-module lex
-
-:: Token
- //Values
- = IdentToken String // Identifier
- | NumberToken Int // Integer
- //Keywords
- | VarToken // var keyword
- | VoidToken // void keyword
- | ReturnToken // return keyword
- | IfToken // if keyword
- | ElseToken // else keyword
- | WhileToken // while keyword
- | TrueToken // True keyword
- | FalseToken // False keyword
- //Single Characters
- | BraceOpenToken // (
- | BraceCloseToken // )
- | CBraceOpenToken // {
- | CBraceCloseToken // {
- | SquareOpenToken // [
- | SquareCloseToken // ]
- | CommaToken // ,
- | ColonToken // :
- | SColonToken // ;
- | DotToken // .
- | PlusToken // +
- | DashToken // -
- | StarToken // *
- | SlashToken // /
- | PercentToken // %
- | EqualsToken // =
- | LesserToken // <
- | BiggerToken // >
- | ExclamationToken // !
- | AmpersandToken // &
- | PipeToken // |
- | SingleQuoteToken // '
-
-Start = "Hello World!\n"
+implementation module lex
+
+import Data.Either
+import Data.List
+import StdString
+import System.CommandLine
+import StdFile
+import StdMisc
+from StdFunc import id, const
+import Data.Maybe
+import Control.Applicative
+import Control.Monad
+import Control.Monad.State
+from Data.Func import $
+
+// Misschien moeten we hier continuation style van maken
+instance toString lexerOutput where
+ toString l = "dit is een lexer output, danwel error\n"
+
+lexer :: [Char] -> LexerOutput [Token]
+lexer _ = Left "Not Implemented"
+
+Start :: *World -> *World
+Start w
+# (args, w) = getCommandLine w // We lezen nu nog standaard van stdin
+# (out, w) = stdio w
+# (toparse, out) = readEntireFile out
+# out = out <<< toString (lexer toparse)
+# (b, w) = fclose out w
+| not b = setReturnCode 1 w
+= w
+ where
+ readEntireFile :: *File -> *([Char], *File)
+ readEntireFile f
+ # (b, c, f) = freadc f
+ | not b = ([], f)
+ # (cs, f) = readEntireFile f
+ = ([c:cs], f)
+
+
+
+// Clean adaption of Yard, a parsec like parser combinator
+:: Parser a = Parser ([Char] -> (LexerOutput a, [Char]))
+
+runParser :: (Parser a) [Char] -> (LexerOutput a, [Char])
+runParser (Parser p) s = p s
+
+instance Functor Parser where
+ fmap f s = liftM f s
+
+instance Applicative Parser where
+ pure a = Parser $ \s -> (Right a, s)
+ (<*>) sf s = ap sf s
+
+instance Monad Parser where
+ bind p f = Parser $ \s -> let (out, rest) = runParser p s in case out of
+ Left e = (Left e, rest)
+ Right t = runParser (f t) rest
+
+//gives us some, many and optional
+instance Alternative Parser where
+ empty = zero
+ (<|>) p1 p2 = parserAlternative p1 p2
+parserAlternative p1 p2 = Parser $ \s -> let (out, rest) = runParser p1 s in case out of
+ Left e = runParser p2 s
+ Right t = (Right t, rest)
+
+//parser that fails with error
+fail :: String -> Parser a
+fail e = Parser $ \s -> (Left e, s)
+
+//parser that always fails
+zero :: Parser a
+zero = fail "Zero parser"
+
+//matches exactly one Char
+item :: Parser Char
+item = Parser $ \s -> case s of
+ [] = (Left "Unexpected empty input", s)
+ [x:xs] = (Right x, xs)
+
+//matches any char which satisfies f
+satisfy :: (Char -> Bool) -> Parser Char
+satisfy f = item >>= (\r -> if (f r) (return r) zero)
+
+//tries a parser, if it fails returns a default value
+optionalDef :: a (Parser a) -> Parser a
+optionalDef def p = parserAlternative p (return def)
+
+//matched given char
+char :: Char -> Parser Char
+char c = satisfy (\i -> c==i) //I hate that we can't do: satisfy (==c)
+
+alpha :: Parser Char
+alpha = satisfy isAlpha
+
+digit :: Parser Char
+digit = satisfy isDigit
+
+//matches a given String
+string :: [Char] -> Parser [Char]
+string s = mapM_ char s >>| return s
\ No newline at end of file