module HaskellLexicalSyntax where
This module is a transcription of the Lexical Syntax given in appendix B.2 of the Haskell 98 Report, except for character set definitions, which are given in module HaskellChars.
The grammar below contains extra annotations (not found in the report) to allow the recognized strings to be paired with token classifications, which are used in the token specifications in the Happy parser.
import List((\\)) import HaskellChars import HsTokens import RegExp -- program = many (lexeme ! whitespace) lexeme = varid & o Varid ! conid & o Conid ! varsym & o Varsym ! consym & o Consym ! literal -- & o Literal ! a special & o Special ! reservedop & o Reservedop ! reservedid & o Reservedid -- ! specialid & o Specialid -- recognized by the parser ! qvarid & o Qvarid ! qconid & o Qconid ! qvarsym & o Qvarsym ! qconsym & o Qconsym literal = integer & o IntLit ! float & o FloatLit ! char & o CharLit ! string & o StringLit whitechar = newline ! a vertab ! a space ! a tab ! a uniWhite newline = a creturn & a linefeed ! a creturn ! a linefeed ! a formfeed whitespace = some whitechar & o Whitespace ! comment & o Comment ! ncomment & o NestedComment comment = dashes & o Commentstart & many (a cany) & newline dashes = as "--" & many (aa "-") opencom = as "{-" --closecom = as "-}" ncomment = opencom & o NestedCommentStart -- handled by calling an external function -- This doesn't work, since regular expressions can't be recursive... --ncomment = opencom & lANYseq & many (ncomment & lANYseq) & closecom --ncomment = fix (opencom & lANYseq & many (Self & lANYseq) & closecom) --ncomment = opencom & lANYseq & closecom -- unnested comments! --lANYseq = many cANY -! (many cANY & ( opencom ! closecom ) & many cANY) --cANY = a graphic ! whitechar varid = a small & idtail -! reservedid conid = a large & idtail idtail = many (a small ! a large ! a digit ! aa "'") reservedid = ass [ "case", "class", "data", "default", "deriving", "do", "else", "if", "import", "in", "infix", "infixl", "infixr", "instance", "let", "module", "newtype", "of", "then", "type", "where", "_"] {- specialid = as"as" ! as"qualified" ! as"hiding" ! as"forall" -- rank 2 polymorphism extension ! as"primitive" -- Hugs foreign function interface -} varsym = (a symbol & many (a symbol ! aa ":")) -! (reservedop ! dashes) consym = (aa ":" & many (a symbol ! aa ":")) -! reservedop reservedop = ass ["..", ":","::", "=","\\","|","<-","->","@","~","=>"] --specialop = aa "-" ! aa "!" -- recognized by the parser instead modid = conid --optq = opt qual -- qual = modid & aa "." -- For Haskell 98 qual = some (modid & aa ".") -- For "hierachical module names"
In the report, qvarid etc include both qualified and unqualified names, but here they denote qualified names only. This allows qualified and unqualified names to be distinguished in a more natural way in the parser.
qvarid = qual & varid
qconid = qual & conid
qvarsym = qual & varsym
qconsym = qual & consym
decimal = some (a digit)
octal = some (a octit)
hexadecimal = some (a hexit)
integer = decimal
! aa "0" & aa "Oo" & octal
! aa "0" & aa "Xx" & hexadecimal
float = decimal & aa "." & decimal & opt (aa "eE" & opt (aa "-+") & decimal)
char = aa "'" & (a (graphic \\ acs "'\\") ! a space ! escape{-<\&>-}) & aa "'"
string = aa "\"" & many (a (graphic \\ acs "\"\\") ! a space ! escape ! gap) & aa "\""
escape = aa "\\" & ( charesc ! ascii ! decimal !
aa "o" & octal ! aa "x" & hexadecimal )
charesc = aa "abfnrtv\\\"'&"
ascii = aa "^" & cntrl !
ass [ "NUL", "SOH", "STX", "ETX", "EOT", "ENQ", "ACK",
"BEL", "BS", "HT", "LF", "VT", "FF", "CR", "SO", "SI", "DLE",
"DC1", "DC2", "DC3", "DC4", "NAK", "SYN", "ETB", "CAN",
"EM", "SUB", "ESC", "FS", "GS", "RS", "US", "SP", "DEL"]
cntrl = a ascLarge ! aa "@[\\]^_"
gap = aa "\\" & some whitechar & aa "\\"
--
aa = a . acs -- any of the ASCII chars
as = ts . acs -- ASCII string
ass = foldr1 (!) . map as
--
--tyvar = varid
--tycon = conid
--tycls = conid
--qtycon = qual & tycon
--qtycls = qual & tycls