pvA $ mkHsWildCardPV (getLoc $1) } -- Template Haskell Extension | splice_untyped { ECP $ pvA $ mkHsSplicePV $1 } | splice_typed { ecpFromExp $ mapLoc (HsSpliceE noAnn) (reLocA $1) } | SIMPLEQUOTE qvar {% fmap ecpFromExp $ acsA (\cs -> sLL $1 (reLocN $>) $ HsBracket (EpAnn (glR $1) [mj AnnSimpleQuote $1] cs) (VarBr noExtField True $2)) } | SIMPLEQUOTE qcon {% fmap ecpFromExp $ acsA (\cs -> sLL $1 (reLocN $>) $ HsBracket (EpAnn (glR $1) [mj AnnSimpleQuote $1] cs) (VarBr noExtField True $2)) } | TH_TY_QUOTE tyvar {% fmap ecpFromExp $ acsA (\cs -> sLL $1 (reLocN $>) $ HsBracket (EpAnn (glR $1) [mj AnnThTyQuote $1 ] cs) (VarBr noExtField False $2)) } | TH_TY_QUOTE gtycon {% fmap ecpFromExp $ acsA (\cs -> sLL $1 (reLocN $>) $ HsBracket (EpAnn (glR $1) [mj AnnThTyQuote $1 ] cs) (VarBr noExtField False $2)) } -- See Note [%shift: aexp2 -> TH_TY_QUOTE] | TH_TY_QUOTE %shift {% reportEmptyDoubleQuotes (getLoc $1) } | '[|' exp '|]' {% runPV (unECP $2) >>= \ $2 -> fmap ecpFromExp $ acsA (\cs -> sLL $1 $> $ HsBracket (EpAnn (glR $1) (if (hasE $1) then [mj AnnOpenE $1, mu AnnCloseQ $3] else [mu AnnOpenEQ $1,mu AnnCloseQ $3]) cs) (ExpBr noExtField $2)) } | '[||' exp '||]' {% runPV (unECP $2) >>= \ $2 -> fmap ecpFromExp $ acsA (\cs -> sLL $1 $> $ HsBracket (EpAnn (glR $1) (if (hasE $1) then [mj AnnOpenE $1,mc $3] else [mo $1,mc $3]) cs) (TExpBr noExtField $2)) } | '[t|' ktype '|]' {% fmap ecpFromExp $ acsA (\cs -> sLL $1 $> $ HsBracket (EpAnn (glR $1) [mo $1,mu AnnCloseQ $3] cs) (TypBr noExtField $2)) } | '[p|' infixexp '|]' {% (checkPattern <=< runPV) (unECP $2) >>= \p -> fmap ecpFromExp $ acsA (\cs -> sLL $1 $> $ HsBracket (EpAnn (glR $1) [mo $1,mu AnnCloseQ $3] cs) (PatBr noExtField p)) } | '[d|' cvtopbody '|]' {% fmap ecpFromExp $ acsA (\cs -> sLL $1 $> $ HsBracket (EpAnn (glR $1) (mo $1:mu AnnCloseQ $3:fst $2) cs) (DecBrL noExtField (snd $2))) } | quasiquote { ECP $ pvA $ mkHsSplicePV $1 } -- arrow notation extension | '(|' aexp cmdargs '|)' {% runPV (unECP $2) >>= \ $2 -> fmap ecpFromCmd $ acsA (\cs -> sLL $1 $> $ HsCmdArrForm (EpAnn (glR $1) (AnnList (Just $ glR $1) (Just $ mu AnnOpenB $1) (Just $ mu AnnCloseB $4) [] []) cs) $2 Prefix Nothing (reverse $3)) } projection :: { Located [Located (HsFieldLabel GhcPs)] } projection -- See Note [Whitespace-sensitive operator parsing] in GHC.Parsing.Lexer : projection TIGHT_INFIX_PROJ field {% acs (\cs -> sLL $1 $> ((sLL $2 $> $ HsFieldLabel (EpAnn (glR $1) (AnnFieldLabel (Just $ glAA $2)) cs) $3) : unLoc $1)) } | PREFIX_PROJ field {% acs (\cs -> sLL $1 $> [sLL $1 $> $ HsFieldLabel (EpAnn (glR $1) (AnnFieldLabel (Just $ glAA $1)) cs) $2]) } splice_exp :: { LHsExpr GhcPs } : splice_untyped { mapLoc (HsSpliceE noAnn) (reLocA $1) } | splice_typed { mapLoc (HsSpliceE noAnn) (reLocA $1) } splice_untyped :: { Located (HsSplice GhcPs) } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer : PREFIX_DOLLAR aexp2 {% runPV (unECP $2) >>= \ $2 -> acs (\cs -> sLLlA $1 $> $ mkUntypedSplice (EpAnn (glR $1) [mj AnnDollar $1] cs) DollarSplice $2) } splice_typed :: { Located (HsSplice GhcPs) } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer : PREFIX_DOLLAR_DOLLAR aexp2 {% runPV (unECP $2) >>= \ $2 -> acs (\cs -> sLLlA $1 $> $ mkTypedSplice (EpAnn (glR $1) [mj AnnDollarDollar $1] cs) DollarSplice $2) } cmdargs :: { [LHsCmdTop GhcPs] } : cmdargs acmd { $2 : $1 } | {- empty -} { [] } acmd :: { LHsCmdTop GhcPs } : aexp {% runPV (unECP $1) >>= \ (cmd :: LHsCmd GhcPs) -> runPV (checkCmdBlockArguments cmd) >>= \ _ -> return (sL1A cmd $ HsCmdTop noExtField cmd) } cvtopbody :: { ([AddEpAnn],[LHsDecl GhcPs]) } : '{' cvtopdecls0 '}' { ([mj AnnOpenC $1 ,mj AnnCloseC $3],$2) } | vocurly cvtopdecls0 close { ([],$2) } cvtopdecls0 :: { [LHsDecl GhcPs] } : topdecls_semi { cvTopDecls $1 } | topdecls { cvTopDecls $1 } ----------------------------------------------------------------------------- -- Tuple expressions -- "texp" is short for tuple expressions: -- things that can appear unparenthesized as long as they're -- inside parens or delimited by commas texp :: { ECP } : exp { $1 } -- Note [Parsing sections] -- ~~~~~~~~~~~~~~~~~~~~~~~ -- We include left and right sections here, which isn't -- technically right according to the Haskell standard. -- For example (3 +, True) isn't legal. -- However, we want to parse bang patterns like -- (!x, !y) -- and it's convenient to do so here as a section -- Then when converting expr to pattern we unravel it again -- Meanwhile, the renamer checks that real sections appear -- inside parens. | infixexp qop {% runPV (unECP $1) >>= \ $1 -> runPV (rejectPragmaPV $1) >> runPV $2 >>= \ $2 -> return $ ecpFromExp $ reLocA $ sLL (reLoc $1) (reLocN $>) $ SectionL noAnn $1 (n2l $2) } | qopm infixexp { ECP $ superInfixOp $ unECP $2 >>= \ $2 -> $1 >>= \ $1 -> pvA $ mkHsSectionR_PV (comb2 (reLocN $1) (reLoc $>)) (n2l $1) $2 } -- View patterns get parenthesized above | exp '->' texp { ECP $ unECP $1 >>= \ $1 -> unECP $3 >>= \ $3 -> mkHsViewPatPV (comb2 (reLoc $1) (reLoc $>)) $1 $3 [mu AnnRarrow $2] } -- Always at least one comma or bar. -- Though this can parse just commas (without any expressions), it won't -- in practice, because (,,,) is parsed as a name. See Note [ExplicitTuple] -- in GHC.Hs.Expr. tup_exprs :: { forall b. DisambECP b => PV (SumOrTuple b) } : texp commas_tup_tail { unECP $1 >>= \ $1 -> $2 >>= \ $2 -> do { t <- amsA $1 [AddCommaAnn (EpaSpan $ rs $ fst $2)] ; return (Tuple (Right t : snd $2)) } } | commas tup_tail { $2 >>= \ $2 -> do { let {cos = map (\ll -> (Left (EpAnn (anc $ rs ll) (EpaSpan $ rs ll) emptyComments))) (fst $1) } ; return (Tuple (cos ++ $2)) } } | texp bars { unECP $1 >>= \ $1 -> return $ (Sum 1 (snd $2 + 1) $1 [] (fst $2)) } | bars texp bars0 { unECP $2 >>= \ $2 -> return $ (Sum (snd $1 + 1) (snd $1 + snd $3 + 1) $2 (fst $1) (fst $3)) } -- Always starts with commas; always follows an expr commas_tup_tail :: { forall b. DisambECP b => PV (SrcSpan,[Either (EpAnn EpaLocation) (LocatedA b)]) } commas_tup_tail : commas tup_tail { $2 >>= \ $2 -> do { let {cos = map (\l -> (Left (EpAnn (anc $ rs l) (EpaSpan $ rs l) emptyComments))) (tail $ fst $1) } ; return ((head $ fst $1, cos ++ $2)) } } -- Always follows a comma tup_tail :: { forall b. DisambECP b => PV [Either (EpAnn EpaLocation) (LocatedA b)] } : texp commas_tup_tail { unECP $1 >>= \ $1 -> $2 >>= \ $2 -> do { t <- amsA $1 [AddCommaAnn (EpaSpan $ rs $ fst $2)] ; return (Right t : snd $2) } } | texp { unECP $1 >>= \ $1 -> return [Right $1] } -- See Note [%shift: tup_tail -> {- empty -}] | {- empty -} %shift { return [Left noAnn] } ----------------------------------------------------------------------------- -- List expressions -- The rules below are little bit contorted to keep lexps left-recursive while -- avoiding another shift/reduce-conflict. -- Never empty. list :: { forall b. DisambECP b => SrcSpan -> (AddEpAnn, AddEpAnn) -> PV (LocatedA b) } : texp { \loc (ao,ac) -> unECP $1 >>= \ $1 -> mkHsExplicitListPV loc [$1] (AnnList Nothing (Just ao) (Just ac) [] []) } | lexps { \loc (ao,ac) -> $1 >>= \ $1 -> mkHsExplicitListPV loc (reverse $1) (AnnList Nothing (Just ao) (Just ac) [] []) } | texp '..' { \loc (ao,ac) -> unECP $1 >>= \ $1 -> acsA (\cs -> L loc $ ArithSeq (EpAnn (spanAsAnchor loc) [ao,mj AnnDotdot $2,ac] cs) Nothing (From $1)) >>= ecpFromExp' } | texp ',' exp '..' { \loc (ao,ac) -> unECP $1 >>= \ $1 -> unECP $3 >>= \ $3 -> acsA (\cs -> L loc $ ArithSeq (EpAnn (spanAsAnchor loc) [ao,mj AnnComma $2,mj AnnDotdot $4,ac] cs) Nothing (FromThen $1 $3)) >>= ecpFromExp' } | texp '..' exp { \loc (ao,ac) -> unECP $1 >>= \ $1 -> unECP $3 >>= \ $3 -> acsA (\cs -> L loc $ ArithSeq (EpAnn (spanAsAnchor loc) [ao,mj AnnDotdot $2,ac] cs) Nothing (FromTo $1 $3)) >>= ecpFromExp' } | texp ',' exp '..' exp { \loc (ao,ac) -> unECP $1 >>= \ $1 -> unECP $3 >>= \ $3 -> unECP $5 >>= \ $5 -> acsA (\cs -> L loc $ ArithSeq (EpAnn (spanAsAnchor loc) [ao,mj AnnComma $2,mj AnnDotdot $4,ac] cs) Nothing (FromThenTo $1 $3 $5)) >>= ecpFromExp' } | texp '|' flattenedpquals { \loc (ao,ac) -> checkMonadComp >>= \ ctxt -> unECP $1 >>= \ $1 -> do { t <- addTrailingVbarA $1 (gl $2) ; acsA (\cs -> L loc $ mkHsCompAnns ctxt (unLoc $3) t (EpAnn (spanAsAnchor loc) (AnnList Nothing (Just ao) (Just ac) [] []) cs)) >>= ecpFromExp' } } lexps :: { forall b. DisambECP b => PV [LocatedA b] } : lexps ',' texp { $1 >>= \ $1 -> unECP $3 >>= \ $3 -> case $1 of (h:t) -> do h' <- addTrailingCommaA h (gl $2) return (((:) $! $3) $! (h':t)) } | texp ',' texp { unECP $1 >>= \ $1 -> unECP $3 >>= \ $3 -> do { h <- addTrailingCommaA $1 (gl $2) ; return [$3,h] }} ----------------------------------------------------------------------------- -- List Comprehensions flattenedpquals :: { Located [LStmt GhcPs (LHsExpr GhcPs)] } : pquals { case (unLoc $1) of [qs] -> sL1 $1 qs -- We just had one thing in our "parallel" list so -- we simply return that thing directly qss -> sL1 $1 [sL1a $1 $ ParStmt noExtField [ParStmtBlock noExtField qs [] noSyntaxExpr | qs <- qss] noExpr noSyntaxExpr] -- We actually found some actual parallel lists so -- we wrap them into as a ParStmt } pquals :: { Located [[LStmt GhcPs (LHsExpr GhcPs)]] } : squals '|' pquals {% case unLoc $1 of (h:t) -> do h' <- addTrailingVbarA h (gl $2) return (sLL $1 $> (reverse (h':t) : unLoc $3)) } | squals { L (getLoc $1) [reverse (unLoc $1)] } squals :: { Located [LStmt GhcPs (LHsExpr GhcPs)] } -- In reverse order, because the last -- one can "grab" the earlier ones : squals ',' transformqual {% case unLoc $1 of (h:t) -> do h' <- addTrailingCommaA h (gl $2) return (sLL $1 $> [sLLa $1 $> ((unLoc $3) (glRR $1) (reverse (h':t)))]) } | squals ',' qual {% runPV $3 >>= \ $3 -> case unLoc $1 of (h:t) -> do h' <- addTrailingCommaA h (gl $2) return (sLL $1 (reLoc $>) ($3 : (h':t))) } | transformqual {% return (sLL $1 $> [L (getLocAnn $1) ((unLoc $1) (glRR $1) [])]) } | qual {% runPV $1 >>= \ $1 -> return $ sL1A $1 [$1] } -- | transformquals1 ',' '{|' pquals '|}' { sLL $1 $> ($4 : unLoc $1) } -- | '{|' pquals '|}' { sL1 $1 [$2] } -- It is possible to enable bracketing (associating) qualifier lists -- by uncommenting the lines with {| |} above. Due to a lack of -- consensus on the syntax, this feature is not being used until we -- get user demand. transformqual :: { Located (RealSrcSpan -> [LStmt GhcPs (LHsExpr GhcPs)] -> Stmt GhcPs (LHsExpr GhcPs)) } -- Function is applied to a list of stmts *in order* : 'then' exp {% runPV (unECP $2) >>= \ $2 -> acs (\cs-> sLLlA $1 $> (\r ss -> (mkTransformStmt (EpAnn (anc r) [mj AnnThen $1] cs) ss $2))) } | 'then' exp 'by' exp {% runPV (unECP $2) >>= \ $2 -> runPV (unECP $4) >>= \ $4 -> acs (\cs -> sLLlA $1 $> ( \r ss -> (mkTransformByStmt (EpAnn (anc r) [mj AnnThen $1,mj AnnBy $3] cs) ss $2 $4))) } | 'then' 'group' 'using' exp {% runPV (unECP $4) >>= \ $4 -> acs (\cs -> sLLlA $1 $> ( \r ss -> (mkGroupUsingStmt (EpAnn (anc r) [mj AnnThen $1,mj AnnGroup $2,mj AnnUsing $3] cs) ss $4))) } | 'then' 'group' 'by' exp 'using' exp {% runPV (unECP $4) >>= \ $4 -> runPV (unECP $6) >>= \ $6 -> acs (\cs -> sLLlA $1 $> ( \r ss -> (mkGroupByUsingStmt (EpAnn (anc r) [mj AnnThen $1,mj AnnGroup $2,mj AnnBy $3,mj AnnUsing $5] cs) ss $4 $6))) } -- Note that 'group' is a special_id, which means that you can enable -- TransformListComp while still using Data.List.group. However, this -- introduces a shift/reduce conflict. Happy chooses to resolve the conflict -- in by choosing the "group by" variant, which is what we want. ----------------------------------------------------------------------------- -- Guards guardquals :: { Located [LStmt GhcPs (LHsExpr GhcPs)] } : guardquals1 { L (getLoc $1) (reverse (unLoc $1)) } guardquals1 :: { Located [LStmt GhcPs (LHsExpr GhcPs)] } : guardquals1 ',' qual {% runPV $3 >>= \ $3 -> case unLoc $1 of (h:t) -> do h' <- addTrailingCommaA h (gl $2) return (sLL $1 (reLoc $>) ($3 : (h':t))) } | qual {% runPV $1 >>= \ $1 -> return $ sL1A $1 [$1] } ----------------------------------------------------------------------------- -- Case alternatives altslist :: { forall b. DisambECP b => PV (LocatedL [LMatch GhcPs (LocatedA b)]) } : '{' alts '}' { $2 >>= \ $2 -> amsrl (sLL $1 $> (reverse (snd $ unLoc $2))) (AnnList (Just $ glR $2) (Just $ moc $1) (Just $ mcc $3) (fst $ unLoc $2) []) } | vocurly alts close { $2 >>= \ $2 -> amsrl (L (getLoc $2) (reverse (snd $ unLoc $2))) (AnnList (Just $ glR $2) Nothing Nothing (fst $ unLoc $2) []) } | '{' '}' { amsrl (sLL $1 $> []) (AnnList Nothing (Just $ moc $1) (Just $ mcc $2) [] []) } | vocurly close { return $ noLocA [] } alts :: { forall b. DisambECP b => PV (Located ([AddEpAnn],[LMatch GhcPs (LocatedA b)])) } : alts1 { $1 >>= \ $1 -> return $ sL1 $1 (fst $ unLoc $1,snd $ unLoc $1) } | ';' alts { $2 >>= \ $2 -> return $ sLL $1 $> (((mz AnnSemi $1) ++ (fst $ unLoc $2)) ,snd $ unLoc $2) } alts1 :: { forall b. DisambECP b => PV (Located ([AddEpAnn],[LMatch GhcPs (LocatedA b)])) } : alts1 ';' alt { $1 >>= \ $1 -> $3 >>= \ $3 -> case snd $ unLoc $1 of [] -> return (sLL $1 (reLoc $>) ((mz AnnSemi $2) ++(fst $ unLoc $1) ,[$3])) (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (sLL $1 (reLoc $>) (fst $ unLoc $1,$3 : h' : t)) } | alts1 ';' { $1 >>= \ $1 -> case snd $ unLoc $1 of [] -> return (sLL $1 $> ((mz AnnSemi $2) ++(fst $ unLoc $1) ,[])) (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (sLL $1 $> (fst $ unLoc $1, h' : t)) } | alt { $1 >>= \ $1 -> return $ sL1 (reLoc $1) ([],[$1]) } alt :: { forall b. DisambECP b => PV (LMatch GhcPs (LocatedA b)) } : pat alt_rhs { $2 >>= \ $2 -> acsA (\cs -> sLL (reLoc $1) $> (Match { m_ext = (EpAnn (glAR $1) [] cs) , m_ctxt = CaseAlt , m_pats = [$1] , m_grhss = unLoc $2 }))} alt_rhs :: { forall b. DisambECP b => PV (Located (GRHSs GhcPs (LocatedA b))) } : ralt wherebinds { $1 >>= \alt -> return $ sLL alt (adaptWhereBinds $>) (GRHSs noExtField (unLoc alt) (unLoc $ adaptWhereBinds $2)) } ralt :: { forall b. DisambECP b => PV (Located [LGRHS GhcPs (LocatedA b)]) } : '->' exp { unECP $2 >>= \ $2 -> acs (\cs -> sLLlA $1 $> (unguardedRHS (EpAnn (glR $1) (GrhsAnn Nothing (mu AnnRarrow $1)) cs) (comb2 $1 (reLoc $2)) $2)) } | gdpats { $1 >>= \gdpats -> return $ sL1 gdpats (reverse (unLoc gdpats)) } gdpats :: { forall b. DisambECP b => PV (Located [LGRHS GhcPs (LocatedA b)]) } : gdpats gdpat { $1 >>= \gdpats -> $2 >>= \gdpat -> return $ sLL gdpats gdpat (gdpat : unLoc gdpats) } | gdpat { $1 >>= \gdpat -> return $ sL1 gdpat [gdpat] } -- layout for MultiWayIf doesn't begin with an open brace, because it's hard to -- generate the open brace in addition to the vertical bar in the lexer, and -- we don't need it. ifgdpats :: { Located ([AddEpAnn],[LGRHS GhcPs (LHsExpr GhcPs)]) } : '{' gdpats '}' {% runPV $2 >>= \ $2 -> return $ sLL $1 $> ([moc $1,mcc $3],unLoc $2) } | gdpats close {% runPV $1 >>= \ $1 -> return $ sL1 $1 ([],unLoc $1) } gdpat :: { forall b. DisambECP b => PV (LGRHS GhcPs (LocatedA b)) } : '|' guardquals '->' exp { unECP $4 >>= \ $4 -> acs (\cs -> sL (comb2A $1 $>) $ GRHS (EpAnn (glR $1) (GrhsAnn (Just $ glAA $1) (mu AnnRarrow $3)) cs) (unLoc $2) $4) } -- 'pat' recognises a pattern, including one with a bang at the top -- e.g. "!x" or "!(x,y)" or "C a b" etc -- Bangs inside are parsed as infix operator applications, so that -- we parse them right when bang-patterns are off pat :: { LPat GhcPs } pat : exp {% (checkPattern <=< runPV) (unECP $1) } bindpat :: { LPat GhcPs } bindpat : exp {% -- See Note [Parser-Validator Hint] in GHC.Parser.PostProcess checkPattern_hints [SuggestMissingDo] (unECP $1) } apat :: { LPat GhcPs } apat : aexp {% (checkPattern <=< runPV) (unECP $1) } apats :: { [LPat GhcPs] } : apat apats { $1 : $2 } | {- empty -} { [] } ----------------------------------------------------------------------------- -- Statement sequences stmtlist :: { forall b. DisambECP b => PV (LocatedL [LocatedA (Stmt GhcPs (LocatedA b))]) } : '{' stmts '}' { $2 >>= \ $2 -> amsrl (sLL $1 $> (reverse $ snd $ unLoc $2)) (AnnList (Just $ glR $2) (Just $ moc $1) (Just $ mcc $3) [] (fst $ unLoc $2)) } -- AZ:performance of reverse? | vocurly stmts close { $2 >>= \ $2 -> amsrl (L (gl $2) (reverse $ snd $ unLoc $2)) (AnnList (Just $ glR $2) Nothing Nothing [] (fst $ unLoc $2)) } -- do { ;; s ; s ; ; s ;; } -- The last Stmt should be an expression, but that's hard to enforce -- here, because we need too much lookahead if we see do { e ; } -- So we use BodyStmts throughout, and switch the last one over -- in ParseUtils.checkDo instead stmts :: { forall b. DisambECP b => PV (Located ([TrailingAnn],[LStmt GhcPs (LocatedA b)])) } : stmts ';' stmt { $1 >>= \ $1 -> $3 >>= \ ($3 :: LStmt GhcPs (LocatedA b)) -> case (snd $ unLoc $1) of [] -> return (sLL $1 (reLoc $>) ((msemi $2) ++ (fst $ unLoc $1) ,$3 : (snd $ unLoc $1))) (h:t) -> do { h' <- addTrailingSemiA h (gl $2) ; return $ sLL $1 (reLoc $>) (fst $ unLoc $1,$3 :(h':t)) }} | stmts ';' { $1 >>= \ $1 -> case (snd $ unLoc $1) of [] -> return (sLL $1 $> ((msemi $2) ++ (fst $ unLoc $1),snd $ unLoc $1)) (h:t) -> do { h' <- addTrailingSemiA h (gl $2) ; return $ sL1 $1 (fst $ unLoc $1,h':t) }} | stmt { $1 >>= \ $1 -> return $ sL1A $1 ([],[$1]) } | {- empty -} { return $ noLoc ([],[]) } -- For typing stmts at the GHCi prompt, where -- the input may consist of just comments. maybe_stmt :: { Maybe (LStmt GhcPs (LHsExpr GhcPs)) } : stmt {% fmap Just (runPV $1) } | {- nothing -} { Nothing } -- For GHC API. e_stmt :: { LStmt GhcPs (LHsExpr GhcPs) } : stmt {% runPV $1 } stmt :: { forall b. DisambECP b => PV (LStmt GhcPs (LocatedA b)) } : qual { $1 } | 'rec' stmtlist { $2 >>= \ $2 -> acsA (\cs -> (sLL $1 (reLoc $>) $ mkRecStmt (EpAnn (glR $1) (hsDoAnn $1 $2 AnnRec) cs) $2)) } qual :: { forall b. DisambECP b => PV (LStmt GhcPs (LocatedA b)) } : bindpat '<-' exp { unECP $3 >>= \ $3 -> acsA (\cs -> sLLlA (reLoc $1) $> $ mkPsBindStmt (EpAnn (glAR $1) [mu AnnLarrow $2] cs) $1 $3) } | exp { unECP $1 >>= \ $1 -> return $ sL1 $1 $ mkBodyStmt $1 } | 'let' binds { acsA (\cs -> (sLL $1 $> $ mkLetStmt (EpAnn (glR $1) [mj AnnLet $1] cs) (unLoc $2))) } ----------------------------------------------------------------------------- -- Record Field Update/Construction fbinds :: { forall b. DisambECP b => PV ([Fbind b], Maybe SrcSpan) } : fbinds1 { $1 } | {- empty -} { return ([], Nothing) } fbinds1 :: { forall b. DisambECP b => PV ([Fbind b], Maybe SrcSpan) } : fbind ',' fbinds1 { $1 >>= \ $1 -> $3 >>= \ $3 -> do h <- addTrailingCommaFBind $1 (gl $2) return (case $3 of (flds, dd) -> (h : flds, dd)) } | fbind { $1 >>= \ $1 -> return ([$1], Nothing) } | '..' { return ([], Just (getLoc $1)) } fbind :: { forall b. DisambECP b => PV (Fbind b) } : qvar '=' texp { unECP $3 >>= \ $3 -> fmap Left $ acsA (\cs -> sLL (reLocN $1) (reLoc $>) $ HsRecField (EpAnn (glNR $1) [mj AnnEqual $2] cs) (sL1N $1 $ mkFieldOcc $1) $3 False) } -- RHS is a 'texp', allowing view patterns (#6038) -- and, incidentally, sections. Eg -- f (R { x = show -> s }) = ... | qvar { placeHolderPunRhs >>= \rhs -> fmap Left $ acsa (\cs -> sL1a (reLocN $1) $ HsRecField (EpAnn (glNR $1) [] cs) (sL1N $1 $ mkFieldOcc $1) rhs True) } -- In the punning case, use a place-holder -- The renamer fills in the final value -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer -- AZ: need to pull out the let block into a helper | field TIGHT_INFIX_PROJ fieldToUpdate '=' texp { do let top = sL1 $1 $ HsFieldLabel noAnn $1 ((L lf (HsFieldLabel _ f)):t) = reverse (unLoc $3) lf' = comb2 $2 (L lf ()) fields = top : L lf' (HsFieldLabel (EpAnn (spanAsAnchor lf') (AnnFieldLabel (Just $ glAA $2)) emptyComments) f) : t final = last fields l = comb2 $1 $3 isPun = False $5 <- unECP $5 fmap Right $ mkHsProjUpdatePV (comb2 $1 (reLoc $5)) (L l fields) $5 isPun [mj AnnEqual $4] } -- See Note [Whitespace-sensitive operator parsing] in GHC.Parser.Lexer -- AZ: need to pull out the let block into a helper | field TIGHT_INFIX_PROJ fieldToUpdate { do let top = sL1 $1 $ HsFieldLabel noAnn $1 ((L lf (HsFieldLabel _ f)):t) = reverse (unLoc $3) lf' = comb2 $2 (L lf ()) fields = top : L lf' (HsFieldLabel (EpAnn (spanAsAnchor lf') (AnnFieldLabel (Just $ glAA $2)) emptyComments) f) : t final = last fields l = comb2 $1 $3 isPun = True var <- mkHsVarPV (L (noAnnSrcSpan $ getLoc final) (mkRdrUnqual . mkVarOcc . unpackFS . unLoc . hflLabel . unLoc $ final)) fmap Right $ mkHsProjUpdatePV l (L l fields) var isPun [] } fieldToUpdate :: { Located [Located (HsFieldLabel GhcPs)] } fieldToUpdate -- See Note [Whitespace-sensitive operator parsing] in Lexer.x : fieldToUpdate TIGHT_INFIX_PROJ field {% getCommentsFor (getLoc $3) >>= \cs -> return (sLL $1 $> ((sLL $2 $> (HsFieldLabel (EpAnn (glR $2) (AnnFieldLabel $ Just $ glAA $2) cs) $3)) : unLoc $1)) } | field {% getCommentsFor (getLoc $1) >>= \cs -> return (sL1 $1 [sL1 $1 (HsFieldLabel (EpAnn (glR $1) (AnnFieldLabel Nothing) cs) $1)]) } ----------------------------------------------------------------------------- -- Implicit Parameter Bindings dbinds :: { Located [LIPBind GhcPs] } -- reversed : dbinds ';' dbind {% case unLoc $1 of (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (let { this = $3; rest = h':t } in rest `seq` this `seq` sLL $1 (reLoc $>) (this : rest)) } | dbinds ';' {% case unLoc $1 of (h:t) -> do h' <- addTrailingSemiA h (gl $2) return (sLL $1 $> (h':t)) } | dbind { let this = $1 in this `seq` (sL1 (reLoc $1) [this]) } -- | {- empty -} { [] } dbind :: { LIPBind GhcPs } dbind : ipvar '=' exp {% runPV (unECP $3) >>= \ $3 -> acsA (\cs -> sLLlA $1 $> (IPBind (EpAnn (glR $1) [mj AnnEqual $2] cs) (Left $1) $3)) } ipvar :: { Located HsIPName } : IPDUPVARID { sL1 $1 (HsIPName (getIPDUPVARID $1)) } ----------------------------------------------------------------------------- -- Overloaded labels overloaded_label :: { Located FastString } : LABELVARID { sL1 $1 (getLABELVARID $1) } ----------------------------------------------------------------------------- -- Warnings and deprecations name_boolformula_opt :: { LBooleanFormula (LocatedN RdrName) } : name_boolformula { $1 } | {- empty -} { noLocA mkTrue } name_boolformula :: { LBooleanFormula (LocatedN RdrName) } : name_boolformula_and { $1 } | name_boolformula_and '|' name_boolformula {% do { h <- addTrailingVbarL $1 (gl $2) ; return (reLocA $ sLLAA $1 $> (Or [h,$3])) } } name_boolformula_and :: { LBooleanFormula (LocatedN RdrName) } : name_boolformula_and_list { reLocA $ sLLAA (head $1) (last $1) (And ($1)) } name_boolformula_and_list :: { [LBooleanFormula (LocatedN RdrName)] } : name_boolformula_atom { [$1] } | name_boolformula_atom ',' name_boolformula_and_list {% do { h <- addTrailingCommaL $1 (gl $2) ; return (h : $3) } } name_boolformula_atom :: { LBooleanFormula (LocatedN RdrName) } : '(' name_boolformula ')' {% amsrl (sLL $1 $> (Parens $2)) (AnnList Nothing (Just (mop $1)) (Just (mcp $3)) [] []) } | name_var { reLocA $ sL1N $1 (Var $1) } namelist :: { Located [LocatedN RdrName] } namelist : name_var { sL1N $1 [$1] } | name_var ',' namelist {% do { h <- addTrailingCommaN $1 (gl $2) ; return (sLL (reLocN $1) $> (h : unLoc $3)) }} name_var :: { LocatedN RdrName } name_var : var { $1 } | con { $1 } ----------------------------------------- -- Data constructors -- There are two different productions here as lifted list constructors -- are parsed differently. qcon_nowiredlist :: { LocatedN RdrName } : gen_qcon { $1 } | sysdcon_nolist { L (getLoc $1) $ nameRdrName (dataConName (unLoc $1)) } qcon :: { LocatedN RdrName } : gen_qcon { $1} | sysdcon { L (getLoc $1) $ nameRdrName (dataConName (unLoc $1)) } gen_qcon :: { LocatedN RdrName } : qconid { $1 } | '(' qconsym ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } con :: { LocatedN RdrName } : conid { $1 } | '(' consym ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } | sysdcon { L (getLoc $1) $ nameRdrName (dataConName (unLoc $1)) } con_list :: { Located [LocatedN RdrName] } con_list : con { sL1N $1 [$1] } | con ',' con_list {% do { h <- addTrailingCommaN $1 (gl $2) ; return (sLL (reLocN $1) $> (h : unLoc $3)) }} -- See Note [ExplicitTuple] in GHC.Hs.Expr sysdcon_nolist :: { LocatedN DataCon } -- Wired in data constructors : '(' ')' {% amsrn (sLL $1 $> unitDataCon) (NameAnnOnly NameParens (glAA $1) (glAA $2) []) } | '(' commas ')' {% amsrn (sLL $1 $> $ tupleDataCon Boxed (snd $2 + 1)) (NameAnnCommas NameParens (glAA $1) (map (EpaSpan . realSrcSpan) (fst $2)) (glAA $3) []) } | '(#' '#)' {% amsrn (sLL $1 $> $ unboxedUnitDataCon) (NameAnnOnly NameParensHash (glAA $1) (glAA $2) []) } | '(#' commas '#)' {% amsrn (sLL $1 $> $ tupleDataCon Unboxed (snd $2 + 1)) (NameAnnCommas NameParensHash (glAA $1) (map (EpaSpan . realSrcSpan) (fst $2)) (glAA $3) []) } -- See Note [Empty lists] in GHC.Hs.Expr sysdcon :: { LocatedN DataCon } : sysdcon_nolist { $1 } | '[' ']' {% amsrn (sLL $1 $> nilDataCon) (NameAnnOnly NameSquare (glAA $1) (glAA $2) []) } conop :: { LocatedN RdrName } : consym { $1 } | '`' conid '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } qconop :: { LocatedN RdrName } : qconsym { $1 } | '`' qconid '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } ---------------------------------------------------------------------------- -- Type constructors -- See Note [Unit tuples] in GHC.Hs.Type for the distinction -- between gtycon and ntgtycon gtycon :: { LocatedN RdrName } -- A "general" qualified tycon, including unit tuples : ntgtycon { $1 } | '(' ')' {% amsrn (sLL $1 $> $ getRdrName unitTyCon) (NameAnnOnly NameParens (glAA $1) (glAA $2) []) } | '(#' '#)' {% amsrn (sLL $1 $> $ getRdrName unboxedUnitTyCon) (NameAnnOnly NameParensHash (glAA $1) (glAA $2) []) } ntgtycon :: { LocatedN RdrName } -- A "general" qualified tycon, excluding unit tuples : oqtycon { $1 } | '(' commas ')' {% amsrn (sLL $1 $> $ getRdrName (tupleTyCon Boxed (snd $2 + 1))) (NameAnnCommas NameParens (glAA $1) (map (EpaSpan . realSrcSpan) (fst $2)) (glAA $3) []) } | '(#' commas '#)' {% amsrn (sLL $1 $> $ getRdrName (tupleTyCon Unboxed (snd $2 + 1))) (NameAnnCommas NameParensHash (glAA $1) (map (EpaSpan . realSrcSpan) (fst $2)) (glAA $3) []) } | '(' '->' ')' {% amsrn (sLL $1 $> $ getRdrName unrestrictedFunTyCon) (NameAnn NameParens (glAA $1) (glAA $2) (glAA $3) []) } | '[' ']' {% amsrn (sLL $1 $> $ listTyCon_RDR) (NameAnnOnly NameSquare (glAA $1) (glAA $2) []) } oqtycon :: { LocatedN RdrName } -- An "ordinary" qualified tycon; -- These can appear in export lists : qtycon { $1 } | '(' qtyconsym ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } oqtycon_no_varcon :: { LocatedN RdrName } -- Type constructor which cannot be mistaken -- for variable constructor in export lists -- see Note [Type constructors in export list] : qtycon { $1 } | '(' QCONSYM ')' {% let { name :: Located RdrName ; name = sL1 $2 $! mkQual tcClsName (getQCONSYM $2) } in amsrn (sLL $1 $> (unLoc name)) (NameAnn NameParens (glAA $1) (glAA $2) (glAA $3) []) } | '(' CONSYM ')' {% let { name :: Located RdrName ; name = sL1 $2 $! mkUnqual tcClsName (getCONSYM $2) } in amsrn (sLL $1 $> (unLoc name)) (NameAnn NameParens (glAA $1) (glAA $2) (glAA $3) []) } | '(' ':' ')' {% let { name :: Located RdrName ; name = sL1 $2 $! consDataCon_RDR } in amsrn (sLL $1 $> (unLoc name)) (NameAnn NameParens (glAA $1) (glAA $2) (glAA $3) []) } {- Note [Type constructors in export list] ~~~~~~~~~~~~~~~~~~~~~ Mixing type constructors and data constructors in export lists introduces ambiguity in grammar: e.g. (*) may be both a type constructor and a function. -XExplicitNamespaces allows to disambiguate by explicitly prefixing type constructors with 'type' keyword. This ambiguity causes reduce/reduce conflicts in parser, which are always resolved in favour of data constructors. To get rid of conflicts we demand that ambiguous type constructors (those, which are formed by the same productions as variable constructors) are always prefixed with 'type' keyword. Unambiguous type constructors may occur both with or without 'type' keyword. Note that in the parser we still parse data constructors as type constructors. As such, they still end up in the type constructor namespace until after renaming when we resolve the proper namespace for each exported child. -} qtyconop :: { LocatedN RdrName } -- Qualified or unqualified -- See Note [%shift: qtyconop -> qtyconsym] : qtyconsym %shift { $1 } | '`' qtycon '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } qtycon :: { LocatedN RdrName } -- Qualified or unqualified : QCONID { sL1n $1 $! mkQual tcClsName (getQCONID $1) } | tycon { $1 } tycon :: { LocatedN RdrName } -- Unqualified : CONID { sL1n $1 $! mkUnqual tcClsName (getCONID $1) } qtyconsym :: { LocatedN RdrName } : QCONSYM { sL1n $1 $! mkQual tcClsName (getQCONSYM $1) } | QVARSYM { sL1n $1 $! mkQual tcClsName (getQVARSYM $1) } | tyconsym { $1 } tyconsym :: { LocatedN RdrName } : CONSYM { sL1n $1 $! mkUnqual tcClsName (getCONSYM $1) } | VARSYM { sL1n $1 $! -- See Note [eqTyCon (~) is built-in syntax] in GHC.Builtin.Types if getVARSYM $1 == fsLit "~" then eqTyCon_RDR else mkUnqual tcClsName (getVARSYM $1) } | ':' { sL1n $1 $! consDataCon_RDR } | '-' { sL1n $1 $! mkUnqual tcClsName (fsLit "-") } | '.' { sL1n $1 $! mkUnqual tcClsName (fsLit ".") } -- An "ordinary" unqualified tycon. See `oqtycon` for the qualified version. -- These can appear in `ANN type` declarations (#19374). otycon :: { LocatedN RdrName } : tycon { $1 } | '(' tyconsym ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } ----------------------------------------------------------------------------- -- Operators op :: { LocatedN RdrName } -- used in infix decls : varop { $1 } | conop { $1 } | '->' { sL1n $1 $ getRdrName unrestrictedFunTyCon } varop :: { LocatedN RdrName } : varsym { $1 } | '`' varid '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } qop :: { forall b. DisambInfixOp b => PV (LocatedN b) } -- used in sections : qvarop { mkHsVarOpPV $1 } | qconop { mkHsConOpPV $1 } | hole_op { pvN $1 } qopm :: { forall b. DisambInfixOp b => PV (LocatedN b) } -- used in sections : qvaropm { mkHsVarOpPV $1 } | qconop { mkHsConOpPV $1 } | hole_op { pvN $1 } hole_op :: { forall b. DisambInfixOp b => PV (Located b) } -- used in sections hole_op : '`' '_' '`' { mkHsInfixHolePV (comb2 $1 $>) (\cs -> EpAnn (glR $1) (EpAnnUnboundVar (glAA $1, glAA $3) (glAA $2)) cs) } qvarop :: { LocatedN RdrName } : qvarsym { $1 } | '`' qvarid '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } qvaropm :: { LocatedN RdrName } : qvarsym_no_minus { $1 } | '`' qvarid '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } ----------------------------------------------------------------------------- -- Type variables tyvar :: { LocatedN RdrName } tyvar : tyvarid { $1 } tyvarop :: { LocatedN RdrName } tyvarop : '`' tyvarid '`' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameBackquotes (glAA $1) (glNRR $2) (glAA $3) []) } tyvarid :: { LocatedN RdrName } : VARID { sL1n $1 $! mkUnqual tvName (getVARID $1) } | special_id { sL1n $1 $! mkUnqual tvName (unLoc $1) } | 'unsafe' { sL1n $1 $! mkUnqual tvName (fsLit "unsafe") } | 'safe' { sL1n $1 $! mkUnqual tvName (fsLit "safe") } | 'interruptible' { sL1n $1 $! mkUnqual tvName (fsLit "interruptible") } -- If this changes relative to varid, update 'checkRuleTyVarBndrNames' -- in GHC.Parser.PostProcess -- See Note [Parsing explicit foralls in Rules] ----------------------------------------------------------------------------- -- Variables var :: { LocatedN RdrName } : varid { $1 } | '(' varsym ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } qvar :: { LocatedN RdrName } : qvarid { $1 } | '(' varsym ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } | '(' qvarsym1 ')' {% amsrn (sLL $1 $> (unLoc $2)) (NameAnn NameParens (glAA $1) (glNRR $2) (glAA $3) []) } -- We've inlined qvarsym here so that the decision about -- whether it's a qvar or a var can be postponed until -- *after* we see the close paren. field :: { Located FastString } : VARID { sL1 $1 $! getVARID $1 } qvarid :: { LocatedN RdrName } : varid { $1 } | QVARID { sL1n $1 $! mkQual varName (getQVARID $1) } -- Note that 'role' and 'family' get lexed separately regardless of -- the use of extensions. However, because they are listed here, -- this is OK and they can be used as normal varids. -- See Note [Lexing type pseudo-keywords] in GHC.Parser.Lexer varid :: { LocatedN RdrName } : VARID { sL1n $1 $! mkUnqual varName (getVARID $1) } | special_id { sL1n $1 $! mkUnqual varName (unLoc $1) } | 'unsafe' { sL1n $1 $! mkUnqual varName (fsLit "unsafe") } | 'safe' { sL1n $1 $! mkUnqual varName (fsLit "safe") } | 'interruptible' { sL1n $1 $! mkUnqual varName (fsLit "interruptible")} | 'forall' { sL1n $1 $! mkUnqual varName (fsLit "forall") } | 'family' { sL1n $1 $! mkUnqual varName (fsLit "family") } | 'role' { sL1n $1 $! mkUnqual varName (fsLit "role") } -- If this changes relative to tyvarid, update 'checkRuleTyVarBndrNames' -- in GHC.Parser.PostProcess -- See Note [Parsing explicit foralls in Rules] qvarsym :: { LocatedN RdrName } : varsym { $1 } | qvarsym1 { $1 } qvarsym_no_minus :: { LocatedN RdrName } : varsym_no_minus { $1 } | qvarsym1 { $1 } qvarsym1 :: { LocatedN RdrName } qvarsym1 : QVARSYM { sL1n $1 $ mkQual varName (getQVARSYM $1) } varsym :: { LocatedN RdrName } : varsym_no_minus { $1 } | '-' { sL1n $1 $ mkUnqual varName (fsLit "-") } varsym_no_minus :: { LocatedN RdrName } -- varsym not including '-' : VARSYM { sL1n $1 $ mkUnqual varName (getVARSYM $1) } | special_sym { sL1n $1 $ mkUnqual varName (unLoc $1) } -- These special_ids are treated as keywords in various places, -- but as ordinary ids elsewhere. 'special_id' collects all these -- except 'unsafe', 'interruptible', 'forall', 'family', 'role', 'stock', and -- 'anyclass', whose treatment differs depending on context special_id :: { Located FastString } special_id : 'as' { sL1 $1 (fsLit "as") } | 'qualified' { sL1 $1 (fsLit "qualified") } | 'hiding' { sL1 $1 (fsLit "hiding") } | 'export' { sL1 $1 (fsLit "export") } | 'label' { sL1 $1 (fsLit "label") } | 'dynamic' { sL1 $1 (fsLit "dynamic") } | 'stdcall' { sL1 $1 (fsLit "stdcall") } | 'ccall' { sL1 $1 (fsLit "ccall") } | 'capi' { sL1 $1 (fsLit "capi") } | 'prim' { sL1 $1 (fsLit "prim") } | 'javascript' { sL1 $1 (fsLit "javascript") } -- See Note [%shift: special_id -> 'group'] | 'group' %shift { sL1 $1 (fsLit "group") } | 'stock' { sL1 $1 (fsLit "stock") } | 'anyclass' { sL1 $1 (fsLit "anyclass") } | 'via' { sL1 $1 (fsLit "via") } | 'unit' { sL1 $1 (fsLit "unit") } | 'dependency' { sL1 $1 (fsLit "dependency") } | 'signature' { sL1 $1 (fsLit "signature") } special_sym :: { Located FastString } special_sym : '.' { sL1 $1 (fsLit ".") } | '*' { sL1 $1 (fsLit (starSym (isUnicode $1))) } ----------------------------------------------------------------------------- -- Data constructors qconid :: { LocatedN RdrName } -- Qualified or unqualified : conid { $1 } | QCONID { sL1n $1 $! mkQual dataName (getQCONID $1) } conid :: { LocatedN RdrName } : CONID { sL1n $1 $ mkUnqual dataName (getCONID $1) } qconsym :: { LocatedN RdrName } -- Qualified or unqualified : consym { $1 } | QCONSYM { sL1n $1 $ mkQual dataName (getQCONSYM $1) } consym :: { LocatedN RdrName } : CONSYM { sL1n $1 $ mkUnqual dataName (getCONSYM $1) } -- ':' means only list cons | ':' { sL1n $1 $ consDataCon_RDR } ----------------------------------------------------------------------------- -- Literals literal :: { Located (HsLit GhcPs) } : CHAR { sL1 $1 $ HsChar (getCHARs $1) $ getCHAR $1 } | STRING { sL1 $1 $ HsString (getSTRINGs $1) $ getSTRING $1 } | PRIMINTEGER { sL1 $1 $ HsIntPrim (getPRIMINTEGERs $1) $ getPRIMINTEGER $1 } | PRIMWORD { sL1 $1 $ HsWordPrim (getPRIMWORDs $1) $ getPRIMWORD $1 } | PRIMCHAR { sL1 $1 $ HsCharPrim (getPRIMCHARs $1) $ getPRIMCHAR $1 } | PRIMSTRING { sL1 $1 $ HsStringPrim (getPRIMSTRINGs $1) $ getPRIMSTRING $1 } | PRIMFLOAT { sL1 $1 $ HsFloatPrim noExtField $ getPRIMFLOAT $1 } | PRIMDOUBLE { sL1 $1 $ HsDoublePrim noExtField $ getPRIMDOUBLE $1 } ----------------------------------------------------------------------------- -- Layout close :: { () } : vccurly { () } -- context popped in lexer. | error {% popContext } ----------------------------------------------------------------------------- -- Miscellaneous (mostly renamings) modid :: { Located ModuleName } : CONID { sL1 $1 $ mkModuleNameFS (getCONID $1) } | QCONID { sL1 $1 $ let (mod,c) = getQCONID $1 in mkModuleNameFS (mkFastString (unpackFS mod ++ '.':unpackFS c)) } commas :: { ([SrcSpan],Int) } -- One or more commas : commas ',' { ((fst $1)++[gl $2],snd $1 + 1) } | ',' { ([gl $1],1) } bars0 :: { ([EpaLocation],Int) } -- Zero or more bars : bars { $1 } | { ([], 0) } bars :: { ([EpaLocation],Int) } -- One or more bars : bars '|' { ((fst $1)++[glAA $2],snd $1 + 1) } | '|' { ([glAA $1],1) } { happyError :: P a happyError = srcParseFail getVARID (L _ (ITvarid x)) = x getCONID (L _ (ITconid x)) = x getVARSYM (L _ (ITvarsym x)) = x getCONSYM (L _ (ITconsym x)) = x getDO (L _ (ITdo x)) = x getMDO (L _ (ITmdo x)) = x getQVARID (L _ (ITqvarid x)) = x getQCONID (L _ (ITqconid x)) = x getQVARSYM (L _ (ITqvarsym x)) = x getQCONSYM (L _ (ITqconsym x)) = x getIPDUPVARID (L _ (ITdupipvarid x)) = x getLABELVARID (L _ (ITlabelvarid x)) = x getCHAR (L _ (ITchar _ x)) = x getSTRING (L _ (ITstring _ x)) = x getINTEGER (L _ (ITinteger x)) = x getRATIONAL (L _ (ITrational x)) = x getPRIMCHAR (L _ (ITprimchar _ x)) = x getPRIMSTRING (L _ (ITprimstring _ x)) = x getPRIMINTEGER (L _ (ITprimint _ x)) = x getPRIMWORD (L _ (ITprimword _ x)) = x getPRIMFLOAT (L _ (ITprimfloat x)) = x getPRIMDOUBLE (L _ (ITprimdouble x)) = x getINLINE (L _ (ITinline_prag _ inl conl)) = (inl,conl) getSPEC_INLINE (L _ (ITspec_inline_prag _ True)) = (Inline, FunLike) getSPEC_INLINE (L _ (ITspec_inline_prag _ False)) = (NoInline,FunLike) getCOMPLETE_PRAGs (L _ (ITcomplete_prag x)) = x getVOCURLY (L (RealSrcSpan l _) ITvocurly) = srcSpanStartCol l getINTEGERs (L _ (ITinteger (IL src _ _))) = src getCHARs (L _ (ITchar src _)) = src getSTRINGs (L _ (ITstring src _)) = src getPRIMCHARs (L _ (ITprimchar src _)) = src getPRIMSTRINGs (L _ (ITprimstring src _)) = src getPRIMINTEGERs (L _ (ITprimint src _)) = src getPRIMWORDs (L _ (ITprimword src _)) = src -- See Note [Pragma source text] in "GHC.Types.Basic" for the following getINLINE_PRAGs (L _ (ITinline_prag src _ _)) = src getSPEC_PRAGs (L _ (ITspec_prag src)) = src getSPEC_INLINE_PRAGs (L _ (ITspec_inline_prag src _)) = src getSOURCE_PRAGs (L _ (ITsource_prag src)) = src getRULES_PRAGs (L _ (ITrules_prag src)) = src getWARNING_PRAGs (L _ (ITwarning_prag src)) = src getDEPRECATED_PRAGs (L _ (ITdeprecated_prag src)) = src getSCC_PRAGs (L _ (ITscc_prag src)) = src getUNPACK_PRAGs (L _ (ITunpack_prag src)) = src getNOUNPACK_PRAGs (L _ (ITnounpack_prag src)) = src getANN_PRAGs (L _ (ITann_prag src)) = src getMINIMAL_PRAGs (L _ (ITminimal_prag src)) = src getOVERLAPPABLE_PRAGs (L _ (IToverlappable_prag src)) = src getOVERLAPPING_PRAGs (L _ (IToverlapping_prag src)) = src getOVERLAPS_PRAGs (L _ (IToverlaps_prag src)) = src getINCOHERENT_PRAGs (L _ (ITincoherent_prag src)) = src getCTYPEs (L _ (ITctype src)) = src getStringLiteral l = StringLiteral (getSTRINGs l) (getSTRING l) Nothing isUnicode :: Located Token -> Bool isUnicode (L _ (ITforall iu)) = iu == UnicodeSyntax isUnicode (L _ (ITdarrow iu)) = iu == UnicodeSyntax isUnicode (L _ (ITdcolon iu)) = iu == UnicodeSyntax isUnicode (L _ (ITlarrow iu)) = iu == UnicodeSyntax isUnicode (L _ (ITrarrow iu)) = iu == UnicodeSyntax isUnicode (L _ (ITlarrowtail iu)) = iu == UnicodeSyntax isUnicode (L _ (ITrarrowtail iu)) = iu == UnicodeSyntax isUnicode (L _ (ITLarrowtail iu)) = iu == UnicodeSyntax isUnicode (L _ (ITRarrowtail iu)) = iu == UnicodeSyntax isUnicode (L _ (IToparenbar iu)) = iu == UnicodeSyntax isUnicode (L _ (ITcparenbar iu)) = iu == UnicodeSyntax isUnicode (L _ (ITopenExpQuote _ iu)) = iu == UnicodeSyntax isUnicode (L _ (ITcloseQuote iu)) = iu == UnicodeSyntax isUnicode (L _ (ITstar iu)) = iu == UnicodeSyntax isUnicode (L _ ITlolly) = True isUnicode _ = False hasE :: Located Token -> Bool hasE (L _ (ITopenExpQuote HasE _)) = True hasE (L _ (ITopenTExpQuote HasE)) = True hasE _ = False getSCC :: Located Token -> P FastString getSCC lt = do let s = getSTRING lt -- We probably actually want to be more restrictive than this if ' ' `elem` unpackFS s then addFatalError $ PsError PsErrSpaceInSCC [] (getLoc lt) else return s -- Utilities for combining source spans comb2 :: Located a -> Located b -> SrcSpan comb2 a b = a `seq` b `seq` combineLocs a b -- Utilities for combining source spans comb2A :: Located a -> LocatedAn t b -> SrcSpan comb2A a b = a `seq` b `seq` combineLocs a (reLoc b) comb2N :: Located a -> LocatedN b -> SrcSpan comb2N a b = a `seq` b `seq` combineLocs a (reLocN b) comb2Al :: LocatedAn t a -> Located b -> SrcSpan comb2Al a b = a `seq` b `seq` combineLocs (reLoc a) b comb3 :: Located a -> Located b -> Located c -> SrcSpan comb3 a b c = a `seq` b `seq` c `seq` combineSrcSpans (getLoc a) (combineSrcSpans (getLoc b) (getLoc c)) comb3A :: Located a -> Located b -> LocatedAn t c -> SrcSpan comb3A a b c = a `seq` b `seq` c `seq` combineSrcSpans (getLoc a) (combineSrcSpans (getLoc b) (getLocA c)) comb3N :: Located a -> Located b -> LocatedN c -> SrcSpan comb3N a b c = a `seq` b `seq` c `seq` combineSrcSpans (getLoc a) (combineSrcSpans (getLoc b) (getLocA c)) comb4 :: Located a -> Located b -> Located c -> Located d -> SrcSpan comb4 a b c d = a `seq` b `seq` c `seq` d `seq` (combineSrcSpans (getLoc a) $ combineSrcSpans (getLoc b) $ combineSrcSpans (getLoc c) (getLoc d)) comb5 :: Located a -> Located b -> Located c -> Located d -> Located e -> SrcSpan comb5 a b c d e = a `seq` b `seq` c `seq` d `seq` e `seq` (combineSrcSpans (getLoc a) $ combineSrcSpans (getLoc b) $ combineSrcSpans (getLoc c) $ combineSrcSpans (getLoc d) (getLoc e)) -- strict constructor version: {-# INLINE sL #-} sL :: l -> a -> GenLocated l a sL loc a = loc `seq` a `seq` L loc a -- See Note [Adding location info] for how these utility functions are used -- replaced last 3 CPP macros in this file {-# INLINE sL0 #-} sL0 :: a -> Located a sL0 = L noSrcSpan -- #define L0 L noSrcSpan {-# INLINE sL1 #-} sL1 :: GenLocated l a -> b -> GenLocated l b sL1 x = sL (getLoc x) -- #define sL1 sL (getLoc $1) {-# INLINE sL1A #-} sL1A :: LocatedAn t a -> b -> Located b sL1A x = sL (getLocA x) -- #define sL1 sL (getLoc $1) {-# INLINE sL1N #-} sL1N :: LocatedN a -> b -> Located b sL1N x = sL (getLocA x) -- #define sL1 sL (getLoc $1) {-# INLINE sL1a #-} sL1a :: Located a -> b -> LocatedAn t b sL1a x = sL (noAnnSrcSpan $ getLoc x) -- #define sL1 sL (getLoc $1) {-# INLINE sL1n #-} sL1n :: Located a -> b -> LocatedN b sL1n x = L (noAnnSrcSpan $ getLoc x) -- #define sL1 sL (getLoc $1) {-# INLINE sLL #-} sLL :: Located a -> Located b -> c -> Located c sLL x y = sL (comb2 x y) -- #define LL sL (comb2 $1 $>) {-# INLINE sLLa #-} sLLa :: Located a -> Located b -> c -> LocatedAn t c sLLa x y = sL (noAnnSrcSpan $ comb2 x y) -- #define LL sL (comb2 $1 $>) {-# INLINE sLLlA #-} sLLlA :: Located a -> LocatedAn t b -> c -> Located c sLLlA x y = sL (comb2A x y) -- #define LL sL (comb2 $1 $>) {-# INLINE sLLAl #-} sLLAl :: LocatedAn t a -> Located b -> c -> Located c sLLAl x y = sL (comb2A y x) -- #define LL sL (comb2 $1 $>) {-# INLINE sLLAA #-} sLLAA :: LocatedAn t a -> LocatedAn u b -> c -> Located c sLLAA x y = sL (comb2 (reLoc y) (reLoc x)) -- #define LL sL (comb2 $1 $>) {- Note [Adding location info] ~~~~~~~~~~~~~~~~~~~~~~~~~~~ This is done using the three functions below, sL0, sL1 and sLL. Note that these functions were mechanically converted from the three macros that used to exist before, namely L0, L1 and LL. They each add a SrcSpan to their argument. sL0 adds 'noSrcSpan', used for empty productions -- This doesn't seem to work anymore -=chak sL1 for a production with a single token on the lhs. Grabs the SrcSpan from that token. sLL for a production with >1 token on the lhs. Makes up a SrcSpan from the first and last tokens. These suffice for the majority of cases. However, we must be especially careful with empty productions: sLL won't work if the first or last token on the lhs can represent an empty span. In these cases, we have to calculate the span using more of the tokens from the lhs, eg. | 'newtype' tycl_hdr '=' newconstr deriving { L (comb3 $1 $4 $5) (mkTyData NewType (unLoc $2) $4 (unLoc $5)) } We provide comb3 and comb4 functions which are useful in such cases. Be careful: there's no checking that you actually got this right, the only symptom will be that the SrcSpans of your syntax will be incorrect. -} -- Make a source location for the file. We're a bit lazy here and just -- make a point SrcSpan at line 1, column 0. Strictly speaking we should -- try to find the span of the whole file (ToDo). fileSrcSpan :: P SrcSpan fileSrcSpan = do l <- getRealSrcLoc; let loc = mkSrcLoc (srcLocFile l) 1 1; return (mkSrcSpan loc loc) -- Hint about linear types hintLinear :: MonadP m => SrcSpan -> m () hintLinear span = do linearEnabled <- getBit LinearTypesBit unless linearEnabled $ addError $ PsError PsErrLinearFunction [] span -- Does this look like (a %m)? looksLikeMult :: LHsType GhcPs -> LocatedN RdrName -> LHsType GhcPs -> Bool looksLikeMult ty1 l_op ty2 | Unqual op_name <- unLoc l_op , occNameFS op_name == fsLit "%" , Just ty1_pos <- getBufSpan (getLocA ty1) , Just pct_pos <- getBufSpan (getLocA l_op) , Just ty2_pos <- getBufSpan (getLocA ty2) , bufSpanEnd ty1_pos /= bufSpanStart pct_pos , bufSpanEnd pct_pos == bufSpanStart ty2_pos = True | otherwise = False -- Hint about the MultiWayIf extension hintMultiWayIf :: SrcSpan -> P () hintMultiWayIf span = do mwiEnabled <- getBit MultiWayIfBit unless mwiEnabled $ addError $ PsError PsErrMultiWayIf [] span -- Hint about explicit-forall hintExplicitForall :: Located Token -> P () hintExplicitForall tok = do forall <- getBit ExplicitForallBit rulePrag <- getBit InRulePragBit unless (forall || rulePrag) $ addError $ PsError (PsErrExplicitForall (isUnicode tok)) [] (getLoc tok) -- Hint about qualified-do hintQualifiedDo :: Located Token -> P () hintQualifiedDo tok = do qualifiedDo <- getBit QualifiedDoBit case maybeQDoDoc of Just qdoDoc | not qualifiedDo -> addError $ PsError (PsErrIllegalQualifiedDo qdoDoc) [] (getLoc tok) _ -> return () where maybeQDoDoc = case unLoc tok of ITdo (Just m) -> Just $ ftext m <> text ".do" ITmdo (Just m) -> Just $ ftext m <> text ".mdo" t -> Nothing -- When two single quotes don't followed by tyvar or gtycon, we report the -- error as empty character literal, or TH quote that missing proper type -- variable or constructor. See #13450. reportEmptyDoubleQuotes :: SrcSpan -> P a reportEmptyDoubleQuotes span = do thQuotes <- getBit ThQuotesBit addFatalError $ PsError (PsErrEmptyDoubleQuotes thQuotes) [] span {- %************************************************************************ %* * Helper functions for generating annotations in the parser %* * %************************************************************************ For the general principles of the following routines, see Note [exact print annotations] in GHC.Parser.Annotation -} -- |Construct an AddEpAnn from the annotation keyword and the location -- of the keyword itself mj :: AnnKeywordId -> Located e -> AddEpAnn mj a l = AddEpAnn a (EpaSpan $ rs $ gl l) mjN :: AnnKeywordId -> LocatedN e -> AddEpAnn mjN a l = AddEpAnn a (EpaSpan $ rs $ glN l) -- |Construct an AddEpAnn from the annotation keyword and the location -- of the keyword itself, provided the span is not zero width mz :: AnnKeywordId -> Located e -> [AddEpAnn] mz a l = if isZeroWidthSpan (gl l) then [] else [AddEpAnn a (EpaSpan $ rs $ gl l)] msemi :: Located e -> [TrailingAnn] msemi l = if isZeroWidthSpan (gl l) then [] else [AddSemiAnn (EpaSpan $ rs $ gl l)] -- |Construct an AddEpAnn from the annotation keyword and the Located Token. If -- the token has a unicode equivalent and this has been used, provide the -- unicode variant of the annotation. mu :: AnnKeywordId -> Located Token -> AddEpAnn mu a lt@(L l t) = AddEpAnn (toUnicodeAnn a lt) (EpaSpan $ rs l) mau :: Located Token -> TrailingAnn mau lt@(L l t) = if isUnicode lt then AddRarrowAnnU (EpaSpan $ rs l) else AddRarrowAnn (EpaSpan $ rs l) -- | If the 'Token' is using its unicode variant return the unicode variant of -- the annotation toUnicodeAnn :: AnnKeywordId -> Located Token -> AnnKeywordId toUnicodeAnn a t = if isUnicode t then unicodeAnn a else a toUnicode :: Located Token -> IsUnicodeSyntax toUnicode t = if isUnicode t then UnicodeSyntax else NormalSyntax gl :: GenLocated l a -> l gl = getLoc glA :: LocatedAn t a -> SrcSpan glA = getLocA glN :: LocatedN a -> SrcSpan glN = getLocA glR :: Located a -> Anchor glR la = Anchor (realSrcSpan $ getLoc la) UnchangedAnchor glAA :: Located a -> EpaLocation glAA = EpaSpan <$> realSrcSpan . getLoc glRR :: Located a -> RealSrcSpan glRR = realSrcSpan . getLoc glAR :: LocatedAn t a -> Anchor glAR la = Anchor (realSrcSpan $ getLocA la) UnchangedAnchor glNR :: LocatedN a -> Anchor glNR ln = Anchor (realSrcSpan $ getLocA ln) UnchangedAnchor glNRR :: LocatedN a -> EpaLocation glNRR = EpaSpan <$> realSrcSpan . getLocA anc :: RealSrcSpan -> Anchor anc r = Anchor r UnchangedAnchor acs :: MonadP m => (EpAnnComments -> Located a) -> m (Located a) acs a = do let (L l _) = a emptyComments cs <- getCommentsFor l return (a cs) -- Called at the very end to pick up the EOF position, as well as any comments not allocated yet. acsFinal :: (EpAnnComments -> Located a) -> P (Located a) acsFinal a = do let (L l _) = a emptyComments cs <- getCommentsFor l csf <- getFinalCommentsFor l meof <- getEofPos let ce = case meof of Nothing -> EpaComments [] Just (pos, gap) -> EpaCommentsBalanced [] [L (realSpanAsAnchor pos) (EpaComment EpaEofComment gap)] return (a (cs Semi.<> csf Semi.<> ce)) acsa :: MonadP m => (EpAnnComments -> LocatedAn t a) -> m (LocatedAn t a) acsa a = do let (L l _) = a emptyComments cs <- getCommentsFor (locA l) return (a cs) acsA :: MonadP m => (EpAnnComments -> Located a) -> m (LocatedAn t a) acsA a = reLocA <$> acs a acsExpr :: (EpAnnComments -> LHsExpr GhcPs) -> P ECP acsExpr a = do { expr :: (LHsExpr GhcPs) <- runPV $ acsa a ; return (ecpFromExp $ expr) } amsA :: MonadP m => LocatedA a -> [TrailingAnn] -> m (LocatedA a) amsA (L l a) bs = do cs <- getCommentsFor (locA l) return (L (addAnnsA l bs cs) a) amsrc :: MonadP m => Located a -> AnnContext -> m (LocatedC a) amsrc a@(L l _) bs = do cs <- getCommentsFor l return (reAnnC bs cs a) amsrl :: MonadP m => Located a -> AnnList -> m (LocatedL a) amsrl a@(L l _) bs = do cs <- getCommentsFor l return (reAnnL bs cs a) amsrp :: MonadP m => Located a -> AnnPragma -> m (LocatedP a) amsrp a@(L l _) bs = do cs <- getCommentsFor l return (reAnnL bs cs a) amsrn :: MonadP m => Located a -> NameAnn -> m (LocatedN a) amsrn (L l a) an = do cs <- getCommentsFor l let ann = (EpAnn (spanAsAnchor l) an cs) return (L (SrcSpanAnn ann l) a) -- |Synonyms for AddEpAnn versions of AnnOpen and AnnClose mo,mc :: Located Token -> AddEpAnn mo ll = mj AnnOpen ll mc ll = mj AnnClose ll moc,mcc :: Located Token -> AddEpAnn moc ll = mj AnnOpenC ll mcc ll = mj AnnCloseC ll mop,mcp :: Located Token -> AddEpAnn mop ll = mj AnnOpenP ll mcp ll = mj AnnCloseP ll moh,mch :: Located Token -> AddEpAnn moh ll = mj AnnOpenPH ll mch ll = mj AnnClosePH ll mos,mcs :: Located Token -> AddEpAnn mos ll = mj AnnOpenS ll mcs ll = mj AnnCloseS ll pvA :: MonadP m => m (Located a) -> m (LocatedAn t a) pvA a = do { av <- a ; return (reLocA av) } pvN :: MonadP m => m (Located a) -> m (LocatedN a) pvN a = do { (L l av) <- a ; return (L (noAnnSrcSpan l) av) } pvL :: MonadP m => m (LocatedAn t a) -> m (Located a) pvL a = do { av <- a ; return (reLoc av) } -- | Parse a Haskell module with Haddock comments. -- This is done in two steps: -- -- * 'parseModuleNoHaddock' to build the AST -- * 'addHaddockToModule' to insert Haddock comments into it -- -- This is the only parser entry point that deals with Haddock comments. -- The other entry points ('parseDeclaration', 'parseExpression', etc) do -- not insert them into the AST. parseModule :: P (Located HsModule) parseModule = parseModuleNoHaddock >>= addHaddockToModule commentsA :: (Monoid ann) => SrcSpan -> EpAnnComments -> SrcSpanAnn' (EpAnn ann) commentsA loc cs = SrcSpanAnn (EpAnn (Anchor (rs loc) UnchangedAnchor) mempty cs) loc -- | Instead of getting the *enclosed* comments, this includes the -- *preceding* ones. It is used at the top level to get comments -- between top level declarations. commentsPA :: (Monoid ann) => LocatedAn ann a -> P (LocatedAn ann a) commentsPA la@(L l a) = do cs <- getPriorCommentsFor (getLocA la) return (L (addCommentsToSrcAnn l cs) a) rs :: SrcSpan -> RealSrcSpan rs (RealSrcSpan l _) = l rs _ = panic "Parser should only have RealSrcSpan" hsDoAnn :: Located a -> LocatedAn t b -> AnnKeywordId -> AnnList hsDoAnn (L l _) (L ll _) kw = AnnList (Just $ spanAsAnchor (locA ll)) Nothing Nothing [AddEpAnn kw (EpaSpan $ rs l)] [] listAsAnchor :: [LocatedAn t a] -> Anchor listAsAnchor [] = spanAsAnchor noSrcSpan listAsAnchor (L l _:_) = spanAsAnchor (locA l) -- ------------------------------------- addTrailingCommaFBind :: MonadP m => Fbind b -> SrcSpan -> m (Fbind b) addTrailingCommaFBind (Left b) l = fmap Left (addTrailingCommaA b l) addTrailingCommaFBind (Right b) l = fmap Right (addTrailingCommaA b l) addTrailingVbarA :: MonadP m => LocatedA a -> SrcSpan -> m (LocatedA a) addTrailingVbarA la span = addTrailingAnnA la span AddVbarAnn addTrailingSemiA :: MonadP m => LocatedA a -> SrcSpan -> m (LocatedA a) addTrailingSemiA la span = addTrailingAnnA la span AddSemiAnn addTrailingCommaA :: MonadP m => LocatedA a -> SrcSpan -> m (LocatedA a) addTrailingCommaA la span = addTrailingAnnA la span AddCommaAnn addTrailingAnnA :: MonadP m => LocatedA a -> SrcSpan -> (EpaLocation -> TrailingAnn) -> m (LocatedA a) addTrailingAnnA (L (SrcSpanAnn anns l) a) ss ta = do -- cs <- getCommentsFor l let cs = emptyComments -- AZ:TODO: generalise updating comments into an annotation let anns' = if isZeroWidthSpan ss then anns else addTrailingAnnToA l (ta (EpaSpan $ rs ss)) cs anns return (L (SrcSpanAnn anns' l) a) -- ------------------------------------- addTrailingVbarL :: MonadP m => LocatedL a -> SrcSpan -> m (LocatedL a) addTrailingVbarL la span = addTrailingAnnL la (AddVbarAnn (EpaSpan $ rs span)) addTrailingCommaL :: MonadP m => LocatedL a -> SrcSpan -> m (LocatedL a) addTrailingCommaL la span = addTrailingAnnL la (AddCommaAnn (EpaSpan $ rs span)) addTrailingAnnL :: MonadP m => LocatedL a -> TrailingAnn -> m (LocatedL a) addTrailingAnnL (L (SrcSpanAnn anns l) a) ta = do cs <- getCommentsFor l let anns' = addTrailingAnnToL l ta cs anns return (L (SrcSpanAnn anns' l) a) -- ------------------------------------- -- Mostly use to add AnnComma, special case it to NOP if adding a zero-width annotation addTrailingCommaN :: MonadP m => LocatedN a -> SrcSpan -> m (LocatedN a) addTrailingCommaN (L (SrcSpanAnn anns l) a) span = do -- cs <- getCommentsFor l let cs = emptyComments -- AZ:TODO: generalise updating comments into an annotation let anns' = if isZeroWidthSpan span then anns else addTrailingCommaToN l anns (EpaSpan $ rs span) return (L (SrcSpanAnn anns' l) a) addTrailingCommaS :: Located StringLiteral -> EpaLocation -> Located StringLiteral addTrailingCommaS (L l sl) span = L l (sl { sl_tc = Just (epaLocationRealSrcSpan span) }) -- ------------------------------------- addTrailingDarrowC :: LocatedC a -> Located Token -> EpAnnComments -> LocatedC a addTrailingDarrowC (L (SrcSpanAnn EpAnnNotUsed l) a) lt cs = let u = if (isUnicode lt) then UnicodeSyntax else NormalSyntax in L (SrcSpanAnn (EpAnn (spanAsAnchor l) (AnnContext (Just (u,glAA lt)) [] []) cs) l) a addTrailingDarrowC (L (SrcSpanAnn (EpAnn lr (AnnContext _ o c) csc) l) a) lt cs = let u = if (isUnicode lt) then UnicodeSyntax else NormalSyntax in L (SrcSpanAnn (EpAnn lr (AnnContext (Just (u,glAA lt)) o c) (cs Semi.<> csc)) l) a -- ------------------------------------- -- We need a location for the where binds, when computing the SrcSpan -- for the AST element using them. Where there is a span, we return -- it, else noLoc, which is ignored in the comb2 call. adaptWhereBinds :: Maybe (Located (HsLocalBinds GhcPs)) -> Located (HsLocalBinds GhcPs) adaptWhereBinds Nothing = noLoc (EmptyLocalBinds noExtField) adaptWhereBinds (Just b) = b }