SrcSpan, combineLocs, srcLocFile,
mkSrcLoc, mkSrcSpan )
import Module
-import StaticFlags ( opt_SccProfilingOn )
+import StaticFlags ( opt_SccProfilingOn, opt_Hpc )
import Type ( Kind, mkArrowKind, liftedTypeKind, unliftedTypeKind )
import BasicTypes ( Boxity(..), Fixity(..), FixityDirection(..), IPName(..),
Activation(..), defaultInlineSpec )
import OrdList
+import HaddockParse
+import {-# SOURCE #-} HaddockLex hiding ( Token )
+import HaddockUtils
import FastString
import Maybes ( orElse )
import Outputable
-import GLAEXTS
+
+import Control.Monad ( unless )
+import GHC.Exts
+import Data.Char
+import Control.Monad ( mplus )
}
{-
-----------------------------------------------------------------------------
-Conflicts: 36 shift/reduce (1.25)
+24 Februar 2006
+
+Conflicts: 33 shift/reduce
+ 1 reduce/reduce
+
+The reduce/reduce conflict is weird. It's between tyconsym and consym, and I
+would think the two should never occur in the same context.
+
+ -=chak
+
+-----------------------------------------------------------------------------
+31 December 2006
+
+Conflicts: 34 shift/reduce
+ 1 reduce/reduce
+
+The reduce/reduce conflict is weird. It's between tyconsym and consym, and I
+would think the two should never occur in the same context.
+
+ -=chak
+
+-----------------------------------------------------------------------------
+6 December 2006
+
+Conflicts: 32 shift/reduce
+ 1 reduce/reduce
+
+The reduce/reduce conflict is weird. It's between tyconsym and consym, and I
+would think the two should never occur in the same context.
+
+ -=chak
+
+-----------------------------------------------------------------------------
+26 July 2006
+
+Conflicts: 37 shift/reduce
+ 1 reduce/reduce
+
+The reduce/reduce conflict is weird. It's between tyconsym and consym, and I
+would think the two should never occur in the same context.
+
+ -=chak
+
+-----------------------------------------------------------------------------
+Conflicts: 38 shift/reduce (1.25)
10 for abiguity in 'if x then y else z + 1' [State 178]
(shift parses as 'if x then y else (z + 1)', as per longest-parse rule)
This saves explicitly defining a grammar for the rule lhs that
doesn't include 'forall'.
+1 for ambiguity when the source file starts with "-- | doc". We need another
+ token of lookahead to determine if a top declaration or the 'module' keyword
+ follows. Shift parses as if the 'module' keyword follows.
+
-- ---------------------------------------------------------------------------
-- Adding location info
They each add a SrcSpan to their argument.
L0 adds 'noSrcSpan', used for empty productions
+ -- This doesn't seem to work anymore -=chak
L1 for a production with a single token on the lhs. Grabs the SrcSpan
from that token.
'data' { L _ ITdata }
'default' { L _ ITdefault }
'deriving' { L _ ITderiving }
+ 'derive' { L _ ITderive }
'do' { L _ ITdo }
'else' { L _ ITelse }
'hiding' { L _ IThiding }
'where' { L _ ITwhere }
'_scc_' { L _ ITscc } -- ToDo: remove
- 'forall' { L _ ITforall } -- GHC extension keywords
+ 'forall' { L _ ITforall } -- GHC extension keywords
'foreign' { L _ ITforeign }
'export' { L _ ITexport }
'label' { L _ ITlabel }
'threadsafe' { L _ ITthreadsafe }
'unsafe' { L _ ITunsafe }
'mdo' { L _ ITmdo }
+ 'family' { L _ ITfamily }
'stdcall' { L _ ITstdcallconv }
'ccall' { L _ ITccallconv }
'dotnet' { L _ ITdotnet }
'{-# RULES' { L _ ITrules_prag }
'{-# CORE' { L _ ITcore_prag } -- hdaume: annotated core
'{-# SCC' { L _ ITscc_prag }
+ '{-# GENERATED' { L _ ITgenerated_prag }
'{-# DEPRECATED' { L _ ITdeprecated_prag }
'{-# UNPACK' { L _ ITunpack_prag }
'#-}' { L _ ITclose_prag }
QCONSYM { L _ (ITqconsym _) }
IPDUPVARID { L _ (ITdupipvarid _) } -- GHC extension
- IPSPLITVARID { L _ (ITsplitipvarid _) } -- GHC extension
CHAR { L _ (ITchar _) }
STRING { L _ (ITstring _) }
PRIMINTEGER { L _ (ITprimint _) }
PRIMFLOAT { L _ (ITprimfloat _) }
PRIMDOUBLE { L _ (ITprimdouble _) }
-
+
+ DOCNEXT { L _ (ITdocCommentNext _) }
+ DOCPREV { L _ (ITdocCommentPrev _) }
+ DOCNAMED { L _ (ITdocCommentNamed _) }
+ DOCSECTION { L _ (ITdocSection _ _) }
+ DOCOPTIONS { L _ (ITdocOptions _) }
+
-- Template Haskell
'[|' { L _ ITopenExpQuote }
'[p|' { L _ ITopenPatQuote }
-- know what they are doing. :-)
module :: { Located (HsModule RdrName) }
- : 'module' modid maybemoddeprec maybeexports 'where' body
- {% fileSrcSpan >>= \ loc ->
- return (L loc (HsModule (Just $2) $4 (fst $6) (snd $6) $3)) }
- | missing_module_keyword top close
+ : optdoc 'module' modid maybemoddeprec maybeexports 'where' body
+ {% fileSrcSpan >>= \ loc -> case $1 of { (opt, info, doc) ->
+ return (L loc (HsModule (Just $3) $5 (fst $7) (snd $7) $4
+ opt info doc) )}}
+ | body2
{% fileSrcSpan >>= \ loc ->
return (L loc (HsModule Nothing Nothing
- (fst $2) (snd $2) Nothing)) }
+ (fst $1) (snd $1) Nothing Nothing emptyHaddockModInfo
+ Nothing)) }
+
+optdoc :: { (Maybe String, HaddockModInfo RdrName, Maybe (HsDoc RdrName)) }
+ : moduleheader { (Nothing, fst $1, snd $1) }
+ | docoptions { (Just $1, emptyHaddockModInfo, Nothing)}
+ | docoptions moduleheader { (Just $1, fst $2, snd $2) }
+ | moduleheader docoptions { (Just $2, fst $1, snd $1) }
+ | {- empty -} { (Nothing, emptyHaddockModInfo, Nothing) }
missing_module_keyword :: { () }
: {- empty -} {% pushCurrentContext }
: '{' top '}' { $2 }
| vocurly top close { $2 }
+body2 :: { ([LImportDecl RdrName], [LHsDecl RdrName]) }
+ : '{' top '}' { $2 }
+ | missing_module_keyword top close { $2 }
+
top :: { ([LImportDecl RdrName], [LHsDecl RdrName]) }
: importdecls { (reverse $1,[]) }
| importdecls ';' cvtopdecls { (reverse $1,$3) }
-- Module declaration & imports only
header :: { Located (HsModule RdrName) }
- : 'module' modid maybemoddeprec maybeexports 'where' header_body
- {% fileSrcSpan >>= \ loc ->
- return (L loc (HsModule (Just $2) $4 $6 [] $3)) }
+ : optdoc 'module' modid maybemoddeprec maybeexports 'where' header_body
+ {% fileSrcSpan >>= \ loc -> case $1 of { (opt, info, doc) ->
+ return (L loc (HsModule (Just $3) $5 $7 [] $4
+ opt info doc))}}
| missing_module_keyword importdecls
{% fileSrcSpan >>= \ loc ->
- return (L loc (HsModule Nothing Nothing $2 [] Nothing)) }
+ return (L loc (HsModule Nothing Nothing $2 [] Nothing
+ Nothing emptyHaddockModInfo Nothing)) }
header_body :: { [LImportDecl RdrName] }
: '{' importdecls { $2 }
: '(' exportlist ')' { Just $2 }
| {- empty -} { Nothing }
-exportlist :: { [LIE RdrName] }
- : ',' { [] }
+exportlist :: { [LIE RdrName] }
+ : expdoclist ',' expdoclist { $1 ++ $3 }
| exportlist1 { $1 }
exportlist1 :: { [LIE RdrName] }
- : export { [$1] }
- | export ',' exportlist { $1 : $3 }
- | {- empty -} { [] }
-
+ : expdoclist export expdoclist ',' exportlist { $1 ++ ($2 : $3) ++ $5 }
+ | expdoclist export expdoclist { $1 ++ ($2 : $3) }
+ | expdoclist { $1 }
+
+expdoclist :: { [LIE RdrName] }
+ : exp_doc expdoclist { $1 : $2 }
+ | {- empty -} { [] }
+
+exp_doc :: { LIE RdrName }
+ : docsection { L1 (case (unLoc $1) of (n, doc) -> IEGroup n doc) }
+ | docnamed { L1 (IEDocNamed ((fst . unLoc) $1)) }
+ | docnext { L1 (IEDoc (unLoc $1)) }
+
-- No longer allow things like [] and (,,,) to be exported
-- They are built in syntax, always available
export :: { LIE RdrName }
| 'module' modid { LL (IEModuleContents (unLoc $2)) }
qcnames :: { [RdrName] }
- : qcnames ',' qcname { unLoc $3 : $1 }
- | qcname { [unLoc $1] }
+ : qcnames ',' qcname_ext { unLoc $3 : $1 }
+ | qcname_ext { [unLoc $1] }
+qcname_ext :: { Located RdrName } -- Variable or data constructor
+ -- or tagged type constructor
+ : qcname { $1 }
+ | 'type' qcon { sL (comb2 $1 $2)
+ (setRdrNameSpace (unLoc $2)
+ tcClsName) }
+
+-- Cannot pull into qcname_ext, as qcname is also used in expression.
qcname :: { Located RdrName } -- Variable or data constructor
- : qvar { $1 }
- | qcon { $1 }
+ : qvar { $1 }
+ | qcon { $1 }
-----------------------------------------------------------------------------
-- Import Declarations
-- Top-Level Declarations
topdecls :: { OrdList (LHsDecl RdrName) }
- : topdecls ';' topdecl { $1 `appOL` $3 }
- | topdecls ';' { $1 }
- | topdecl { $1 }
+ : topdecls ';' topdecl { $1 `appOL` $3 }
+ | topdecls ';' { $1 }
+ | topdecl { $1 }
topdecl :: { OrdList (LHsDecl RdrName) }
- : tycl_decl { unitOL (L1 (TyClD (unLoc $1))) }
- | 'instance' inst_type where
- { let (binds,sigs) = cvBindsAndSigs (unLoc $3)
- in unitOL (L (comb3 $1 $2 $3) (InstD (InstDecl $2 binds sigs))) }
+ : cl_decl { unitOL (L1 (TyClD (unLoc $1))) }
+ | ty_decl { unitOL (L1 (TyClD (unLoc $1))) }
+ | 'instance' inst_type where_inst
+ { let (binds, sigs, ats, _) = cvBindsAndSigs (unLoc $3)
+ in
+ unitOL (L (comb3 $1 $2 $3) (InstD (InstDecl $2 binds sigs ats)))}
+ | stand_alone_deriving { unitOL (LL (DerivD (unLoc $1))) }
| 'default' '(' comma_types0 ')' { unitOL (LL $ DefD (DefaultDecl $3)) }
| 'foreign' fdecl { unitOL (LL (unLoc $2)) }
| '{-# DEPRECATED' deprecations '#-}' { $2 }
L1 $ HsVar (mkUnqual varName (getTH_ID_SPLICE $1))
)) }
-tycl_decl :: { LTyClDecl RdrName }
- : 'type' type '=' ctype
- -- Note type on the left of the '='; this allows
- -- infix type constructors to be declared
- --
- -- Note ctype, not sigtype, on the right
+-- Type classes
+--
+cl_decl :: { LTyClDecl RdrName }
+ : 'class' tycl_hdr fds where_cls
+ {% do { let { (binds, sigs, ats, docs) =
+ cvBindsAndSigs (unLoc $4)
+ ; (ctxt, tc, tvs, tparms) = unLoc $2}
+ ; checkTyVars tparms -- only type vars allowed
+ ; checkKindSigs ats
+ ; return $ L (comb4 $1 $2 $3 $4)
+ (mkClassDecl (ctxt, tc, tvs)
+ (unLoc $3) sigs binds ats docs) } }
+
+-- Type declarations (toplevel)
+--
+ty_decl :: { LTyClDecl RdrName }
+ -- ordinary type synonyms
+ : 'type' type '=' ctype
+ -- Note ctype, 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
- {% do { (tc,tvs) <- checkSynHdr $2
- ; return (LL (TySynonym tc tvs $4)) } }
-
+ --
+ -- Note the use of type for the head; this allows
+ -- infix type constructors to be declared
+ {% do { (tc, tvs, _) <- checkSynHdr $2 False
+ ; return (L (comb2 $1 $4)
+ (TySynonym tc tvs Nothing $4))
+ } }
+
+ -- type family declarations
+ | 'type' 'family' type opt_kind_sig
+ -- Note the use of type for the head; this allows
+ -- infix type constructors to be declared
+ --
+ {% do { (tc, tvs, _) <- checkSynHdr $3 False
+ ; return (L (comb3 $1 $3 $4)
+ (TyFamily TypeFamily tc tvs (unLoc $4)))
+ } }
+
+ -- type instance declarations
+ | 'type' 'instance' type '=' ctype
+ -- Note the use of type for the head; this allows
+ -- infix type constructors and type patterns
+ --
+ {% do { (tc, tvs, typats) <- checkSynHdr $3 True
+ ; return (L (comb2 $1 $5)
+ (TySynonym tc tvs (Just typats) $5))
+ } }
+
+ -- ordinary data type or newtype declaration
| data_or_newtype tycl_hdr constrs deriving
- { L (comb4 $1 $2 $3 $4) -- We need the location on tycl_hdr
- -- in case constrs and deriving are both empty
- (mkTyData (unLoc $1) (unLoc $2) Nothing (reverse (unLoc $3)) (unLoc $4)) }
-
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $2}
+ ; checkTyVars tparms -- no type pattern
+ ; return $
+ L (comb4 $1 $2 $3 $4)
+ -- We need the location on tycl_hdr in case
+ -- constrs and deriving are both empty
+ (mkTyData (unLoc $1) (ctxt, tc, tvs, Nothing)
+ Nothing (reverse (unLoc $3)) (unLoc $4)) } }
+
+ -- ordinary GADT declaration
| data_or_newtype tycl_hdr opt_kind_sig
'where' gadt_constrlist
deriving
- { L (comb4 $1 $2 $4 $5)
- (mkTyData (unLoc $1) (unLoc $2) $3 (reverse (unLoc $5)) (unLoc $6)) }
-
- | 'class' tycl_hdr fds where
- { let
- (binds,sigs) = cvBindsAndSigs (unLoc $4)
- in
- L (comb4 $1 $2 $3 $4) (mkClassDecl (unLoc $2) (unLoc $3) sigs
- binds) }
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $2}
+ ; checkTyVars tparms -- can have type pats
+ ; return $
+ L (comb4 $1 $2 $4 $5)
+ (mkTyData (unLoc $1) (ctxt, tc, tvs, Nothing)
+ (unLoc $3) (reverse (unLoc $5)) (unLoc $6)) } }
+
+ -- data/newtype family
+ | 'data' 'family' tycl_hdr opt_kind_sig
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $3}
+ ; checkTyVars tparms -- no type pattern
+ ; unless (null (unLoc ctxt)) $ -- and no context
+ parseError (getLoc ctxt)
+ "A family declaration cannot have a context"
+ ; return $
+ L (comb3 $1 $2 $4)
+ (TyFamily DataFamily tc tvs (unLoc $4)) } }
+
+ -- data/newtype instance declaration
+ | data_or_newtype 'instance' tycl_hdr constrs deriving
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $3}
+ -- can have type pats
+ ; return $
+ L (comb4 $1 $3 $4 $5)
+ -- We need the location on tycl_hdr in case
+ -- constrs and deriving are both empty
+ (mkTyData (unLoc $1) (ctxt, tc, tvs, Just tparms)
+ Nothing (reverse (unLoc $4)) (unLoc $5)) } }
+
+ -- GADT instance declaration
+ | data_or_newtype 'instance' tycl_hdr opt_kind_sig
+ 'where' gadt_constrlist
+ deriving
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $3}
+ -- can have type pats
+ ; return $
+ L (comb4 $1 $3 $6 $7)
+ (mkTyData (unLoc $1) (ctxt, tc, tvs, Just tparms)
+ (unLoc $4) (reverse (unLoc $6)) (unLoc $7)) } }
+
+-- Associate 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 :: { LTyClDecl RdrName }
+ -- type family declarations
+ : 'type' type opt_kind_sig
+ -- Note the use of type for the head; this allows
+ -- infix type constructors to be declared
+ --
+ {% do { (tc, tvs, _) <- checkSynHdr $2 False
+ ; return (L (comb3 $1 $2 $3)
+ (TyFamily TypeFamily tc tvs (unLoc $3)))
+ } }
+
+ -- default type instance
+ | 'type' type '=' ctype
+ -- Note the use of type for the head; this allows
+ -- infix type constructors and type patterns
+ --
+ {% do { (tc, tvs, typats) <- checkSynHdr $2 True
+ ; return (L (comb2 $1 $4)
+ (TySynonym tc tvs (Just typats) $4))
+ } }
+
+ -- data/newtype family declaration
+ | 'data' tycl_hdr opt_kind_sig
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $2}
+ ; checkTyVars tparms -- no type pattern
+ ; unless (null (unLoc ctxt)) $ -- and no context
+ parseError (getLoc ctxt)
+ "A family declaration cannot have a context"
+ ; return $
+ L (comb3 $1 $2 $3)
+ (TyFamily DataFamily tc tvs (unLoc $3))
+ } }
+
+-- Associate type instances
+--
+at_decl_inst :: { LTyClDecl RdrName }
+ -- type instance declarations
+ : 'type' type '=' ctype
+ -- Note the use of type for the head; this allows
+ -- infix type constructors and type patterns
+ --
+ {% do { (tc, tvs, typats) <- checkSynHdr $2 True
+ ; return (L (comb2 $1 $4)
+ (TySynonym tc tvs (Just typats) $4))
+ } }
+
+ -- data/newtype instance declaration
+ | data_or_newtype tycl_hdr constrs deriving
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $2}
+ -- can have type pats
+ ; return $
+ L (comb4 $1 $2 $3 $4)
+ -- We need the location on tycl_hdr in case
+ -- constrs and deriving are both empty
+ (mkTyData (unLoc $1) (ctxt, tc, tvs, Just tparms)
+ Nothing (reverse (unLoc $3)) (unLoc $4)) } }
+
+ -- GADT instance declaration
+ | data_or_newtype tycl_hdr opt_kind_sig
+ 'where' gadt_constrlist
+ deriving
+ {% do { let {(ctxt, tc, tvs, tparms) = unLoc $2}
+ -- can have type pats
+ ; return $
+ L (comb4 $1 $2 $5 $6)
+ (mkTyData (unLoc $1) (ctxt, tc, tvs, Just tparms)
+ (unLoc $3) (reverse (unLoc $5)) (unLoc $6)) } }
data_or_newtype :: { Located NewOrData }
: 'data' { L1 DataType }
| 'newtype' { L1 NewType }
-opt_kind_sig :: { Maybe Kind }
- : { Nothing }
- | '::' kind { Just $2 }
+opt_kind_sig :: { Located (Maybe Kind) }
+ : { noLoc Nothing }
+ | '::' kind { LL (Just (unLoc $2)) }
--- tycl_hdr parses the header of a type or class decl,
+-- 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 (LHsContext RdrName, Located RdrName, [LHsTyVarBndr RdrName]) }
+tycl_hdr :: { Located (LHsContext RdrName,
+ Located RdrName,
+ [LHsTyVarBndr RdrName],
+ [LHsType RdrName]) }
: context '=>' type {% checkTyClHdr $1 $3 >>= return.LL }
| type {% checkTyClHdr (noLoc []) $1 >>= return.L1 }
-----------------------------------------------------------------------------
+-- Stand-alone deriving
+
+-- Glasgow extension: stand-alone deriving declarations
+stand_alone_deriving :: { LDerivDecl RdrName }
+ : 'derive' 'instance' inst_type {% checkDerivDecl (LL (DerivDecl $3)) }
+
+-----------------------------------------------------------------------------
-- Nested declarations
+-- Declaration in class bodies
+--
+decl_cls :: { Located (OrdList (LHsDecl RdrName)) }
+decl_cls : at_decl_cls { LL (unitOL (L1 (TyClD (unLoc $1)))) }
+ | decl { $1 }
+
+decls_cls :: { Located (OrdList (LHsDecl RdrName)) } -- Reversed
+ : decls_cls ';' decl_cls { LL (unLoc $1 `appOL` unLoc $3) }
+ | decls_cls ';' { LL (unLoc $1) }
+ | decl_cls { $1 }
+ | {- empty -} { noLoc nilOL }
+
+
+decllist_cls
+ :: { Located (OrdList (LHsDecl RdrName)) } -- Reversed
+ : '{' decls_cls '}' { LL (unLoc $2) }
+ | vocurly decls_cls close { $2 }
+
+-- Class body
+--
+where_cls :: { Located (OrdList (LHsDecl RdrName)) } -- Reversed
+ -- No implicit parameters
+ -- May have type declarations
+ : 'where' decllist_cls { LL (unLoc $2) }
+ | {- empty -} { noLoc nilOL }
+
+-- Declarations in instance bodies
+--
+decl_inst :: { Located (OrdList (LHsDecl RdrName)) }
+decl_inst : at_decl_inst { LL (unitOL (L1 (TyClD (unLoc $1)))) }
+ | decl { $1 }
+
+decls_inst :: { Located (OrdList (LHsDecl RdrName)) } -- Reversed
+ : decls_inst ';' decl_inst { LL (unLoc $1 `appOL` unLoc $3) }
+ | decls_inst ';' { LL (unLoc $1) }
+ | decl_inst { $1 }
+ | {- empty -} { noLoc nilOL }
+
+decllist_inst
+ :: { Located (OrdList (LHsDecl RdrName)) } -- Reversed
+ : '{' decls_inst '}' { LL (unLoc $2) }
+ | vocurly decls_inst close { $2 }
+
+-- Instance body
+--
+where_inst :: { Located (OrdList (LHsDecl RdrName)) } -- Reversed
+ -- No implicit parameters
+ -- May have type declarations
+ : 'where' decllist_inst { LL (unLoc $2) }
+ | {- empty -} { noLoc nilOL }
+
+-- Declarations in binding groups other than classes and instances
+--
decls :: { Located (OrdList (LHsDecl RdrName)) }
: decls ';' decl { LL (unLoc $1 `appOL` unLoc $3) }
| decls ';' { LL (unLoc $1) }
| decl { $1 }
| {- empty -} { noLoc nilOL }
-
decllist :: { Located (OrdList (LHsDecl RdrName)) }
: '{' decls '}' { LL (unLoc $2) }
| vocurly decls close { $2 }
-where :: { Located (OrdList (LHsDecl RdrName)) }
- -- No implicit parameters
- : 'where' decllist { LL (unLoc $2) }
- | {- empty -} { noLoc nilOL }
-
+-- Binding groups other than those of class and instance declarations
+--
binds :: { Located (HsLocalBinds RdrName) } -- May have implicit parameters
+ -- No type declarations
: decllist { L1 (HsValBinds (cvBindGroup (unLoc $1))) }
| '{' dbinds '}' { LL (HsIPBinds (IPBinds (unLoc $2) emptyLHsBinds)) }
| vocurly dbinds close { L (getLoc $2) (HsIPBinds (IPBinds (unLoc $2) emptyLHsBinds)) }
wherebinds :: { Located (HsLocalBinds RdrName) } -- May have implicit parameters
+ -- No type declarations
: 'where' binds { LL (unLoc $2) }
| {- empty -} { noLoc emptyLocalBinds }
| 'threadsafe' { PlaySafe True }
fspec :: { Located (Located FastString, Located RdrName, LHsType RdrName) }
- : STRING var '::' sigtype { LL (L (getLoc $1) (getSTRING $1), $2, $4) }
- | var '::' sigtype { LL (noLoc nilFS, $1, $3) }
+ : STRING var '::' sigtypedoc { LL (L (getLoc $1) (getSTRING $1), $2, $4) }
+ | var '::' sigtypedoc { LL (noLoc nilFS, $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
: ctype { L1 (mkImplicitHsForAllTy (noLoc []) $1) }
-- Wrap an Implicit forall if there isn't one there already
+sigtypedoc :: { LHsType RdrName }
+ : ctypedoc { L1 (mkImplicitHsForAllTy (noLoc []) $1) }
+ -- Wrap an Implicit forall if there isn't one there already
+
sig_vars :: { Located [Located RdrName] }
: sig_vars ',' var { LL ($3 : unLoc $1) }
| var { L1 [$1] }
-----------------------------------------------------------------------------
-- Types
+infixtype :: { LHsType RdrName }
+ : btype qtyconop gentype { LL $ HsOpTy $1 $2 $3 }
+ | btype tyvarop gentype { LL $ HsOpTy $1 $2 $3 }
+
+infixtypedoc :: { LHsType RdrName }
+ : infixtype { $1 }
+ | infixtype docprev { LL $ HsDocTy $1 $2 }
+
+gentypedoc :: { LHsType RdrName }
+ : btype { $1 }
+ | btypedoc { $1 }
+ | infixtypedoc { $1 }
+ | btype '->' ctypedoc { LL $ HsFunTy $1 $3 }
+ | btypedoc '->' ctypedoc { LL $ HsFunTy $1 $3 }
+
+ctypedoc :: { LHsType RdrName }
+ : 'forall' tv_bndrs '.' ctypedoc { LL $ mkExplicitHsForAllTy $2 (noLoc []) $4 }
+ | context '=>' gentypedoc { LL $ mkImplicitHsForAllTy $1 $3 }
+ -- A type of form (context => type) is an *implicit* HsForAllTy
+ | gentypedoc { $1 }
+
strict_mark :: { Located HsBang }
: '!' { L1 HsStrict }
| '{-# UNPACK' '#-}' '!' { LL HsUnbox }
-- 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 =>
+--
+-- We have the t1 ~ t2 form here and in gentype, to permit an individual
+-- equational constraint without parenthesis.
context :: { LHsContext RdrName }
- : btype {% checkContext $1 }
+ : btype '~' btype {% checkContext
+ (LL $ HsPredTy (HsEqualP $1 $3)) }
+ | btype {% checkContext $1 }
type :: { LHsType RdrName }
: ipvar '::' gentype { LL (HsPredTy (HsIParam (unLoc $1) $3)) }
: btype { $1 }
| btype qtyconop gentype { LL $ HsOpTy $1 $2 $3 }
| btype tyvarop gentype { LL $ HsOpTy $1 $2 $3 }
- | btype '->' ctype { LL $ HsFunTy $1 $3 }
+ | btype '->' ctype { LL $ HsFunTy $1 $3 }
+ | btype '~' btype { LL $ HsPredTy (HsEqualP $1 $3) }
btype :: { LHsType RdrName }
: btype atype { LL $ HsAppTy $1 $2 }
| atype { $1 }
+btypedoc :: { LHsType RdrName }
+ : btype atype docprev { LL $ HsDocTy (L (comb2 $1 $2) (HsAppTy $1 $2)) $3 }
+ | atype docprev { LL $ HsDocTy $1 $2 }
+
atype :: { LHsType RdrName }
: gtycon { L1 (HsTyVar (unLoc $1)) }
| tyvar { L1 (HsTyVar (unLoc $1)) }
| '[' ctype ']' { LL $ HsListTy $2 }
| '[:' ctype ':]' { LL $ HsPArrTy $2 }
| '(' ctype ')' { LL $ HsParTy $2 }
- | '(' ctype '::' kind ')' { LL $ HsKindSig $2 $4 }
+ | '(' ctype '::' kind ')' { LL $ HsKindSig $2 (unLoc $4) }
-- Generics
| INTEGER { L1 (HsNumTy (getINTEGER $1)) }
tv_bndr :: { LHsTyVarBndr RdrName }
: tyvar { L1 (UserTyVar (unLoc $1)) }
- | '(' tyvar '::' kind ')' { LL (KindedTyVar (unLoc $2) $4) }
+ | '(' tyvar '::' kind ')' { LL (KindedTyVar (unLoc $2)
+ (unLoc $4)) }
fds :: { Located [Located ([RdrName], [RdrName])] }
: {- empty -} { noLoc [] }
-----------------------------------------------------------------------------
-- Kinds
-kind :: { Kind }
+kind :: { Located Kind }
: akind { $1 }
- | akind '->' kind { mkArrowKind $1 $3 }
+ | akind '->' kind { LL (mkArrowKind (unLoc $1) (unLoc $3)) }
-akind :: { Kind }
- : '*' { liftedTypeKind }
- | '!' { unliftedTypeKind }
- | '(' kind ')' { $2 }
+akind :: { Located Kind }
+ : '*' { L1 liftedTypeKind }
+ | '!' { L1 unliftedTypeKind }
+ | '(' kind ')' { LL (unLoc $2) }
-----------------------------------------------------------------------------
-- XXX revisit audreyt
| constr_stuff_record '::' sigtype
{ let (con,details) = unLoc $1 in
- LL (ConDecl con Implicit [] (noLoc []) details (ResTyGADT $3)) }
+ LL (ConDecl con Implicit [] (noLoc []) details (ResTyGADT $3) Nothing) }
{-
| forall context '=>' constr_stuff_record '::' sigtype
{ let (con,details) = unLoc $4 in
- LL (ConDecl con Implicit (unLoc $1) $2 details (ResTyGADT $6)) }
+ LL (ConDecl con Implicit (unLoc $1) $2 details (ResTyGADT $6) Nothing ) }
| forall constr_stuff_record '::' sigtype
{ let (con,details) = unLoc $2 in
- LL (ConDecl con Implicit (unLoc $1) (noLoc []) details (ResTyGADT $4)) }
+ LL (ConDecl con Implicit (unLoc $1) (noLoc []) details (ResTyGADT $4) Nothing) }
-}
constrs :: { Located [LConDecl RdrName] }
: {- empty; a GHC extension -} { noLoc [] }
- | '=' constrs1 { LL (unLoc $2) }
+ | maybe_docnext '=' constrs1 { L (comb2 $2 $3) (addConDocs (unLoc $3) $1) }
constrs1 :: { Located [LConDecl RdrName] }
- : constrs1 '|' constr { LL ($3 : unLoc $1) }
- | constr { L1 [$1] }
+ : constrs1 maybe_docnext '|' maybe_docprev constr { LL (addConDoc $5 $2 : addConDocFirst (unLoc $1) $4) }
+ | constr { L1 [$1] }
constr :: { LConDecl RdrName }
- : forall context '=>' constr_stuff
- { let (con,details) = unLoc $4 in
- LL (ConDecl con Explicit (unLoc $1) $2 details ResTyH98) }
- | forall constr_stuff
- { let (con,details) = unLoc $2 in
- LL (ConDecl con Explicit (unLoc $1) (noLoc []) details ResTyH98) }
+ : maybe_docnext forall context '=>' constr_stuff maybe_docprev
+ { let (con,details) = unLoc $5 in
+ L (comb4 $2 $3 $4 $5) (ConDecl con Explicit (unLoc $2) $3 details ResTyH98 ($1 `mplus` $6)) }
+ | maybe_docnext forall constr_stuff maybe_docprev
+ { let (con,details) = unLoc $3 in
+ L (comb2 $2 $3) (ConDecl con Explicit (unLoc $2) (noLoc []) details ResTyH98 ($1 `mplus` $4)) }
forall :: { Located [LHsTyVarBndr RdrName] }
: 'forall' tv_bndrs '.' { LL $2 }
| {- empty -} { noLoc [] }
-constr_stuff :: { Located (Located RdrName, HsConDetails RdrName (LBangType RdrName)) }
+constr_stuff :: { Located (Located RdrName, HsConDeclDetails RdrName) }
-- We parse the constructor declaration
-- C t1 t2
-- as a btype (treating C as a type constructor) and then convert C to be
| oqtycon '{' fielddecls '}' {% mkRecCon $1 $3 >>= return.LL }
| btype conop btype { LL ($2, InfixCon $1 $3) }
-constr_stuff_record :: { Located (Located RdrName, HsConDetails RdrName (LBangType RdrName)) }
+constr_stuff_record :: { Located (Located RdrName, HsConDeclDetails RdrName) }
: oqtycon '{' '}' {% mkRecCon $1 [] >>= return.sL (comb2 $1 $>) }
| oqtycon '{' fielddecls '}' {% mkRecCon $1 $3 >>= return.sL (comb2 $1 $>) }
-fielddecls :: { [([Located RdrName], LBangType RdrName)] }
- : fielddecl ',' fielddecls { unLoc $1 : $3 }
- | fielddecl { [unLoc $1] }
+fielddecls :: { [([Located RdrName], LBangType RdrName, Maybe (LHsDoc RdrName))] }
+ : fielddecl maybe_docnext ',' maybe_docprev fielddecls { addFieldDoc (unLoc $1) $4 : addFieldDocs $5 $2 }
+ | fielddecl { [unLoc $1] }
-fielddecl :: { Located ([Located RdrName], LBangType RdrName) }
- : sig_vars '::' ctype { LL (reverse (unLoc $1), $3) }
+fielddecl :: { Located ([Located RdrName], LBangType RdrName, Maybe (LHsDoc RdrName)) }
+ : maybe_docnext sig_vars '::' ctype maybe_docprev { L (comb3 $2 $3 $4) (reverse (unLoc $2), $4, $1 `mplus` $5) }
-- We allow the odd-looking 'inst_type' in a deriving clause, so that
-- we can do deriving( forall a. C [a] ) in a newtype (GHC extension).
We can't tell whether to reduce var to qvar until after we've read the signatures.
-}
+docdecl :: { LHsDecl RdrName }
+ : docdecld { L1 (DocD (unLoc $1)) }
+
+docdecld :: { LDocDecl RdrName }
+ : docnext { L1 (DocCommentNext (unLoc $1)) }
+ | docprev { L1 (DocCommentPrev (unLoc $1)) }
+ | docnamed { L1 (case (unLoc $1) of (n, doc) -> DocCommentNamed n doc) }
+ | docsection { L1 (case (unLoc $1) of (n, doc) -> DocGroup n doc) }
+
decl :: { Located (OrdList (LHsDecl RdrName)) }
: sigdecl { $1 }
- | '!' infixexp rhs {% do { pat <- checkPattern $2;
- return (LL $ unitOL $ LL $ ValD $
+ | '!' aexp rhs {% do { pat <- checkPattern $2;
+ return (LL $ unitOL $ LL $ ValD (
PatBind (LL $ BangPat pat) (unLoc $3)
- placeHolderType placeHolderNames) } }
+ placeHolderType placeHolderNames)) } }
| infixexp opt_sig rhs {% do { r <- checkValDef $1 $2 $3;
return (LL $ unitOL (LL $ ValD r)) } }
+ | docdecl { LL $ unitOL $1 }
rhs :: { Located (GRHSs RdrName) }
: '=' exp wherebinds { L (comb3 $1 $2 $3) $ GRHSs (unguardedRHS $2) (unLoc $3) }
: '|' quals '=' exp { sL (comb2 $1 $>) $ GRHS (reverse (unLoc $2)) $4 }
sigdecl :: { Located (OrdList (LHsDecl RdrName)) }
- : infixexp '::' sigtype
+ : infixexp '::' sigtypedoc
{% do s <- checkValSig $1 $3;
return (LL $ unitOL (LL $ SigD s)) }
-- See the above notes for why we need infixexp here
- | var ',' sig_vars '::' sigtype
+ | var ',' sig_vars '::' sigtypedoc
{ LL $ toOL [ LL $ SigD (TypeSig n $5) | n <- $1 : unLoc $3 ] }
| infix prec ops { LL $ toOL [ LL $ SigD (FixSig (FixitySig n (Fixity $2 (unLoc $1))))
| n <- unLoc $3 ] }
| '{-# INLINE' activation qvar '#-}'
{ LL $ unitOL (LL $ SigD (InlineSig $3 (mkInlineSpec $2 (getINLINE $1)))) }
| '{-# SPECIALISE' qvar '::' sigtypes1 '#-}'
- { LL $ toOL [ LL $ SigD (SpecSig $2 t defaultInlineSpec)
+ { LL $ toOL [ LL $ SigD (SpecSig $2 t defaultInlineSpec)
| t <- $4] }
| '{-# SPECIALISE_INLINE' activation qvar '::' sigtypes1 '#-}'
{ LL $ toOL [ LL $ SigD (SpecSig $3 t (mkInlineSpec $2 (getSPEC_INLINE $1)))
| infixexp qop exp10 { LL (OpApp $1 $2 (panic "fixity") $3) }
exp10 :: { LHsExpr RdrName }
- : '\\' aexp aexps opt_asig '->' exp
- {% checkPatterns ($2 : reverse $3) >>= \ ps ->
- return (LL $ HsLam (mkMatchGroup [LL $ Match ps $4
- (GRHSs (unguardedRHS $6) emptyLocalBinds
- )])) }
+ : '\\' apat apats opt_asig '->' exp
+ { LL $ HsLam (mkMatchGroup [LL $ Match ($2:$3) $4
+ (unguardedGRHSs $6)
+ ]) }
| 'let' binds 'in' exp { LL $ HsLet (unLoc $2) $4 }
| 'if' exp 'then' exp 'else' exp { LL $ HsIf $2 $4 $6 }
| 'case' exp 'of' altslist { LL $ HsCase $2 (mkMatchGroup (unLoc $4)) }
- | '-' fexp { LL $ mkHsNegApp $2 }
+ | '-' fexp { LL $ NegApp $2 noSyntaxExpr }
| 'do' stmtlist {% let loc = comb2 $1 $2 in
checkDo loc (unLoc $2) >>= \ (stmts,body) ->
| scc_annot exp { LL $ if opt_SccProfilingOn
then HsSCC (unLoc $1) $2
else HsPar $2 }
+ | hpc_annot exp { LL $ if opt_Hpc
+ then HsTickPragma (unLoc $1) $2
+ else HsPar $2 }
| 'proc' aexp '->' exp
{% checkPattern $2 >>= \ p ->
: '_scc_' STRING { LL $ getSTRING $2 }
| '{-# SCC' STRING '#-}' { LL $ getSTRING $2 }
+hpc_annot :: { Located (FastString,(Int,Int),(Int,Int)) }
+ : '{-# GENERATED' STRING INTEGER ':' INTEGER '-' INTEGER ':' INTEGER '#-}'
+ { LL $ (getSTRING $2
+ ,( fromInteger $ getINTEGER $3
+ , fromInteger $ getINTEGER $5
+ )
+ ,( fromInteger $ getINTEGER $7
+ , fromInteger $ getINTEGER $9
+ )
+ )
+ }
+
fexp :: { LHsExpr RdrName }
: fexp aexp { LL $ HsApp $1 $2 }
| aexp { $1 }
-aexps :: { [LHsExpr RdrName] }
- : aexps aexp { $2 : $1 }
- | {- empty -} { [] }
-
aexp :: { LHsExpr RdrName }
: qvar '@' aexp { LL $ EAsPat $1 $3 }
| '~' aexp { LL $ ELazyPat $2 }
--- | '!' aexp { LL $ EBangPat $2 }
| aexp1 { $1 }
aexp1 :: { LHsExpr RdrName }
- : aexp1 '{' fbinds '}' {% do { r <- mkRecConstrOrUpdate $1 (comb2 $2 $4)
- (reverse $3);
- return (LL r) }}
+ : aexp1 '{' fbinds '}' {% do { r <- mkRecConstrOrUpdate $1 (comb2 $2 $4) $3
+ ; return (LL r) }}
| aexp2 { $1 }
-- Here was the syntax for type applications that I was planning
: ipvar { L1 (HsIPVar $! unLoc $1) }
| qcname { L1 (HsVar $! unLoc $1) }
| literal { L1 (HsLit $! unLoc $1) }
+-- This will enable overloaded strings permanently. Normally the renamer turns HsString
+-- into HsOverLit when -foverloaded-strings is on.
+-- | STRING { L1 (HsOverLit $! mkHsIsString (getSTRING $1)) }
| INTEGER { L1 (HsOverLit $! mkHsIntegral (getINTEGER $1)) }
| RATIONAL { L1 (HsOverLit $! mkHsFractional (getRATIONAL $1)) }
| '(' exp ')' { LL (HsPar $2) }
| '[|' exp '|]' { LL $ HsBracket (ExpBr $2) }
| '[t|' ctype '|]' { LL $ HsBracket (TypBr $2) }
| '[p|' infixexp '|]' {% checkPattern $2 >>= \p ->
- return (LL $ HsBracket (PatBr p)) }
- | '[d|' cvtopbody '|]' { LL $ HsBracket (DecBr (mkGroup $2)) }
+ return (LL $ HsBracket (PatBr p)) }
+ | '[d|' cvtopbody '|]' {% checkDecBrGroup $2 >>= \g ->
+ return (LL $ HsBracket (DecBr g)) }
-- arrow notation extension
| '(|' aexp2 cmdargs '|)' { LL $ HsArrForm $2 Nothing (reverse $3) }
parr :: { LHsExpr RdrName }
: { noLoc (ExplicitPArr placeHolderType []) }
- | exp { L1 $ ExplicitPArr placeHolderType [$1] }
+ | texp { L1 $ ExplicitPArr placeHolderType [$1] }
| lexps { L1 $ ExplicitPArr placeHolderType
(reverse (unLoc $1)) }
- | exp '..' exp { LL $ PArrSeq noPostTcExpr (FromTo $1 $3) }
- | exp ',' exp '..' exp { LL $ PArrSeq noPostTcExpr (FromThenTo $1 $3 $5) }
- | exp pquals { sL (comb2 $1 $>) $ mkHsDo PArrComp (reverse (unLoc $2)) $1 }
+ | texp '..' exp { LL $ PArrSeq noPostTcExpr (FromTo $1 $3) }
+ | texp ',' exp '..' exp { LL $ PArrSeq noPostTcExpr (FromThenTo $1 $3 $5) }
+ | texp pquals { sL (comb2 $1 $>) $ mkHsDo PArrComp (reverse (unLoc $2)) $1 }
-- We are reusing `lexps' and `pquals' from the list case.
| alt { L1 [$1] }
alt :: { LMatch RdrName }
- : infixexp opt_sig alt_rhs {% checkPattern $1 >>= \p ->
- return (LL (Match [p] $2 (unLoc $3))) }
+ : pat opt_sig alt_rhs { LL (Match [$1] $2 (unLoc $3)) }
alt_rhs :: { Located (GRHSs RdrName) }
: ralt wherebinds { LL (GRHSs (unLoc $1) (unLoc $2)) }
gdpat :: { LGRHS RdrName }
: '|' quals '->' exp { sL (comb2 $1 $>) $ GRHS (reverse (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 RdrName }
+pat : exp {% checkPattern $1 }
+ | '!' aexp {% checkPattern (LL (SectionR (L1 (HsVar bang_RDR)) $2)) }
+
+apat :: { LPat RdrName }
+apat : aexp {% checkPattern $1 }
+ | '!' aexp {% checkPattern (LL (SectionR (L1 (HsVar bang_RDR)) $2)) }
+
+apats :: { [LPat RdrName] }
+ : apat apats { $1 : $2 }
+ | {- empty -} { [] }
+
-----------------------------------------------------------------------------
-- Statement sequences
stmt :: { LStmt RdrName }
: qual { $1 }
+-- What is this next production doing? I have no clue! SLPJ Dec06
| infixexp '->' exp {% checkPattern $3 >>= \p ->
return (LL $ mkBindStmt p $1) }
| 'rec' stmtlist { LL $ mkRecStmt (unLoc $2) }
qual :: { LStmt RdrName }
- : exp '<-' exp {% checkPattern $1 >>= \p ->
- return (LL $ mkBindStmt p $3) }
+ : pat '<-' exp { LL $ mkBindStmt $1 $3 }
| exp { L1 $ mkExprStmt $1 }
| 'let' binds { LL $ LetStmt (unLoc $2) }
-----------------------------------------------------------------------------
-- Record Field Update/Construction
-fbinds :: { HsRecordBinds RdrName }
+fbinds :: { ([HsRecField RdrName (LHsExpr RdrName)], Bool) }
: fbinds1 { $1 }
- | {- empty -} { [] }
+ | {- empty -} { ([], False) }
-fbinds1 :: { HsRecordBinds RdrName }
- : fbinds1 ',' fbind { $3 : $1 }
- | fbind { [$1] }
+fbinds1 :: { ([HsRecField RdrName (LHsExpr RdrName)], Bool) }
+ : fbind ',' fbinds1 { case $3 of (flds, dd) -> ($1 : flds, dd) }
+ | fbind { ([$1], False) }
+ | '..' { ([], True) }
-fbind :: { (Located RdrName, LHsExpr RdrName) }
- : qvar '=' exp { ($1,$3) }
+fbind :: { HsRecField RdrName (LHsExpr RdrName) }
+ : qvar '=' exp { HsRecField $1 $3 False }
+ | qvar { HsRecField $1 (L (getLoc $1) (HsVar (unLoc $1))) True }
+ -- Here's where we say that plain 'x'
+ -- means exactly 'x = x'. The pun-flag boolean is
+ -- there so we can still print it right
-----------------------------------------------------------------------------
-- Implicit Parameter Bindings
dbind : ipvar '=' exp { LL (IPBind (unLoc $1) $3) }
ipvar :: { Located (IPName RdrName) }
- : IPDUPVARID { L1 (Dupable (mkUnqual varName (getIPDUPVARID $1))) }
- | IPSPLITVARID { L1 (Linear (mkUnqual varName (getIPSPLITVARID $1))) }
+ : IPDUPVARID { L1 (IPName (mkUnqual varName (getIPDUPVARID $1))) }
-----------------------------------------------------------------------------
-- Deprecations
: VARID { L1 $! mkUnqual varName (getVARID $1) }
| special_id { L1 $! mkUnqual varName (unLoc $1) }
| 'forall' { L1 $! mkUnqual varName FSLIT("forall") }
+ | 'family' { L1 $! mkUnqual varName FSLIT("family") }
qvarsym :: { Located RdrName }
: varsym { $1 }
-- These special_ids are treated as keywords in various places,
-- but as ordinary ids elsewhere. 'special_id' collects all these
--- except 'unsafe' and 'forall' whose treatment differs depending on context
+-- except 'unsafe', 'forall', and 'family' whose treatment differs
+-- depending on context
special_id :: { Located FastString }
special_id
: 'as' { L1 FSLIT("as") }
| 'qualified' { L1 FSLIT("qualified") }
| 'hiding' { L1 FSLIT("hiding") }
+ | 'derive' { L1 FSLIT("derive") }
| 'export' { L1 FSLIT("export") }
| 'label' { L1 FSLIT("label") }
| 'dynamic' { L1 FSLIT("dynamic") }
literal :: { Located HsLit }
: CHAR { L1 $ HsChar $ getCHAR $1 }
- | STRING { L1 $ HsString $ getSTRING $1 }
+ | STRING { L1 $ HsString $ getSTRING $1 }
| PRIMINTEGER { L1 $ HsIntPrim $ getPRIMINTEGER $1 }
| PRIMCHAR { L1 $ HsCharPrim $ getPRIMCHAR $1 }
| PRIMSTRING { L1 $ HsStringPrim $ getPRIMSTRING $1 }
| ',' { 2 }
-----------------------------------------------------------------------------
+-- Documentation comments
+
+docnext :: { LHsDoc RdrName }
+ : DOCNEXT {% case parseHaddockParagraphs (tokenise (getDOCNEXT $1)) of {
+ Left err -> parseError (getLoc $1) err;
+ Right doc -> return (L1 doc) } }
+
+docprev :: { LHsDoc RdrName }
+ : DOCPREV {% case parseHaddockParagraphs (tokenise (getDOCPREV $1)) of {
+ Left err -> parseError (getLoc $1) err;
+ Right doc -> return (L1 doc) } }
+
+docnamed :: { Located (String, (HsDoc RdrName)) }
+ : DOCNAMED {%
+ let string = getDOCNAMED $1
+ (name, rest) = break isSpace string
+ in case parseHaddockParagraphs (tokenise rest) of {
+ Left err -> parseError (getLoc $1) err;
+ Right doc -> return (L1 (name, doc)) } }
+
+docsection :: { Located (n, HsDoc RdrName) }
+ : DOCSECTION {% let (n, doc) = getDOCSECTION $1 in
+ case parseHaddockString (tokenise doc) of {
+ Left err -> parseError (getLoc $1) err;
+ Right doc -> return (L1 (n, doc)) } }
+
+docoptions :: { String }
+ : DOCOPTIONS { getDOCOPTIONS $1 }
+
+moduleheader :: { (HaddockModInfo RdrName, Maybe (HsDoc RdrName)) }
+ : DOCNEXT {% let string = getDOCNEXT $1 in
+ case parseModuleHeader string of {
+ Right (str, info) ->
+ case parseHaddockParagraphs (tokenise str) of {
+ Left err -> parseError (getLoc $1) err;
+ Right doc -> return (info, Just doc);
+ };
+ Left err -> parseError (getLoc $1) err
+ } }
+
+maybe_docprev :: { Maybe (LHsDoc RdrName) }
+ : docprev { Just $1 }
+ | {- empty -} { Nothing }
+
+maybe_docnext :: { Maybe (LHsDoc RdrName) }
+ : docnext { Just $1 }
+ | {- empty -} { Nothing }
{
happyError :: P a
getQVARSYM (L _ (ITqvarsym x)) = x
getQCONSYM (L _ (ITqconsym x)) = x
getIPDUPVARID (L _ (ITdupipvarid x)) = x
-getIPSPLITVARID (L _ (ITsplitipvarid x)) = x
getCHAR (L _ (ITchar x)) = x
getSTRING (L _ (ITstring x)) = x
getINTEGER (L _ (ITinteger x)) = x
getINLINE (L _ (ITinline_prag b)) = b
getSPEC_INLINE (L _ (ITspec_inline_prag b)) = b
+getDOCNEXT (L _ (ITdocCommentNext x)) = x
+getDOCPREV (L _ (ITdocCommentPrev x)) = x
+getDOCNAMED (L _ (ITdocCommentNamed x)) = x
+getDOCSECTION (L _ (ITdocSection n x)) = (n, x)
+getDOCOPTIONS (L _ (ITdocOptions x)) = x
+
-- Utilities for combining source spans
comb2 :: Located a -> Located b -> SrcSpan
comb2 = combineLocs