{-# OPTIONS -cpp #-} ------------------------------------------------------------------ -- A primop-table mangling program -- ------------------------------------------------------------------ module Main where #if __GLASGOW_HASKELL__ >= 504 import Text.ParserCombinators.Parsec #else import Parsec #endif import Monad import Char import List import System ( getArgs ) import Maybe ( catMaybes ) main :: IO () main = getArgs >>= \args -> if length args /= 1 || head args `notElem` known_args then error ("usage: genprimopcode command < primops.txt > ...\n" ++ " where command is one of\n" ++ unlines (map (" "++) known_args) ) else do s <- getContents let pres = parse pTop "" s case pres of Left err -> error ("parse error at " ++ (show err)) Right p_o_specs -> myseq (sanityTop p_o_specs) ( case head args of "--data-decl" -> putStr (gen_data_decl p_o_specs) "--has-side-effects" -> putStr (gen_switch_from_attribs "has_side_effects" "primOpHasSideEffects" p_o_specs) "--out-of-line" -> putStr (gen_switch_from_attribs "out_of_line" "primOpOutOfLine" p_o_specs) "--commutable" -> putStr (gen_switch_from_attribs "commutable" "commutableOp" p_o_specs) "--needs-wrapper" -> putStr (gen_switch_from_attribs "needs_wrapper" "primOpNeedsWrapper" p_o_specs) "--can-fail" -> putStr (gen_switch_from_attribs "can_fail" "primOpCanFail" p_o_specs) "--strictness" -> putStr (gen_switch_from_attribs "strictness" "primOpStrictness" p_o_specs) "--usage" -> putStr (gen_switch_from_attribs "usage" "primOpUsg" p_o_specs) "--enabled" -> putStr (gen_switch_from_attribs "enabled" "primOpEnabled" p_o_specs) "--primop-primop-info" -> putStr (gen_primop_info p_o_specs) "--primop-tag" -> putStr (gen_primop_tag p_o_specs) "--primop-list" -> putStr (gen_primop_list p_o_specs) "--make-haskell-wrappers" -> putStr (gen_wrappers p_o_specs) "--make-haskell-source" -> putStr (gen_hs_source p_o_specs) "--make-latex-doc" -> putStr (gen_latex_doc p_o_specs) _ -> error "Should not happen, known_args out of sync?" ) known_args :: [String] known_args = [ "--data-decl", "--has-side-effects", "--out-of-line", "--commutable", "--needs-wrapper", "--can-fail", "--strictness", "--usage", "--enabled", "--primop-primop-info", "--primop-tag", "--primop-list", "--make-haskell-wrappers", "--make-haskell-source", "--make-latex-doc" ] ------------------------------------------------------------------ -- Code generators ----------------------------------------------- ------------------------------------------------------------------ gen_hs_source :: Info -> String gen_hs_source (Info defaults entries) = "-----------------------------------------------------------------------------\n" ++ "-- |\n" ++ "-- Module : GHC.Arr\n" ++ "-- \n" ++ "-- Maintainer : cvs-ghc@haskell.org\n" ++ "-- Stability : internal\n" ++ "-- Portability : non-portable (GHC extensions)\n" ++ "--\n" ++ "-- GHC\'s primitive types and operations.\n" ++ "--\n" ++ "-----------------------------------------------------------------------------\n" ++ "module GHC.Prim (\n" ++ unlines (map (("\t" ++) . hdr) entries) ++ ") where\n\n{-\n" ++ unlines (map opt defaults) ++ "-}\n" ++ unlines (map ent entries) ++ "\n\n\n" where opt (OptionFalse n) = n ++ " = False" opt (OptionTrue n) = n ++ " = True" opt (OptionString n v) = n ++ " = { " ++ v ++ "}" hdr s@(Section {}) = sec s hdr (PrimOpSpec { name = n }) = wrapOp n ++ "," hdr (PseudoOpSpec { name = n }) = wrapOp n ++ "," hdr (PrimTypeSpec { ty = TyApp n _ }) = wrapTy n ++ "," hdr (PrimTypeSpec {}) = error "Illegal type spec" ent (Section {}) = "" ent o@(PrimOpSpec {}) = spec o ent o@(PrimTypeSpec {}) = spec o ent o@(PseudoOpSpec {}) = spec o sec s = "\n-- * " ++ escape (title s) ++ "\n" ++ (unlines $ map ("-- " ++ ) $ lines $ unlatex $ escape $ "|" ++ desc s) ++ "\n" spec o = comm ++ decl where decl = case o of PrimOpSpec { name = n, ty = t } -> wrapOp n ++ " :: " ++ pty t PseudoOpSpec { name = n, ty = t } -> wrapOp n ++ " :: " ++ pty t PrimTypeSpec { ty = t } -> "data " ++ pty t Section { } -> "" comm = case (desc o) of [] -> "" d -> "\n" ++ (unlines $ map ("-- " ++ ) $ lines $ unlatex $ escape $ "|" ++ d) pty (TyF t1 t2) = pbty t1 ++ " -> " ++ pty t2 pty t = pbty t pbty (TyApp tc ts) = tc ++ (concat (map (' ':) (map paty ts))) pbty (TyUTup ts) = "(# " ++ (concat (intersperse "," (map pty ts))) ++ " #)" pbty t = paty t paty (TyVar tv) = tv paty t = "(" ++ pty t ++ ")" wrapOp nm | isAlpha (head nm) = nm | otherwise = "(" ++ nm ++ ")" wrapTy nm | isAlpha (head nm) = nm | otherwise = "(" ++ nm ++ ")" unlatex s = case s of '\\':'t':'e':'x':'t':'t':'t':'{':cs -> markup "@" "@" cs '{':'\\':'t':'t':cs -> markup "@" "@" cs '{':'\\':'i':'t':cs -> markup "/" "/" cs c : cs -> c : unlatex cs [] -> [] markup s t xs = s ++ mk (dropWhile isSpace xs) where mk "" = t mk ('\n':cs) = ' ' : mk cs mk ('}':cs) = t ++ unlatex cs mk (c:cs) = c : mk cs escape = concatMap (\c -> if c `elem` special then '\\':c:[] else c:[]) where special = "/'`\"@<" gen_latex_doc :: Info -> String gen_latex_doc (Info defaults entries) = "\\primopdefaults{" ++ mk_options defaults ++ "}\n" ++ (concat (map mk_entry entries)) where mk_entry (PrimOpSpec {cons=constr,name=n,ty=t,cat=c,desc=d,opts=o}) = "\\primopdesc{" ++ latex_encode constr ++ "}{" ++ latex_encode n ++ "}{" ++ latex_encode (zencode n) ++ "}{" ++ latex_encode (show c) ++ "}{" ++ latex_encode (mk_source_ty t) ++ "}{" ++ latex_encode (mk_core_ty t) ++ "}{" ++ d ++ "}{" ++ mk_options o ++ "}\n" mk_entry (Section {title=ti,desc=d}) = "\\primopsection{" ++ latex_encode ti ++ "}{" ++ d ++ "}\n" mk_entry (PrimTypeSpec {ty=t,desc=d,opts=o}) = "\\primtypespec{" ++ latex_encode (mk_source_ty t) ++ "}{" ++ latex_encode (mk_core_ty t) ++ "}{" ++ d ++ "}{" ++ mk_options o ++ "}\n" mk_entry (PseudoOpSpec {name=n,ty=t,desc=d,opts=o}) = "\\pseudoopspec{" ++ latex_encode (zencode n) ++ "}{" ++ latex_encode (mk_source_ty t) ++ "}{" ++ latex_encode (mk_core_ty t) ++ "}{" ++ d ++ "}{" ++ mk_options o ++ "}\n" mk_source_ty typ = pty typ where pty (TyF t1 t2) = pbty t1 ++ " -> " ++ pty t2 pty t = pbty t pbty (TyApp tc ts) = tc ++ (concat (map (' ':) (map paty ts))) pbty (TyUTup ts) = "(# " ++ (concat (intersperse "," (map pty ts))) ++ " #)" pbty t = paty t paty (TyVar tv) = tv paty t = "(" ++ pty t ++ ")" mk_core_ty typ = foralls ++ (pty typ) where pty (TyF t1 t2) = pbty t1 ++ " -> " ++ pty t2 pty t = pbty t pbty (TyApp tc ts) = (zencode tc) ++ (concat (map (' ':) (map paty ts))) pbty (TyUTup ts) = (zencode (utuplenm (length ts))) ++ (concat ((map (' ':) (map paty ts)))) pbty t = paty t paty (TyVar tv) = zencode tv paty (TyApp tc []) = zencode tc paty t = "(" ++ pty t ++ ")" utuplenm 1 = "(# #)" utuplenm n = "(#" ++ (replicate (n-1) ',') ++ "#)" foralls = if tvars == [] then "" else "%forall " ++ (tbinds tvars) tvars = tvars_of typ tbinds [] = ". " tbinds ("o":tbs) = "(o::?) " ++ (tbinds tbs) tbinds (tv:tbs) = tv ++ " " ++ (tbinds tbs) tvars_of (TyF t1 t2) = tvars_of t1 `union` tvars_of t2 tvars_of (TyApp _ ts) = foldl union [] (map tvars_of ts) tvars_of (TyUTup ts) = foldr union [] (map tvars_of ts) tvars_of (TyVar tv) = [tv] mk_options o = "\\primoptions{" ++ mk_has_side_effects o ++ "}{" ++ mk_out_of_line o ++ "}{" ++ mk_commutable o ++ "}{" ++ mk_needs_wrapper o ++ "}{" ++ mk_can_fail o ++ "}{" ++ latex_encode (mk_strictness o) ++ "}{" ++ latex_encode (mk_usage o) ++ "}" mk_has_side_effects o = mk_bool_opt o "has_side_effects" "Has side effects." "Has no side effects." mk_out_of_line o = mk_bool_opt o "out_of_line" "Implemented out of line." "Implemented in line." mk_commutable o = mk_bool_opt o "commutable" "Commutable." "Not commutable." mk_needs_wrapper o = mk_bool_opt o "needs_wrapper" "Needs wrapper." "Needs no wrapper." mk_can_fail o = mk_bool_opt o "can_fail" "Can fail." "Cannot fail." mk_bool_opt o opt_name if_true if_false = case lookup_attrib opt_name o of Just (OptionTrue _) -> if_true Just (OptionFalse _) -> if_false Just (OptionString _ _) -> error "String value for boolean option" Nothing -> "" mk_strictness o = case lookup_attrib "strictness" o of Just (OptionString _ s) -> s -- for now Just _ -> error "Boolean value for strictness" Nothing -> "" mk_usage o = case lookup_attrib "usage" o of Just (OptionString _ s) -> s -- for now Just _ -> error "Boolean value for usage" Nothing -> "" zencode xs = case maybe_tuple xs of Just n -> n -- Tuples go to Z2T etc Nothing -> concat (map encode_ch xs) where maybe_tuple "(# #)" = Just("Z1H") maybe_tuple ('(' : '#' : cs) = case count_commas (0::Int) cs of (n, '#' : ')' : _) -> Just ('Z' : shows (n+1) "H") _ -> Nothing maybe_tuple "()" = Just("Z0T") maybe_tuple ('(' : cs) = case count_commas (0::Int) cs of (n, ')' : _) -> Just ('Z' : shows (n+1) "T") _ -> Nothing maybe_tuple _ = Nothing count_commas :: Int -> String -> (Int, String) count_commas n (',' : cs) = count_commas (n+1) cs count_commas n cs = (n,cs) unencodedChar :: Char -> Bool -- True for chars that don't need encoding unencodedChar 'Z' = False unencodedChar 'z' = False unencodedChar c = isAlphaNum c encode_ch :: Char -> String encode_ch c | unencodedChar c = [c] -- Common case first -- Constructors encode_ch '(' = "ZL" -- Needed for things like (,), and (->) encode_ch ')' = "ZR" -- For symmetry with ( encode_ch '[' = "ZM" encode_ch ']' = "ZN" encode_ch ':' = "ZC" encode_ch 'Z' = "ZZ" -- Variables encode_ch 'z' = "zz" encode_ch '&' = "za" encode_ch '|' = "zb" encode_ch '^' = "zc" encode_ch '$' = "zd" encode_ch '=' = "ze" encode_ch '>' = "zg" encode_ch '#' = "zh" encode_ch '.' = "zi" encode_ch '<' = "zl" encode_ch '-' = "zm" encode_ch '!' = "zn" encode_ch '+' = "zp" encode_ch '\'' = "zq" encode_ch '\\' = "zr" encode_ch '/' = "zs" encode_ch '*' = "zt" encode_ch '_' = "zu" encode_ch '%' = "zv" encode_ch c = 'z' : shows (ord c) "U" latex_encode [] = [] latex_encode (c:cs) | c `elem` "#$%&_^{}" = "\\" ++ c:(latex_encode cs) latex_encode ('~':cs) = "\\verb!~!" ++ (latex_encode cs) latex_encode ('\\':cs) = "$\\backslash$" ++ (latex_encode cs) latex_encode (c:cs) = c:(latex_encode cs) gen_wrappers :: Info -> String gen_wrappers (Info _ entries) = "{-# OPTIONS -fno-implicit-prelude #-}\n" -- Dependencies on Prelude must be explicit in libraries/base, but we -- don't need the Prelude here so we add -fno-implicit-prelude. ++ "module GHC.PrimopWrappers where\n" ++ "import qualified GHC.Prim\n" ++ unlines (map f (filter (not.dodgy) (filter is_primop entries))) where f spec = let args = map (\n -> "a" ++ show n) [1 .. arity (ty spec)] src_name = wrap (name spec) in "{-# NOINLINE " ++ src_name ++ " #-}\n" ++ src_name ++ " " ++ unwords args ++ " = (GHC.Prim." ++ name spec ++ ") " ++ unwords args wrap nm | isLower (head nm) = nm | otherwise = "(" ++ nm ++ ")" dodgy spec = name spec `elem` [-- C code generator can't handle these "seq#", "tagToEnum#", -- not interested in parallel support "par#", "parGlobal#", "parLocal#", "parAt#", "parAtAbs#", "parAtRel#", "parAtForNow#" ] gen_primop_list :: Info -> String gen_primop_list (Info _ entries) = unlines ( [ " [" ++ cons first ] ++ map (\p -> " , " ++ cons p) rest ++ [ " ]" ] ) where (first:rest) = filter is_primop entries gen_primop_tag :: Info -> String gen_primop_tag (Info _ entries) = unlines (max_def : zipWith f primop_entries [1 :: Int ..]) where primop_entries = filter is_primop entries f i n = "tagOf_PrimOp " ++ cons i ++ " = _ILIT(" ++ show n ++ ") :: FastInt" max_def = "maxPrimOpTag = " ++ show (length primop_entries) ++ " :: Int" gen_data_decl :: Info -> String gen_data_decl (Info _ entries) = let conss = map cons (filter is_primop entries) in "data PrimOp\n = " ++ head conss ++ "\n" ++ unlines (map (" | "++) (tail conss)) gen_switch_from_attribs :: String -> String -> Info -> String gen_switch_from_attribs attrib_name fn_name (Info defaults entries) = let defv = lookup_attrib attrib_name defaults alternatives = catMaybes (map mkAlt (filter is_primop entries)) getAltRhs (OptionFalse _) = "False" getAltRhs (OptionTrue _) = "True" getAltRhs (OptionString _ s) = s mkAlt po = case lookup_attrib attrib_name (opts po) of Nothing -> Nothing Just xx -> Just (fn_name ++ " " ++ cons po ++ " = " ++ getAltRhs xx) in case defv of Nothing -> error ("gen_switch_from: " ++ attrib_name) Just xx -> unlines alternatives ++ fn_name ++ " other = " ++ getAltRhs xx ++ "\n" ------------------------------------------------------------------ -- Create PrimOpInfo text from PrimOpSpecs ----------------------- ------------------------------------------------------------------ gen_primop_info :: Info -> String gen_primop_info (Info _ entries) = unlines (map mkPOItext (filter is_primop entries)) mkPOItext :: Entry -> String mkPOItext i = mkPOI_LHS_text i ++ mkPOI_RHS_text i mkPOI_LHS_text :: Entry -> String mkPOI_LHS_text i = "primOpInfo " ++ cons i ++ " = " mkPOI_RHS_text :: Entry -> String mkPOI_RHS_text i = case cat i of Compare -> case ty i of TyF t1 (TyF _ _) -> "mkCompare " ++ sl_name i ++ ppType t1 _ -> error "Type error in comparison op" Monadic -> case ty i of TyF t1 _ -> "mkMonadic " ++ sl_name i ++ ppType t1 _ -> error "Type error in monadic op" Dyadic -> case ty i of TyF t1 (TyF _ _) -> "mkDyadic " ++ sl_name i ++ ppType t1 _ -> error "Type error in dyadic op" GenPrimOp -> let (argTys, resTy) = flatTys (ty i) in "mkGenPrimOp " ++ sl_name i ++ " " ++ listify (map ppType argTys) ++ " " ++ "(" ++ ppType resTy ++ ")" sl_name :: Entry -> String sl_name i = "FSLIT(\"" ++ name i ++ "\") " ppType :: Ty -> String ppType (TyApp "Int#" []) = "intPrimTy" ppType (TyApp "Int8#" []) = "int8PrimTy" ppType (TyApp "Int16#" []) = "int16PrimTy" ppType (TyApp "Int32#" []) = "int32PrimTy" ppType (TyApp "Int64#" []) = "int64PrimTy" ppType (TyApp "Char#" []) = "charPrimTy" ppType (TyApp "Word#" []) = "wordPrimTy" ppType (TyApp "Word8#" []) = "word8PrimTy" ppType (TyApp "Word16#" []) = "word16PrimTy" ppType (TyApp "Word32#" []) = "word32PrimTy" ppType (TyApp "Word64#" []) = "word64PrimTy" ppType (TyApp "Addr#" []) = "addrPrimTy" ppType (TyApp "Float#" []) = "floatPrimTy" ppType (TyApp "Double#" []) = "doublePrimTy" ppType (TyApp "RealWorld" []) = "realWorldTy" ppType (TyApp "ThreadId#" []) = "threadIdPrimTy" ppType (TyApp "ForeignObj#" []) = "foreignObjPrimTy" ppType (TyApp "Bool#" []) = "boolPrimTy" ppType (TyApp "BCO#" []) = "bcoPrimTy" ppType (TyApp "()" []) = "unitTy" -- unitTy is TysWiredIn's name for () ppType (TyVar "a") = "alphaTy" ppType (TyVar "b") = "betaTy" ppType (TyVar "c") = "gammaTy" ppType (TyVar "m") = "unboxedAlphaTy" ppType (TyVar "n") = "unboxedBetaTy" ppType (TyVar "o") = "argAlphaTy" ppType (TyVar "p") = "ptrAlphaTy" ppType (TyVar "q") = "ptrBetaTy" ppType (TyVar "s") = "deltaTy" ppType (TyVar "u") = "(mkTyVarTy (mkAlphaTyVars unliftedTypeKind !! 20))" ppType (TyApp "State#" [x]) = "mkStatePrimTy " ++ ppType x ppType (TyApp "MutVar#" [x,y]) = "mkMutVarPrimTy " ++ ppType x ++ " " ++ ppType y ppType (TyApp "MutArr#" [x,y]) = "mkMutableArrayPrimTy " ++ ppType x ++ " " ++ ppType y ppType (TyApp "MutUArr#" [x,y]) = "mkMutableUArrayPrimTy " ++ ppType x ++ " " ++ ppType y ppType (TyApp "Array#" [x]) = "mkArrayPrimTy " ++ ppType x ppType (TyApp "UArray#" [x]) = "mkUArrayPrimTy " ++ ppType x ppType (TyApp "Weak#" [x]) = "mkWeakPrimTy " ++ ppType x ppType (TyApp "StablePtr#" [x]) = "mkStablePtrPrimTy " ++ ppType x ppType (TyApp "StableName#" [x]) = "mkStableNamePrimTy " ++ ppType x ppType (TyApp "MVar#" [x,y]) = "mkMVarPrimTy " ++ ppType x ++ " " ++ ppType y ppType (TyApp "TVar#" [x,y]) = "mkTVarPrimTy " ++ ppType x ++ " " ++ ppType y ppType (TyUTup ts) = "(mkTupleTy Unboxed " ++ show (length ts) ++ " " ++ listify (map ppType ts) ++ ")" ppType (TyF s d) = "(mkFunTy (" ++ ppType s ++ ") (" ++ ppType d ++ "))" ppType other = error ("ppType: can't handle: " ++ show other ++ "\n") listify :: [String] -> String listify ss = "[" ++ concat (intersperse ", " ss) ++ "]" flatTys :: Ty -> ([Ty],Ty) flatTys (TyF t1 t2) = case flatTys t2 of (ts,t) -> (t1:ts,t) flatTys other = ([],other) tvsIn :: Ty -> [TyVar] tvsIn (TyF t1 t2) = tvsIn t1 ++ tvsIn t2 tvsIn (TyApp _ tys) = concatMap tvsIn tys tvsIn (TyVar tv) = [tv] tvsIn (TyUTup tys) = concatMap tvsIn tys arity :: Ty -> Int arity = length . fst . flatTys ------------------------------------------------------------------ -- Abstract syntax ----------------------------------------------- ------------------------------------------------------------------ -- info for all primops; the totality of the info in primops.txt(.pp) data Info = Info [Option] [Entry] -- defaults, primops deriving Show -- info for one primop data Entry = PrimOpSpec { cons :: String, -- PrimOp name name :: String, -- name in prog text ty :: Ty, -- type cat :: Category, -- category desc :: String, -- description opts :: [Option] } -- default overrides | PseudoOpSpec { name :: String, -- name in prog text ty :: Ty, -- type desc :: String, -- description opts :: [Option] } -- default overrides | PrimTypeSpec { ty :: Ty, -- name in prog text desc :: String, -- description opts :: [Option] } -- default overrides | Section { title :: String, -- section title desc :: String } -- description deriving Show is_primop :: Entry -> Bool is_primop (PrimOpSpec _ _ _ _ _ _) = True is_primop _ = False -- a binding of property to value data Option = OptionFalse String -- name = False | OptionTrue String -- name = True | OptionString String String -- name = { ... unparsed stuff ... } deriving Show -- categorises primops data Category = Dyadic | Monadic | Compare | GenPrimOp deriving Show -- types data Ty = TyF Ty Ty | TyApp TyCon [Ty] | TyVar TyVar | TyUTup [Ty] -- unboxed tuples; just a TyCon really, -- but convenient like this deriving (Eq,Show) type TyVar = String type TyCon = String ------------------------------------------------------------------ -- Sanity checking ----------------------------------------------- ------------------------------------------------------------------ {- Do some simple sanity checks: * all the default field names are unique * for each PrimOpSpec, all override field names are unique * for each PrimOpSpec, all overriden field names have a corresponding default value * that primop types correspond in certain ways to the Category: eg if Comparison, the type must be of the form T -> T -> Bool. Dies with "error" if there's a problem, else returns (). -} myseq :: () -> a -> a myseq () x = x myseqAll :: [()] -> a -> a myseqAll (():ys) x = myseqAll ys x myseqAll [] x = x sanityTop :: Info -> () sanityTop (Info defs entries) = let opt_names = map get_attrib_name defs primops = filter is_primop entries in if length opt_names /= length (nub opt_names) then error ("non-unique default attribute names: " ++ show opt_names ++ "\n") else myseqAll (map (sanityPrimOp opt_names) primops) () sanityPrimOp :: [String] -> Entry -> () sanityPrimOp def_names p = let p_names = map get_attrib_name (opts p) p_names_ok = length p_names == length (nub p_names) && all (`elem` def_names) p_names ty_ok = sane_ty (cat p) (ty p) in if not p_names_ok then error ("attribute names are non-unique or have no default in\n" ++ "info for primop " ++ cons p ++ "\n") else if not ty_ok then error ("type of primop " ++ cons p ++ " doesn't make sense w.r.t" ++ " category " ++ show (cat p) ++ "\n") else () sane_ty :: Category -> Ty -> Bool sane_ty Compare (TyF t1 (TyF t2 td)) | t1 == t2 && td == TyApp "Bool#" [] = True sane_ty Monadic (TyF t1 td) | t1 == td = True sane_ty Dyadic (TyF t1 (TyF t2 _)) | t1 == t2 && t2 == t2 = True sane_ty GenPrimOp _ = True sane_ty _ _ = False get_attrib_name :: Option -> String get_attrib_name (OptionFalse nm) = nm get_attrib_name (OptionTrue nm) = nm get_attrib_name (OptionString nm _) = nm lookup_attrib :: String -> [Option] -> Maybe Option lookup_attrib _ [] = Nothing lookup_attrib nm (a:as) = if get_attrib_name a == nm then Just a else lookup_attrib nm as ------------------------------------------------------------------ -- The parser ---------------------------------------------------- ------------------------------------------------------------------ keywords :: [String] keywords = [ "section", "primop", "pseudoop", "primtype", "with"] -- Due to lack of proper lexing facilities, a hack to zap any -- leading comments pTop :: Parser Info pTop = then4 (\_ ds es _ -> Info ds es) pCommentAndWhitespace pDefaults (many pEntry) (lit "thats_all_folks") pEntry :: Parser Entry pEntry = alts [pPrimOpSpec, pPrimTypeSpec, pPseudoOpSpec, pSection] pSection :: Parser Entry pSection = then3 (\_ n d -> Section {title = n, desc = d}) (lit "section") stringLiteral pDesc pDefaults :: Parser [Option] pDefaults = then2 sel22 (lit "defaults") (many pOption) pOption :: Parser Option pOption = alts [ then3 (\nm _ _ -> OptionFalse nm) pName (lit "=") (lit "False"), then3 (\nm _ _ -> OptionTrue nm) pName (lit "=") (lit "True"), then3 (\nm _ zz -> OptionString nm zz) pName (lit "=") pStuffBetweenBraces ] pPrimOpSpec :: Parser Entry pPrimOpSpec = then7 (\_ c n k t d o -> PrimOpSpec { cons = c, name = n, ty = t, cat = k, desc = d, opts = o } ) (lit "primop") pConstructor stringLiteral pCategory pType pDesc pOptions pPrimTypeSpec :: Parser Entry pPrimTypeSpec = then4 (\_ t d o -> PrimTypeSpec { ty = t, desc = d, opts = o } ) (lit "primtype") pType pDesc pOptions pPseudoOpSpec :: Parser Entry pPseudoOpSpec = then5 (\_ n t d o -> PseudoOpSpec { name = n, ty = t, desc = d, opts = o } ) (lit "pseudoop") stringLiteral pType pDesc pOptions pOptions :: Parser [Option] pOptions = pOptDef [] (then2 sel22 (lit "with") (many pOption)) pCategory :: Parser Category pCategory = alts [ apply (const Dyadic) (lit "Dyadic"), apply (const Monadic) (lit "Monadic"), apply (const Compare) (lit "Compare"), apply (const GenPrimOp) (lit "GenPrimOp") ] pDesc :: Parser String pDesc = pOptDef "" pStuffBetweenBraces pStuffBetweenBraces :: Parser String pStuffBetweenBraces = lexeme ( do char '{' ass <- many pInsides char '}' return (concat ass) ) pInsides :: Parser String pInsides = (do char '{' stuff <- many pInsides char '}' return ("{" ++ (concat stuff) ++ "}")) <|> (do c <- satisfy (/= '}') return [c]) ------------------- -- Parsing types -- ------------------- pType :: Parser Ty pType = then2 (\t maybe_tt -> case maybe_tt of Just tt -> TyF t tt Nothing -> t) paT (pOpt (then2 sel22 (lit "->") pType)) -- Atomic types paT :: Parser Ty paT = alts [ then2 TyApp pTycon (many ppT), pUnboxedTupleTy, then3 sel23 (lit "(") pType (lit ")"), ppT ] -- the magic bit in the middle is: T (,T)* so to speak pUnboxedTupleTy :: Parser Ty pUnboxedTupleTy = then3 (\ _ ts _ -> TyUTup ts) (lit "(#") (then2 (:) pType (many (then2 sel22 (lit ",") pType))) (lit "#)") -- Primitive types ppT :: Parser Ty ppT = alts [apply TyVar pTyvar, apply (\tc -> TyApp tc []) pTycon ] pTyvar :: Parser String pTyvar = sat (`notElem` keywords) pName pTycon :: Parser String pTycon = alts [pConstructor, lexeme (string "()")] pName :: Parser String pName = lexeme (then2 (:) lower (many isIdChar)) pConstructor :: Parser String pConstructor = lexeme (then2 (:) upper (many isIdChar)) isIdChar :: Parser Char isIdChar = satisfy (`elem` idChars) idChars :: [Char] idChars = ['a' .. 'z'] ++ ['A' .. 'Z'] ++ ['0' .. '9'] ++ "#_" sat :: (a -> Bool) -> Parser a -> Parser a sat predicate p = do x <- try p if predicate x then return x else pzero ------------------------------------------------------------------ -- Helpful additions to Daan's parser stuff ---------------------- ------------------------------------------------------------------ alts :: [Parser a] -> Parser a alts [] = pzero alts [p1] = try p1 alts (p1:p2:ps) = (try p1) <|> alts (p2:ps) then2 :: (a -> b -> c) -> Parser a -> Parser b -> Parser c then2 f p1 p2 = do x1 <- p1 ; x2 <- p2 ; return (f x1 x2) then3 :: (a -> b -> c -> d) -> Parser a -> Parser b -> Parser c -> Parser d then3 f p1 p2 p3 = do x1 <- p1 ; x2 <- p2 ; x3 <- p3 ; return (f x1 x2 x3) then4 :: (a -> b -> c -> d -> e) -> Parser a -> Parser b -> Parser c -> Parser d -> Parser e then4 f p1 p2 p3 p4 = do x1 <- p1 ; x2 <- p2 ; x3 <- p3 ; x4 <- p4 ; return (f x1 x2 x3 x4) then5 :: (a -> b -> c -> d -> e -> f) -> Parser a -> Parser b -> Parser c -> Parser d -> Parser e -> Parser f then5 f p1 p2 p3 p4 p5 = do x1 <- p1 ; x2 <- p2 ; x3 <- p3 ; x4 <- p4 ; x5 <- p5 return (f x1 x2 x3 x4 x5) then6 :: (a -> b -> c -> d -> e -> f -> g) -> Parser a -> Parser b -> Parser c -> Parser d -> Parser e -> Parser f -> Parser g then6 f p1 p2 p3 p4 p5 p6 = do x1 <- p1 ; x2 <- p2 ; x3 <- p3 ; x4 <- p4 ; x5 <- p5 ; x6 <- p6 return (f x1 x2 x3 x4 x5 x6) then7 :: (a -> b -> c -> d -> e -> f -> g -> h) -> Parser a -> Parser b -> Parser c -> Parser d -> Parser e -> Parser f -> Parser g -> Parser h then7 f p1 p2 p3 p4 p5 p6 p7 = do x1 <- p1 ; x2 <- p2 ; x3 <- p3 ; x4 <- p4 ; x5 <- p5 ; x6 <- p6 ; x7 <- p7 return (f x1 x2 x3 x4 x5 x6 x7) pOpt :: Parser a -> Parser (Maybe a) pOpt p = (do x <- p; return (Just x)) <|> return Nothing pOptDef :: a -> Parser a -> Parser a pOptDef d p = (do x <- p; return x) <|> return d sel12 :: a -> b -> a sel12 a _ = a sel22 :: a -> b -> b sel22 _ b = b sel23 :: a -> b -> c -> b sel23 _ b _ = b apply :: (a -> b) -> Parser a -> Parser b apply f p = liftM f p -- Hacks for zapping whitespace and comments, unfortunately needed -- because Daan won't let us have a lexer before the parser :-( lexeme :: Parser p -> Parser p lexeme p = then2 sel12 p pCommentAndWhitespace lit :: String -> Parser () lit s = apply (const ()) (lexeme (string s)) pCommentAndWhitespace :: Parser () pCommentAndWhitespace = apply (const ()) (many (alts [pLineComment, apply (const ()) (satisfy isSpace)])) <|> return () pLineComment :: Parser () pLineComment = try (then3 (\_ _ _ -> ()) (string "--") (many (satisfy (/= '\n'))) (char '\n')) stringLiteral :: Parser String stringLiteral = lexeme ( do { between (char '"') (char '"' "end of string") (many (noneOf "\"")) } "literal string") ------------------------------------------------------------------ -- end -- ------------------------------------------------------------------