gnusosa/hlischeme.hs

## hlischeme.hs
{-# LANGUAGE ExistentialQuantification #-}
import Text.ParserCombinators.Parsec hiding (spaces)
import System.Environment
import Control.Monad
import Control.Monad.Except
import System.IO

symbol :: Parser Char
symbol = oneOf "!#$%&|*+-/:<=>?@^_~"

spaces :: Parser ()
spaces = skipMany1 space

escape :: Parser String
escape = do
    d <- char '\\'
    c <- oneOf "\\\"0nrvtbf"
    return [d, c]

nonEscape :: Parser Char
nonEscape = noneOf "\\\"\0\n\r\v\t\b\f"

character :: Parser String
character = return <$> nonEscape <|> escape

data LispError = NumArgs Integer [LispVal]
               | TypeMismatch String LispVal
               | Parser ParseError
               | BadSpecialForm String LispVal
               | NotFunction String String
               | UnboundVar String String
               | Default String

showError :: LispError -> String
showError (UnboundVar message varname)  = message ++ ": " ++ varname
showError (BadSpecialForm message form) = message ++ ": " ++ show form
showError (NotFunction message func)    = message ++ ": " ++ show func
showError (NumArgs expected found)      = "Expected " ++ show expected
                                       ++ " args; found values " ++ unwordsList found
showError (TypeMismatch expected found) = "Invalid type: expected " ++ expected
                                       ++ ", found " ++ show found
showError (Parser parseErr)             = "Parse error at " ++ show parseErr

instance Show LispError where show = showError

type ThrowsError = Either LispError

trapError :: (MonadError a m, Show a) => m String -> m String
trapError action = catchError action (return . show)

extractValue :: ThrowsError a -> a
extractValue (Right val) = val

data LispVal = Atom String
               | List [LispVal]
               | DottedList [LispVal] LispVal
               | Number Integer
               | String String
               | Bool Bool

data Unpacker = forall a. Eq a => AnyUnpacker (LispVal -> ThrowsError a)

primitives :: [(String, [LispVal] -> ThrowsError LispVal)]
primitives = [
               ("+", numericBinop (+))
             , ("-", numericBinop (-))
             , ("*", numericBinop (*))
             , ("/", numericBinop div)
             , ("mod", numericBinop mod)
             , ("quotient", numericBinop quot)
             , ("remainder", numericBinop rem)
             , ("=", numBoolBinop (==))
             , ("<", numBoolBinop (<))
             , (">", numBoolBinop (>))
             , ("/=", numBoolBinop (/=))
             , (">=", numBoolBinop (>=))
             , ("<=", numBoolBinop (<=))
             , ("&&", boolBoolBinop (&&))
             , ("||", boolBoolBinop (||))
             , ("string=?", strBoolBinop (==))
             , ("string<?", strBoolBinop (<))
             , ("string>?", strBoolBinop (>))
             , ("string<=?", strBoolBinop (<=))
             , ("string>=?", strBoolBinop (>=))
             , ("car", car)
             , ("cdr", cdr)
             , ("cons", cons)
             , ("eq?", eqv)
             , ("eqv?", eqv)
             , ("equal?", equal)
             ]

car :: [LispVal] -> ThrowsError LispVal
car [List (x : xs)]         = return x
car [DottedList (x : xs) _] = return x
car [badArg]                = throwError $ TypeMismatch "pair" badArg
car badArgList              = throwError $ NumArgs 1 badArgList

cdr :: [LispVal] -> ThrowsError LispVal
cdr [List (x : xs)]         = return $ List xs
cdr [DottedList [_] x]      = return x
cdr [DottedList (_ : xs) x] = return $ DottedList xs x
cdr [badArg]                = throwError $ TypeMismatch "pair" badArg
cdr badArgList              = throwError $ NumArgs 1 badArgList

cons :: [LispVal] -> ThrowsError LispVal
cons [x1, List []] = return $ List [x1]
cons [x, List xs] = return $ List $ x : xs
cons [x, DottedList xs xlast] = return $ DottedList (x : xs) xlast
cons [x1, x2] = return $ DottedList [x1] x2
cons badArgList = throwError $ NumArgs 2 badArgList

eqv :: [LispVal] -> ThrowsError LispVal
eqv [(Bool arg1), (Bool arg2)]             = return $ Bool $ arg1 == arg2
eqv [(Number arg1), (Number arg2)]         = return $ Bool $ arg1 == arg2
eqv [(String arg1), (String arg2)]         = return $ Bool $ arg1 == arg2
eqv [(Atom arg1), (Atom arg2)]             = return $ Bool $ arg1 == arg2
eqv [(DottedList xs x), (DottedList ys y)] = eqv [List $ xs ++ [x], List $ ys ++ [y]]
eqv [(List arg1), (List arg2)]             = return $ Bool $ (length arg1 == length arg2) &&
                                                             (all eqvPair $ zip arg1 arg2)
     where eqvPair (x1, x2) = case eqv [x1, x2] of
                                Left err -> False
                                Right (Bool val) -> val
eqv [_, _]                                 = return $ Bool False
eqv badArgList                             = throwError $ NumArgs 2 badArgList

equal :: [LispVal] -> ThrowsError LispVal
equal [arg1, arg2] = do
      primitiveEquals <- liftM or $ mapM (unpackEquals arg1 arg2)
                         [AnyUnpacker unpackNum, AnyUnpacker unpackStr, AnyUnpacker unpackBool]
      eqvEquals <- eqv [arg1, arg2]
      return $ Bool $ (primitiveEquals || let (Bool x) = eqvEquals in x)
equal badArgList = throwError $ NumArgs 2 badArgList

unpackEquals :: LispVal -> LispVal -> Unpacker -> ThrowsError Bool
unpackEquals arg1 arg2 (AnyUnpacker unpacker) =
             do unpacked1 <- unpacker arg1
                unpacked2 <- unpacker arg2
                return $ unpacked1 == unpacked2
        `catchError` (const $ return False)

unpackNum :: LispVal -> ThrowsError Integer
unpackNum (Number n) = return n
unpackNum (String n) = let parsed = reads n in
                           if null parsed
                             then throwError $ TypeMismatch "number" $ String n
                             else return $ fst $ parsed !! 0
unpackNum (List [n]) = unpackNum n
unpackNum notNum     = throwError $ TypeMismatch "number" notNum

numericBinop :: (Integer -> Integer -> Integer) -> [LispVal] -> ThrowsError LispVal
numericBinop op           []  = throwError $ NumArgs 2 []
numericBinop op singleVal@[_] = throwError $ NumArgs 2 singleVal
numericBinop op params        = mapM unpackNum params >>= return . Number . foldl1 op

boolBinop :: (LispVal -> ThrowsError a) -> (a -> a -> Bool) -> [LispVal] -> ThrowsError LispVal
boolBinop unpacker op args = if length args /= 2
                             then throwError $ NumArgs 2 args
                             else do left <- unpacker $ args !! 0
                                     right <- unpacker $ args !! 1
                                     return $ Bool $ left `op` right

numBoolBinop :: (Integer -> Integer -> Bool) -> [LispVal] -> ThrowsError LispVal
numBoolBinop  = boolBinop unpackNum

strBoolBinop :: (String -> String -> Bool) -> [LispVal] -> ThrowsError LispVal
strBoolBinop  = boolBinop unpackStr

boolBoolBinop  :: (Bool -> Bool -> Bool) -> [LispVal] -> ThrowsError LispVal
boolBoolBinop = boolBinop unpackBool

unpackStr :: LispVal -> ThrowsError String
unpackStr (String s) = return s
unpackStr (Number s) = return $ show s
unpackStr (Bool s)   = return $ show s
unpackStr notString  = throwError $ TypeMismatch "string" notString

unpackBool :: LispVal -> ThrowsError Bool
unpackBool (Bool b) = return b
unpackBool notBool  = throwError $ TypeMismatch "boolean" notBool

unwordsList :: [LispVal] -> String
unwordsList = unwords . map showVal

apply :: String -> [LispVal] -> ThrowsError LispVal
apply func args = maybe (throwError $ NotFunction "Unrecognized primitive function args" func)
                        ($ args)
                        (lookup func primitives)

showVal :: LispVal -> String
showVal (String contents) = "\"" ++ contents ++ "\""
showVal (Atom name) = name
showVal (Number contents) = show contents
showVal (Bool True) = "#t"
showVal (Bool False) = "#f"
showVal (List contents) = "(" ++ unwordsList contents ++ ")"
showVal (DottedList head tail) = "(" ++ unwordsList head ++ " . " ++ showVal tail ++ ")"

instance Show LispVal where show = showVal

eval :: LispVal -> ThrowsError LispVal
eval val@(String _) = return val
eval val@(Number _) = return val
eval val@(Bool _) = return val
eval (List [Atom "quote", val]) = return val
eval (List [Atom "if", pred, conseq, alt]) =
     do result <- eval pred
        case result of
             Bool False -> eval alt
             otherwise  -> eval conseq
--alt can be a maybe, check for empty if not else expression
eval l@(List (Atom "case":key:_)) =
     do evalKey <- eval key
        let (_:_:cxs) = clauses l
        let datumsWithExpr = map datumsWithExprEval cxs
        let alt = last datumsWithExpr
        datums <- filterByDatums evalKey datumsWithExpr
        if null datums then do
          return $ List []
          else do
          lastExpr $ mapM eval (snd (head datums))
        where clauses (List cxs) = cxs
              -- datumsWithExprEval (List [List datums, expr]) = (datums, expr)
              datumsWithExprEval (List (List datums:expr)) = (datums, expr)
              datumsWithExprEval (List (Atom "else":expr)) = ([Atom "else"], expr)
              datumsWithExprEval (List _) = ([], [List []])
              checkEqual expr xs = mapM (\x -> equal [expr, x]) xs
              checkBool (Bool a) = True == a
              checkElse (Atom "else") = True
              checkElse _ = False
              filterByDatums expr xs = filterM (\x -> liftM (any (checkBool)) $ checkEqual expr (fst x)) xs

eval (List (Atom "else": expr)) = lastExpr $ mapM eval expr
eval (List (Atom func : args)) = mapM eval args >>= apply func
eval badForm = throwError $ BadSpecialForm "Unrecognized special form" badForm

parseString :: Parser LispVal
parseString = do
                char '"'
                x <- many character
                char '"'
                return $ String $ concat x

parseAtom :: Parser LispVal
parseAtom = do
              first <- letter <|> symbol
              rest <- many (letter <|> digit <|> symbol)
              let atom = first:rest
              return $ case atom of
                         "#t" -> Bool True
                         "#f" -> Bool False
                         _    -> Atom atom

parseNumber :: Parser LispVal
parseNumber = many1 digit >>= return . Number . read

parseList :: Parser LispVal
parseList = sepBy parseExpr spaces >>= return . List

parseDottedList :: Parser LispVal
parseDottedList = do
    head <- endBy parseExpr spaces
    tail <- char '.' >> spaces >> parseExpr
    return $ DottedList head tail

parseQuoted :: Parser LispVal
parseQuoted = do
    char '\''
    x <- parseExpr
    return $ List [Atom "quote", x]

parseExpr :: Parser LispVal
parseExpr = parseAtom
         <|> parseString
         <|> parseNumber
         <|> parseQuoted
         <|> do char '('
                x <- try parseList <|> parseDottedList
                char ')'
                return x

readExpr :: String -> ThrowsError LispVal
readExpr input = case parse parseExpr "input" input of
     Left err -> throwError $ Parser err
     Right val -> return val

flushStr :: String -> IO ()
flushStr str = putStr str >> hFlush stdout

readPrompt :: String -> IO String
readPrompt prompt = flushStr prompt >> getLine

evalString :: String -> IO String
evalString expr = return $ extractValue $ trapError (liftM show $ readExpr expr >>= eval)

evalAndPrint :: String -> IO ()
evalAndPrint expr =  evalString expr >>= putStrLn

until_ :: Monad m => (a -> Bool) -> m a -> (a -> m ()) -> m ()
until_ pred prompt action = do
   result <- prompt
   if pred result
      then return ()
      else action result >> until_ pred prompt action

runRepl :: IO ()
runRepl = until_ (== "quit") (readPrompt "Scheme>>> ") evalAndPrint

main :: IO ()
main = do args <- getArgs
          case length args of
               0 -> runRepl
               1 -> evalAndPrint $ args !! 0
               otherwise -> putStrLn "Program takes only 0 or 1 argument"
	{-# LANGUAGE ExistentialQuantification #-}
	import Text.ParserCombinators.Parsec hiding (spaces)
	import System.Environment
	import Control.Monad
	import Control.Monad.Except
	import System.IO

	symbol :: Parser Char
	symbol = oneOf "!#$%&\|*+-/:<=>?@^_~"

	spaces :: Parser ()
	spaces = skipMany1 space

	escape :: Parser String
	escape = do
	d <- char '\\'
	c <- oneOf "\\\"0nrvtbf"
	return [d, c]

	nonEscape :: Parser Char
	nonEscape = noneOf "\\\"\0\n\r\v\t\b\f"

	character :: Parser String
	character = return <$> nonEscape <\|> escape

	data LispError = NumArgs Integer [LispVal]
	\| TypeMismatch String LispVal
	\| Parser ParseError
	\| BadSpecialForm String LispVal
	\| NotFunction String String
	\| UnboundVar String String
	\| Default String

	showError :: LispError -> String
	showError (UnboundVar message varname) = message ++ ": " ++ varname
	showError (BadSpecialForm message form) = message ++ ": " ++ show form
	showError (NotFunction message func) = message ++ ": " ++ show func
	showError (NumArgs expected found) = "Expected " ++ show expected
	++ " args; found values " ++ unwordsList found
	showError (TypeMismatch expected found) = "Invalid type: expected " ++ expected
	++ ", found " ++ show found
	showError (Parser parseErr) = "Parse error at " ++ show parseErr

	instance Show LispError where show = showError

	type ThrowsError = Either LispError

	trapError :: (MonadError a m, Show a) => m String -> m String
	trapError action = catchError action (return . show)

	extractValue :: ThrowsError a -> a
	extractValue (Right val) = val

	data LispVal = Atom String
	\| List [LispVal]
	\| DottedList [LispVal] LispVal
	\| Number Integer
	\| String String
	\| Bool Bool

	data Unpacker = forall a. Eq a => AnyUnpacker (LispVal -> ThrowsError a)

	primitives :: [(String, [LispVal] -> ThrowsError LispVal)]
	primitives = [
	("+", numericBinop (+))
	, ("-", numericBinop (-))
	, ("", numericBinop ())
	, ("/", numericBinop div)
	, ("mod", numericBinop mod)
	, ("quotient", numericBinop quot)
	, ("remainder", numericBinop rem)
	, ("=", numBoolBinop (==))
	, ("<", numBoolBinop (<))
	, (">", numBoolBinop (>))
	, ("/=", numBoolBinop (/=))
	, (">=", numBoolBinop (>=))
	, ("<=", numBoolBinop (<=))
	, ("&&", boolBoolBinop (&&))
	, ("\|\|", boolBoolBinop (\|\|))
	, ("string=?", strBoolBinop (==))
	, ("string<?", strBoolBinop (<))
	, ("string>?", strBoolBinop (>))
	, ("string<=?", strBoolBinop (<=))
	, ("string>=?", strBoolBinop (>=))
	, ("car", car)
	, ("cdr", cdr)
	, ("cons", cons)
	, ("eq?", eqv)
	, ("eqv?", eqv)
	, ("equal?", equal)
	]

	car :: [LispVal] -> ThrowsError LispVal
	car [List (x : xs)] = return x
	car [DottedList (x : xs) _] = return x
	car [badArg] = throwError $ TypeMismatch "pair" badArg
	car badArgList = throwError $ NumArgs 1 badArgList

	cdr :: [LispVal] -> ThrowsError LispVal
	cdr [List (x : xs)] = return $ List xs
	cdr [DottedList [_] x] = return x
	cdr [DottedList (_ : xs) x] = return $ DottedList xs x
	cdr [badArg] = throwError $ TypeMismatch "pair" badArg
	cdr badArgList = throwError $ NumArgs 1 badArgList

	cons :: [LispVal] -> ThrowsError LispVal
	cons [x1, List []] = return $ List [x1]
	cons [x, List xs] = return $ List $ x : xs
	cons [x, DottedList xs xlast] = return $ DottedList (x : xs) xlast
	cons [x1, x2] = return $ DottedList [x1] x2
	cons badArgList = throwError $ NumArgs 2 badArgList

	eqv :: [LispVal] -> ThrowsError LispVal
	eqv [(Bool arg1), (Bool arg2)] = return $ Bool $ arg1 == arg2
	eqv [(Number arg1), (Number arg2)] = return $ Bool $ arg1 == arg2
	eqv [(String arg1), (String arg2)] = return $ Bool $ arg1 == arg2
	eqv [(Atom arg1), (Atom arg2)] = return $ Bool $ arg1 == arg2
	eqv [(DottedList xs x), (DottedList ys y)] = eqv [List $ xs ++ [x], List $ ys ++ [y]]
	eqv [(List arg1), (List arg2)] = return $ Bool $ (length arg1 == length arg2) &&
	(all eqvPair $ zip arg1 arg2)
	where eqvPair (x1, x2) = case eqv [x1, x2] of
	Left err -> False
	Right (Bool val) -> val
	eqv [_, _] = return $ Bool False
	eqv badArgList = throwError $ NumArgs 2 badArgList

	equal :: [LispVal] -> ThrowsError LispVal
	equal [arg1, arg2] = do
	primitiveEquals <- liftM or $ mapM (unpackEquals arg1 arg2)
	[AnyUnpacker unpackNum, AnyUnpacker unpackStr, AnyUnpacker unpackBool]
	eqvEquals <- eqv [arg1, arg2]
	return $ Bool $ (primitiveEquals \|\| let (Bool x) = eqvEquals in x)
	equal badArgList = throwError $ NumArgs 2 badArgList

	unpackEquals :: LispVal -> LispVal -> Unpacker -> ThrowsError Bool
	unpackEquals arg1 arg2 (AnyUnpacker unpacker) =
	do unpacked1 <- unpacker arg1
	unpacked2 <- unpacker arg2
	return $ unpacked1 == unpacked2
	`catchError` (const $ return False)

	unpackNum :: LispVal -> ThrowsError Integer
	unpackNum (Number n) = return n
	unpackNum (String n) = let parsed = reads n in
	if null parsed
	then throwError $ TypeMismatch "number" $ String n
	else return $ fst $ parsed !! 0
	unpackNum (List [n]) = unpackNum n
	unpackNum notNum = throwError $ TypeMismatch "number" notNum

	numericBinop :: (Integer -> Integer -> Integer) -> [LispVal] -> ThrowsError LispVal
	numericBinop op [] = throwError $ NumArgs 2 []
	numericBinop op singleVal@[_] = throwError $ NumArgs 2 singleVal
	numericBinop op params = mapM unpackNum params >>= return . Number . foldl1 op

	boolBinop :: (LispVal -> ThrowsError a) -> (a -> a -> Bool) -> [LispVal] -> ThrowsError LispVal
	boolBinop unpacker op args = if length args /= 2
	then throwError $ NumArgs 2 args
	else do left <- unpacker $ args !! 0
	right <- unpacker $ args !! 1
	return $ Bool $ left `op` right

	numBoolBinop :: (Integer -> Integer -> Bool) -> [LispVal] -> ThrowsError LispVal
	numBoolBinop = boolBinop unpackNum

	strBoolBinop :: (String -> String -> Bool) -> [LispVal] -> ThrowsError LispVal
	strBoolBinop = boolBinop unpackStr

	boolBoolBinop :: (Bool -> Bool -> Bool) -> [LispVal] -> ThrowsError LispVal
	boolBoolBinop = boolBinop unpackBool

	unpackStr :: LispVal -> ThrowsError String
	unpackStr (String s) = return s
	unpackStr (Number s) = return $ show s
	unpackStr (Bool s) = return $ show s
	unpackStr notString = throwError $ TypeMismatch "string" notString

	unpackBool :: LispVal -> ThrowsError Bool
	unpackBool (Bool b) = return b
	unpackBool notBool = throwError $ TypeMismatch "boolean" notBool

	unwordsList :: [LispVal] -> String
	unwordsList = unwords . map showVal

	apply :: String -> [LispVal] -> ThrowsError LispVal
	apply func args = maybe (throwError $ NotFunction "Unrecognized primitive function args" func)
	($ args)
	(lookup func primitives)

	showVal :: LispVal -> String
	showVal (String contents) = "\"" ++ contents ++ "\""
	showVal (Atom name) = name
	showVal (Number contents) = show contents
	showVal (Bool True) = "#t"
	showVal (Bool False) = "#f"
	showVal (List contents) = "(" ++ unwordsList contents ++ ")"
	showVal (DottedList head tail) = "(" ++ unwordsList head ++ " . " ++ showVal tail ++ ")"

	instance Show LispVal where show = showVal

	eval :: LispVal -> ThrowsError LispVal
	eval val@(String _) = return val
	eval val@(Number _) = return val
	eval val@(Bool _) = return val
	eval (List [Atom "quote", val]) = return val
	eval (List [Atom "if", pred, conseq, alt]) =
	do result <- eval pred
	case result of
	Bool False -> eval alt
	otherwise -> eval conseq
	--alt can be a maybe, check for empty if not else expression
	eval l@(List (Atom "case":key:_)) =
	do evalKey <- eval key
	let (_:_:cxs) = clauses l
	let datumsWithExpr = map datumsWithExprEval cxs
	let alt = last datumsWithExpr
	datums <- filterByDatums evalKey datumsWithExpr
	if null datums then do
	return $ List []
	else do
	lastExpr $ mapM eval (snd (head datums))
	where clauses (List cxs) = cxs
	-- datumsWithExprEval (List [List datums, expr]) = (datums, expr)
	datumsWithExprEval (List (List datums:expr)) = (datums, expr)
	datumsWithExprEval (List (Atom "else":expr)) = ([Atom "else"], expr)
	datumsWithExprEval (List _) = ([], [List []])
	checkEqual expr xs = mapM (\x -> equal [expr, x]) xs
	checkBool (Bool a) = True == a
	checkElse (Atom "else") = True
	checkElse _ = False
	filterByDatums expr xs = filterM (\x -> liftM (any (checkBool)) $ checkEqual expr (fst x)) xs

	eval (List (Atom "else": expr)) = lastExpr $ mapM eval expr
	eval (List (Atom func : args)) = mapM eval args >>= apply func
	eval badForm = throwError $ BadSpecialForm "Unrecognized special form" badForm

	parseString :: Parser LispVal
	parseString = do
	char '"'
	x <- many character
	char '"'
	return $ String $ concat x

	parseAtom :: Parser LispVal
	parseAtom = do
	first <- letter <\|> symbol
	rest <- many (letter <\|> digit <\|> symbol)
	let atom = first:rest
	return $ case atom of
	"#t" -> Bool True
	"#f" -> Bool False
	_ -> Atom atom

	parseNumber :: Parser LispVal
	parseNumber = many1 digit >>= return . Number . read

	parseList :: Parser LispVal
	parseList = sepBy parseExpr spaces >>= return . List

	parseDottedList :: Parser LispVal
	parseDottedList = do
	head <- endBy parseExpr spaces
	tail <- char '.' >> spaces >> parseExpr
	return $ DottedList head tail

	parseQuoted :: Parser LispVal
	parseQuoted = do
	char '\''
	x <- parseExpr
	return $ List [Atom "quote", x]

	parseExpr :: Parser LispVal
	parseExpr = parseAtom
	<\|> parseString
	<\|> parseNumber
	<\|> parseQuoted
	<\|> do char '('
	x <- try parseList <\|> parseDottedList
	char ')'
	return x

	readExpr :: String -> ThrowsError LispVal
	readExpr input = case parse parseExpr "input" input of
	Left err -> throwError $ Parser err
	Right val -> return val

	flushStr :: String -> IO ()
	flushStr str = putStr str >> hFlush stdout

	readPrompt :: String -> IO String
	readPrompt prompt = flushStr prompt >> getLine

	evalString :: String -> IO String
	evalString expr = return $ extractValue $ trapError (liftM show $ readExpr expr >>= eval)

	evalAndPrint :: String -> IO ()
	evalAndPrint expr = evalString expr >>= putStrLn

	until_ :: Monad m => (a -> Bool) -> m a -> (a -> m ()) -> m ()
	until_ pred prompt action = do
	result <- prompt
	if pred result
	then return ()
	else action result >> until_ pred prompt action

	runRepl :: IO ()
	runRepl = until_ (== "quit") (readPrompt "Scheme>>> ") evalAndPrint

	main :: IO ()
	main = do args <- getArgs
	case length args of
	0 -> runRepl
	1 -> evalAndPrint $ args !! 0
	otherwise -> putStrLn "Program takes only 0 or 1 argument"