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module IPAddress where
import Numeric
import Control.Monad (join)
import Control.Applicative
import Data.Char
import Data.List
import Data.Maybe
import Data.Map (lookup, Map(..), fromList)
import Data.Word
import Data.Bits
import Text.Trifecta
-- 6. Write a parser for IPv4 addresses.
data IPAddress = IPAddress Word32 deriving (Eq, Ord)
parseIP4 :: Parser IPAddress
parseIP4 = do
p1 <- natural
_ <- char '.'
p2 <- natural
_ <- char '.'
p3 <- natural
_ <- char '.'
p4 <- natural
return $ IPAddress $ fromIntegral $ xor (xor (xor (shift p1 24) (shift p2 16)) (shift p3 8)) p4
-- A 32-bit word is a 32-bit unsigned int. Lowest value is 0 rahter than being
-- capable of representing negative numbers, but the highest possible value in
-- the same number of bits is twice as high.
--
-- Word32 is an appropriate and compact way to represent IPv4 addresses. You
-- are expected to figure out not only how to parse the typical IP address
-- format, but how IP addresses work numerically insofar as is required to
-- write a working parser. This will require using a search engine unless you
-- have an appropriate book on internet networking handy.
-- 7. Same as before, but IPv6.
data IPAddress6 = IPAddress6 Word64 Word64 deriving (Eq, Ord)
-- One of the trickier parts about IPv6 will be full vs. collapsed
-- addresses and the abbrevations. See this Q&A thread 13 about
-- IPv6 abbreviations for more.
newtype IPV6Normed = IPV6Normed String
deriving (Eq, Ord, Show)
newtype IPV6Str = IPV6Str String
deriving (Eq, Ord, Show)
spanList :: ([a] -> Bool) -> [a] -> ([a], [a])
spanList _ [] = ([],[])
spanList func list@(x:xs) =
if func list
then (x:ys,zs)
else ([],list)
where (ys,zs) = spanList func xs
breakList :: ([a] -> Bool) -> [a] -> ([a], [a])
breakList func = spanList (not . func)
split' :: Eq a => [a] -> [a] -> [[a]]
split' _ [] = []
split' delim str =
let (firstline, remainder) = breakList (isPrefixOf delim) str
in
firstline : case remainder of
[] -> []
x -> if x == delim
then [] : []
else split' delim
(drop (length delim) x)
join :: [a] -> [[a]] -> [a]
join delim l = concat (intersperse delim l)
replace :: Eq a => [a] -> [a] -> [a] -> [a]
replace old new l = IPAddress.join new . split' old $ l
split :: Eq a => a -> [a] -> [[a]]
split d [] = []
split d s = x : split d (drop 1 y)
where
(x, y) = Data.List.span (/= d) s
twoRaised16Exp :: [Integer]
twoRaised16Exp = fmap ((2 ^ 16) ^) [0,1 ..]
validHexChars :: String
validHexChars = "0123456789abcdefABCDEF"
validHexCharsLowerOnly :: String
validHexCharsLowerOnly = "0123456789abcdef"
buildExpanded0s :: Int -> String
buildExpanded0s i = intersperse ':' (take i (repeat '0'))
ipv6NormedToIPAddress6 :: IPV6Normed -> IPAddress6
ipv6NormedToIPAddress6 (IPV6Normed str) = IPAddress6 quotient remainder
where
asSegs = split ':' str
zippedWithExp = zip (reverse asSegs) twoRaised16Exp
asInteger = foldr (\(s, exp) acc -> hexToDec s * exp + acc) 0 zippedWithExp
(q, r) = quotRem asInteger word64Max
quotient = fromIntegral q
remainder = fromIntegral r
hexToDec :: String -> Integer
hexToDec s = toInteger asInt
where
asInt = baseNToDec 16 (\c -> fromMaybe 0 (Data.Map.lookup (toLower c) hexCharToValue)) s
baseNToDec :: Num i => i -> (a -> i) -> [a] -> i
baseNToDec base toInt = foldl' (\acc n -> base * acc + toInt n ) 0
hexCharToValue :: Map Char Int
hexCharToValue = Data.Map.fromList $ zip validHexCharsLowerOnly [0 ..]
word64Max :: Integer
word64Max = toInteger (maxBound :: Word64)
mkIPV6Normed :: String -> Either String IPV6Normed
mkIPV6Normed origS = result
where
expand s
| s == "::" = IPV6Normed $ buildExpanded0s 8
| isPrefixOf "::" s =
let expandCnt = 8 - (length $ split ':' s) + 2
filler = buildExpanded0s expandCnt ++ ":"
replaced = replace "::" filler s
in IPV6Normed replaced
| isSuffixOf "::" s =
let expandCnt = 8 - (length $ split ':' s) + 1
filler = ':' : buildExpanded0s expandCnt
replaced = replace "::" filler s
in IPV6Normed replaced
| isInfixOf "::" s =
let expandCnt = 8 - (length $ split ':' s) + 1
filler = ':' : buildExpanded0s expandCnt ++ ":"
replaced = replace "::" filler s
in IPV6Normed replaced
| otherwise = IPV6Normed s
expanded = expand origS
IPV6Normed expandedStr = expanded
result = if length (split ':' expandedStr) == 8
then Right expanded
else Left "invalid sections"
parseIPV6Section :: Parser String
parseIPV6Section = do
mL <- optional (try $ string "::" <|> string ":")
seq <- some (oneOf validHexChars)
mR <- optional (try $ string "::" <|> string ":")
let lowered = map toLower seq
l = fromMaybe "" mL
r = fromMaybe "" mR
return $ l ++ lowered ++ r
parseIPV6Str :: Parser IPV6Str
parseIPV6Str = do
s <- (try $ (fmap (: []) (string "::" <* eof))) <|> manyTill parseIPV6Section
eof
if length s < 1
then fail "Did not find valid sections"
else return $ IPV6Str $ Control.Monad.join s
parseIPV6Normed :: Parser IPV6Normed
parseIPV6Normed = do
str <- parseIPV6Str
let IPV6Str (s) = str
full = mkIPV6Normed s
case full of
Left err -> fail err
Right fullstr -> return fullstr
parseIP6 :: Parser IPAddress6
parseIP6 = do
normed <- parseIPV6Normed
return $ ipv6NormedToIPAddress6 normed
-- 8. Remove the derived Show instances from the IPAddress/IPAddress6
-- types, and write your own Show instance for each type that renders in the
-- typical textual format appropriate to each.
ipAddressToIPV4DotFields :: IPAddress -> [Integer]
ipAddressToIPV4DotFields (IPAddress word) = repr
where
asInteger = toInteger word
repr = decToBaseN asInteger 0 [0 .. 255]
instance Show IPAddress where
show ip = Control.Monad.join $ intersperse "." asStrings
where
repr = ipAddressToIPV4DotFields ip
asStrings = fmap show repr
ipAddress6toInteger :: IPAddress6 -> Integer
ipAddress6toInteger (IPAddress6 q r) = toInteger q * word64Max + toInteger r
iPAddress6ToIPV6Normed :: IPAddress6 -> IPV6Normed
iPAddress6ToIPV6Normed ip = IPV6Normed s
where
asInteger = ipAddress6toInteger ip
chopped = integerToChoppedUp asInteger
ss = fmap integerToHexString chopped
fillCnt = 8 - length ss
filled = (take fillCnt (repeat "0")) ++ ss
s = Control.Monad.join $ intersperse ":" filled
instance Show IPAddress6 where
show ip = normed
where IPV6Normed normed = iPAddress6ToIPV6Normed ip
-- 9. Write a function that converts between IPAddress and IPAddress6.
decToBaseN :: Integral a => a -> b -> [b] -> [b]
decToBaseN i zero digits = if base == 0
then []
else go i []
where
base = fromIntegral $ length digits
go 0 [] = [zero]
go 0 acc = acc
go curr acc =
let (q, r) = quotRem curr base
in go q ((digits !! fromIntegral r) : acc)
integerToHexString :: Integer -> String
integerToHexString i = decToBaseN i '0' validHexCharsLowerOnly
integerToChoppedUp :: Integer -> [Integer]
integerToChoppedUp i = go i []
where
go 0 [] = [0]
go 0 acc = acc
go curr acc =
let (q, r) = quotRem curr (2 ^ 16)
in go q (r : acc)
ipV4ToIpV6Normed :: IPAddress -> IPV6Normed
ipV4ToIpV6Normed (IPAddress word) = normed
where
asInteger = toInteger word
chopped = integerToChoppedUp asInteger
ss = fmap integerToHexString chopped
fillCnt = 8 - length ss - 1
-- - ffff signifies an ip4 to ip6 conversion
-- (http://www.tcpipguide.com/free/t_IPv6IPv4AddressEmbedding-2.htm)
filled = (take fillCnt $ repeat "0") ++ ["ffff"] ++ ss
s = Control.Monad.join $ intersperse ":" filled
normed = IPV6Normed s
ipV4ToIpV6 :: IPAddress -> IPAddress6
ipV4ToIpV6 ip = ipv6
where
normed = ipV4ToIpV6Normed ip
ipv6 = ipv6NormedToIPAddress6 normed
|
