zearen/JSONParser.hs

## JSONParser.hs
{-
    Zachary Weaver <zaw6@pitt.edu>
    JSONParser.hs
    Version 0.1.1

    A simple example of parsing JSON with Parsec in haskell.  Note that
    since the primary point of this excersize is demonstration,
    Text.Parsec.Token was avoided to expose more of the grammar.  Also,
    complicated optimizations and shorcuts were avoided (mostly).

    http://www.json.org was the primary reference.
-}

{-# LANGUAGE NoMonomorphismRestriction #-}

-- We need these for Show JSON
import Data.List (foldl', intersperse)
-- Used when parsing unicode escape sequences
import Data.Char (chr, ord)
-- Used to represent JS Assoiciative arrays
import qualified Data.Map as Map

import Text.Parsec
import Text.Parsec.Char

-- This is our data structure to represent JSON
data JSON = JsonNum Double
          | JsonStr String
          | JsonArr [JSON] -- An array
          | JsonAA (Map.Map String JSON) -- An associative array
          | JsonBool Bool
          | JsonNull
    deriving (Eq, Ord)

-- Collapse a JSON document to a string
-- If this confuses you, just accept it as magic.
instance Show JSON where
    showsPrec _ = showsJSON
      where commaJoin = foldl' (.) id . intersperse (", "++)
            showsAssoc (field, val) = shows field . (": "++) . shows val
            showsJSON (JsonNum num)  = shows num
            showsJSON (JsonStr str)  = shows str
            showsJSON (JsonArr jarr) =
                ('[':) . commaJoin (map shows jarr) . (']':)
            showsJSON (JsonAA aa)    =
                ('{':) . commaJoin (map showsAssoc $ Map.toList aa) . ('}':)
            showsJSON (JsonBool tf)  =
                if tf then ("true"++) else ("false"++)
            showsJSON JsonNull       = ("null"++)

-- The base parser
jsonParser = do
    spaces -- handle whitespace
    -- Each of these parses the corresponding data type
    -- E.g. jsonPStr -> JsonStr
    json <- jsonPNum
        <|> jsonPStr
        <|> jsonPBool
        <|> jsonPNull
        <|> jsonPArr
        <|> jsonPAA
        <?> "value" -- Otherwise report we expected a value
    spaces
    -- return for monads means something very different than
    -- + procedural languages.
    -- Simply put, it wraps the value in the monad
    return json

-- These parsers try to collect a literal as a string.
-- Note that the try is not strictly necessary, but this is a good example
-- + of when one might use it (Consider if there was also a "none" value)
jsonPNull = try (string "null") >> return JsonNull

jsonPBool = fmap JsonBool
    $ (try (string "true") >> return True)
    <|> (try (string "false") >> return False)

-- Note how this parser splits the problem into parts
jsonPNum = do
    -- We return a function that might negate our result later
    doNeg <- (char '-' >> return negate) <|> return id
    -- Every number can
    realPart <- realP
    fracPart <- fracP
    expPart  <- expP
    -- We put all the pieces together and wrap it into a JSON type
    return $ JsonNum $ doNeg $ (realPart + fracPart) * 10 ** expPart
        -- This is the real part.  It must exist.
  where realP = (char '0' >> return 0) <|> (do
                -- It's either just a 0, or begins with 1 - 9
                firstDigit <- satisfy (\ ch -> '1' <= ch && ch <= '9')
                -- after that it can be any digit
                restDigits <- many digit
                return $ read $ firstDigit : restDigits
            )
        fracP = (do
                char '.'
                digits <- many1 digit
                return $ read $ "0." ++ digits
            )
            -- This parser will fail if there's no dot
            -- That means there's no fractional part, so we default to 0
            <|> return 0
        expP = (do
            oneOf "eE"
            -- This is similar to the other doNeg, but we have an
            -- + extra option
            doNeg <- (char '-' >> return negate)
                <|> (char '+' >> return id)
                <|> return id
            digits <- many1 digit
            return $ doNeg $ read digits
            )
            -- Similarly, we default to 0 if there's no exponent
            <|> return 0

jsonStr = do
    char '\"'
    strChar `manyTill` (char '\"')
        -- This is a list of substutions to make after a \
  where subMap = Map.fromList
            [ ('\"', '\"')
            , ('\\', '\\')
            , ('/', '/')
            , ('n', '\n')
            , ('r', '\r')
            , ('f', '\f')
            , ('t', '\t')
            , ('b', '\b')
            ]
        -- Parses a
        unicode = do
            -- get 4 hexadecimal digits
            code <- count 4 hexDigit
            if null code -- The docs say this is possible
              then fail $ "expecting unicode"
              -- Otherwise, just read the values
              else return $ chr $ read $ "0x" ++ code
        -- This acts like aanyChar, but will try to escape first
        strChar = (do
            char '\\'
            ch <- anyChar
            -- search for the correct substitution
            case Map.lookup ch subMap of
                Just newCh -> return newCh
                Nothing -> do
                    if ch == 'u' -- It might yet be unicode
                      then unicode
                      else fail "expecting escape sequence"
            )
            -- If we don't have an escape sequence, just return the char
            <|> anyChar

-- This just wraps the String result of jsonStr into a JSON
jsonPStr = fmap JsonStr jsonStr

-- Arrays are real simple at this point.
-- Just get a comma seperated list of JSON values between brackets
jsonPArr = do
    char '['
    jarr <- jsonParser `sepBy` (char ',')
    char ']'
    return $ JsonArr $ jarr

-- Associative arrays are almost as simple, except we need to teach it
-- + how to parse fields
jsonPAA = do
    char '{'
    jAA <- assocP `sepBy` char ',' -- returns a list of (key, value) tuples
    char '}'
    return $ JsonAA $ Map.fromList $ jAA
        -- This should seem really straight forward.
        -- We get the label followed by a colon and its corresponding
        -- + JSON value
  where assocP = do
            spaces
            label <- jsonStr
            spaces
            char ':'
            json <- jsonParser
            return (label, json)

-- A real simple interactive program to test
main = do
    line <- getLine
    case parse jsonParser "" line of
        Right json -> do
            print json
            main
        Left err -> print err
	{-
	Zachary Weaver <zaw6@pitt.edu>
	JSONParser.hs
	Version 0.1.1

	A simple example of parsing JSON with Parsec in haskell. Note that
	since the primary point of this excersize is demonstration,
	Text.Parsec.Token was avoided to expose more of the grammar. Also,
	complicated optimizations and shorcuts were avoided (mostly).

	http://www.json.org was the primary reference.
	-}

	{-# LANGUAGE NoMonomorphismRestriction #-}

	-- We need these for Show JSON
	import Data.List (foldl', intersperse)
	-- Used when parsing unicode escape sequences
	import Data.Char (chr, ord)
	-- Used to represent JS Assoiciative arrays
	import qualified Data.Map as Map

	import Text.Parsec
	import Text.Parsec.Char

	-- This is our data structure to represent JSON
	data JSON = JsonNum Double
	\| JsonStr String
	\| JsonArr [JSON] -- An array
	\| JsonAA (Map.Map String JSON) -- An associative array
	\| JsonBool Bool
	\| JsonNull
	deriving (Eq, Ord)

	-- Collapse a JSON document to a string
	-- If this confuses you, just accept it as magic.
	instance Show JSON where
	showsPrec _ = showsJSON
	where commaJoin = foldl' (.) id . intersperse (", "++)
	showsAssoc (field, val) = shows field . (": "++) . shows val
	showsJSON (JsonNum num) = shows num
	showsJSON (JsonStr str) = shows str
	showsJSON (JsonArr jarr) =
	('[':) . commaJoin (map shows jarr) . (']':)
	showsJSON (JsonAA aa) =
	('{':) . commaJoin (map showsAssoc $ Map.toList aa) . ('}':)
	showsJSON (JsonBool tf) =
	if tf then ("true"++) else ("false"++)
	showsJSON JsonNull = ("null"++)

	-- The base parser
	jsonParser = do
	spaces -- handle whitespace
	-- Each of these parses the corresponding data type
	-- E.g. jsonPStr -> JsonStr
	json <- jsonPNum
	<\|> jsonPStr
	<\|> jsonPBool
	<\|> jsonPNull
	<\|> jsonPArr
	<\|> jsonPAA
	<?> "value" -- Otherwise report we expected a value
	spaces
	-- return for monads means something very different than
	-- + procedural languages.
	-- Simply put, it wraps the value in the monad
	return json

	-- These parsers try to collect a literal as a string.
	-- Note that the try is not strictly necessary, but this is a good example
	-- + of when one might use it (Consider if there was also a "none" value)
	jsonPNull = try (string "null") >> return JsonNull

	jsonPBool = fmap JsonBool
	$ (try (string "true") >> return True)
	<\|> (try (string "false") >> return False)

	-- Note how this parser splits the problem into parts
	jsonPNum = do
	-- We return a function that might negate our result later
	doNeg <- (char '-' >> return negate) <\|> return id
	-- Every number can
	realPart <- realP
	fracPart <- fracP
	expPart <- expP
	-- We put all the pieces together and wrap it into a JSON type
	return $ JsonNum $ doNeg $ (realPart + fracPart) * 10 ** expPart
	-- This is the real part. It must exist.
	where realP = (char '0' >> return 0) <\|> (do
	-- It's either just a 0, or begins with 1 - 9
	firstDigit <- satisfy (\ ch -> '1' <= ch && ch <= '9')
	-- after that it can be any digit
	restDigits <- many digit
	return $ read $ firstDigit : restDigits
	)
	fracP = (do
	char '.'
	digits <- many1 digit
	return $ read $ "0." ++ digits
	)
	-- This parser will fail if there's no dot
	-- That means there's no fractional part, so we default to 0
	<\|> return 0
	expP = (do
	oneOf "eE"
	-- This is similar to the other doNeg, but we have an
	-- + extra option
	doNeg <- (char '-' >> return negate)
	<\|> (char '+' >> return id)
	<\|> return id
	digits <- many1 digit
	return $ doNeg $ read digits
	)
	-- Similarly, we default to 0 if there's no exponent
	<\|> return 0

	jsonStr = do
	char '\"'
	strChar `manyTill` (char '\"')
	-- This is a list of substutions to make after a \
	where subMap = Map.fromList
	[ ('\"', '\"')
	, ('\\', '\\')
	, ('/', '/')
	, ('n', '\n')
	, ('r', '\r')
	, ('f', '\f')
	, ('t', '\t')
	, ('b', '\b')
	]
	-- Parses a
	unicode = do
	-- get 4 hexadecimal digits
	code <- count 4 hexDigit
	if null code -- The docs say this is possible
	then fail $ "expecting unicode"
	-- Otherwise, just read the values
	else return $ chr $ read $ "0x" ++ code
	-- This acts like aanyChar, but will try to escape first
	strChar = (do
	char '\\'
	ch <- anyChar
	-- search for the correct substitution
	case Map.lookup ch subMap of
	Just newCh -> return newCh
	Nothing -> do
	if ch == 'u' -- It might yet be unicode
	then unicode
	else fail "expecting escape sequence"
	)
	-- If we don't have an escape sequence, just return the char
	<\|> anyChar

	-- This just wraps the String result of jsonStr into a JSON
	jsonPStr = fmap JsonStr jsonStr

	-- Arrays are real simple at this point.
	-- Just get a comma seperated list of JSON values between brackets
	jsonPArr = do
	char '['
	jarr <- jsonParser `sepBy` (char ',')
	char ']'
	return $ JsonArr $ jarr

	-- Associative arrays are almost as simple, except we need to teach it
	-- + how to parse fields
	jsonPAA = do
	char '{'
	jAA <- assocP `sepBy` char ',' -- returns a list of (key, value) tuples
	char '}'
	return $ JsonAA $ Map.fromList $ jAA
	-- This should seem really straight forward.
	-- We get the label followed by a colon and its corresponding
	-- + JSON value
	where assocP = do
	spaces
	label <- jsonStr
	spaces
	char ':'
	json <- jsonParser
	return (label, json)

	-- A real simple interactive program to test
	main = do
	line <- getLine
	case parse jsonParser "" line of
	Right json -> do
	print json
	main
	Left err -> print err