{-# LANGUAGE BangPatterns #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE DeriveGeneric #-} module Data.IP.Addr where import Control.Monad import Data.Bits import Data.Char import Data.Data (Data) import Data.List (foldl', intersperse) import Data.String import Data.Typeable (Typeable) import Data.Word import Network.Socket import Numeric (showHex, showInt) import System.ByteOrder import Text.Appar.String import GHC.Enum (succError,predError) import GHC.Generics ---------------------------------------------------------------- {-| A unified IP data for 'IPv4' and 'IPv6'. To create this, use the data constructors. Or use 'read' @\"192.0.2.1\"@ :: 'IP', for example. Also, @\"192.0.2.1\"@ can be used as literal with OverloadedStrings. >>> (read "192.0.2.1" :: IP) == IPv4 (read "192.0.2.1" :: IPv4) True >>> (read "2001:db8:00:00:00:00:00:01" :: IP) == IPv6 (read "2001:db8:00:00:00:00:00:01" :: IPv6) True -} data IP = IPv4 { ipv4 :: IPv4 } | IPv6 { ipv6 :: IPv6 } deriving (Data,Generic,Typeable) {-| Equality over IP addresses. Correctly compare IPv4 and IPv4-embedded-in-IPv6 addresses. >>> (read "2001:db8:00:00:00:00:00:01" :: IP) == (read "2001:db8:00:00:00:00:00:01" :: IP) True >>> (read "2001:db8:00:00:00:00:00:01" :: IP) == (read "2001:db8:00:00:00:00:00:05" :: IP) False >>> (read "127.0.0.1" :: IP) == (read "127.0.0.1" :: IP) True >>> (read "127.0.0.1" :: IP) == (read "10.0.0.1" :: IP) False >>> (read "::ffff:127.0.0.1" :: IP) == (read "127.0.0.1" :: IP) True >>> (read "::ffff:127.0.0.1" :: IP) == (read "127.0.0.9" :: IP) False >>> (read "::ffff:127.0.0.1" :: IP) >= (read "127.0.0.1" :: IP) True >>> (read "::ffff:127.0.0.1" :: IP) <= (read "127.0.0.1" :: IP) True -} instance Eq IP where (IPv4 ip1) == (IPv4 ip2) = ip1 == ip2 (IPv6 ip1) == (IPv6 ip2) = ip1 == ip2 (IPv4 ip1) == (IPv6 ip2) = ipv4ToIPv6 ip1 == ip2 (IPv6 ip1) == (IPv4 ip2) = ip1 == ipv4ToIPv6 ip2 instance Ord IP where (IPv4 ip1) `compare` (IPv4 ip2) = ip1 `compare` ip2 (IPv6 ip1) `compare` (IPv6 ip2) = ip1 `compare` ip2 (IPv4 ip1) `compare` (IPv6 ip2) = ipv4ToIPv6 ip1 `compare` ip2 (IPv6 ip1) `compare` (IPv4 ip2) = ip1 `compare` ipv4ToIPv6 ip2 instance Show IP where show (IPv4 ip) = show ip show (IPv6 ip) = show ip ---------------------------------------------------------------- -- This is host byte order type IPv4Addr = Word32 type IPv6Addr = (Word32,Word32,Word32,Word32) {-| The abstract data type to express an IPv4 address. To create this, use 'toIPv4'. Or use 'read' @\"192.0.2.1\"@ :: 'IPv4', for example. Also, @\"192.0.2.1\"@ can be used as literal with OverloadedStrings. >>> read "192.0.2.1" :: IPv4 192.0.2.1 -} newtype IPv4 = IP4 IPv4Addr deriving (Eq, Ord, Bounded, Data, Generic, Typeable) {-| The abstract data type to express an IPv6 address. To create this, use 'toIPv6'. Or use 'read' @\"2001:DB8::1\"@ :: 'IPv6', for example. Also, @\"2001:DB8::1\"@ can be used as literal with OverloadedStrings. >>> read "2001:db8:00:00:00:00:00:01" :: IPv6 2001:db8::1 >>> read "2001:db8:11e:c00::101" :: IPv6 2001:db8:11e:c00::101 >>> read "2001:db8:11e:c00:aa:bb:192.0.2.1" :: IPv6 2001:db8:11e:c00:aa:bb:c000:201 >>> read "2001:db8::192.0.2.1" :: IPv6 2001:db8::c000:201 >>> read "0::ffff:192.0.2.1" :: IPv6 ::ffff:192.0.2.1 >>> read "0::0:c000:201" :: IPv6 ::192.0.2.1 >>> read "::0.0.0.1" :: IPv6 ::1 -} newtype IPv6 = IP6 IPv6Addr deriving (Eq, Ord, Bounded, Data, Generic, Typeable) ---------------------------------------------------------------- -- -- Enum -- instance Enum IPv4 where fromEnum (IP4 a) = fromEnum a toEnum = IP4 . toEnum instance Enum IPv6 where -- fromEnum and toEnum are not really useful, but I defined them anyway fromEnum (IP6 (a,b,c,d)) = let a' = fromEnum a `shift` 96 b' = fromEnum b `shift` 64 c' = fromEnum c `shift` 32 d' = fromEnum d in a' .|. b' .|. c' .|. d' toEnum i = let i' = fromIntegral i :: Integer a = fromIntegral (i' `shiftR` 96 .&. 0xffffffff) b = fromIntegral (i' `shiftR` 64 .&. 0xffffffff) c = fromIntegral (i' `shiftR` 32 .&. 0xffffffff) d = fromIntegral (i' .&. 0xffffffff) in IP6 (a,b,c,d) succ (IP6 (0xffffffff,0xffffffff,0xffffffff,0xffffffff)) = succError "IPv6" succ (IP6 (a, 0xffffffff,0xffffffff,0xffffffff)) = IP6 (succ a,0,0,0) succ (IP6 (a, b,0xffffffff,0xffffffff)) = IP6 (a,succ b,0,0) succ (IP6 (a, b, c,0xffffffff)) = IP6 (a,b,succ c,0) succ (IP6 (a, b, c, d)) = IP6 (a,b,c,succ d) pred (IP6 (0,0,0,0)) = predError "IPv6" pred (IP6 (a,0,0,0)) = IP6 (pred a, 0xffffffff, 0xffffffff, 0xffffffff) pred (IP6 (a,b,0,0)) = IP6 ( a, pred b, 0xffffffff, 0xffffffff) pred (IP6 (a,b,c,0)) = IP6 ( a, b, pred c, 0xffffffff) pred (IP6 (a,b,c,d)) = IP6 ( a, b, c, pred d) enumFrom ip = ip:gen ip where gen i = let i' = succ i in i':gen i' enumFromTo ip ip' = ip:gen ip where gen i | i == ip' = [] | otherwise = let i' = succ i in i':gen i' -- These two are implemented via the integer enum instance. -- A more correct implementation would essentially require -- implementing instance Num IPv6, which isn't something -- I wanna do. Another approach is to use Word128 to store -- an IPv6 address. enumFromThen ip ip' = fmap integerToIP6 [ip6ToInteger ip, ip6ToInteger ip' ..] enumFromThenTo ip inc fin = fmap integerToIP6 [ip6ToInteger ip, ip6ToInteger inc .. ip6ToInteger fin] instance Enum IP where fromEnum (IPv4 ip) = fromEnum ip fromEnum (IPv6 ip) = fromEnum ip -- Because Int cannot hold an IPv6 anyway toEnum = IPv4 . toEnum succ (IPv4 ip) = IPv4 $ succ ip succ (IPv6 ip) = IPv6 $ succ ip pred (IPv4 ip) = IPv4 $ pred ip pred (IPv6 ip) = IPv6 $ pred ip enumFrom (IPv4 ip) = fmap IPv4 $ enumFrom ip enumFrom (IPv6 ip) = fmap IPv6 $ enumFrom ip enumFromTo (IPv4 ip) (IPv4 ip') = fmap IPv4 $ enumFromTo ip ip' enumFromTo (IPv6 ip) (IPv6 ip') = fmap IPv6 $ enumFromTo ip ip' enumFromTo _ _ = error "enumFromTo: Incompatible IP families" enumFromThen (IPv4 ip) (IPv4 ip') = fmap IPv4 $ enumFromThen ip ip' enumFromThen (IPv6 ip) (IPv6 ip') = fmap IPv6 $ enumFromThen ip ip' enumFromThen _ _ = error "enumFromThen: Incompatible IP families" enumFromThenTo (IPv4 ip) (IPv4 inc) (IPv4 fin) = fmap IPv4 $ enumFromThenTo ip inc fin enumFromThenTo (IPv6 ip) (IPv6 inc) (IPv6 fin) = fmap IPv6 $ enumFromThenTo ip inc fin enumFromThenTo _ _ _ = error "enumFromThenTo: Incompatible IP families" ip6ToInteger :: IPv6 -> Integer ip6ToInteger (IP6 (a,b,c,d)) = let a' = word32ToInteger a `shift` 96 b' = word32ToInteger b `shift` 64 c' = word32ToInteger c `shift` 32 d' = word32ToInteger d in a' .|. b' .|. c' .|. d' where word32ToInteger :: Word32 -> Integer word32ToInteger = toEnum . fromEnum integerToIP6 :: Integer -> IPv6 integerToIP6 i = let a = integerToWord32 (i `shiftR` 96 .&. 0xffffffff) b = integerToWord32 (i `shiftR` 64 .&. 0xffffffff) c = integerToWord32 (i `shiftR` 32 .&. 0xffffffff) d = integerToWord32 (i .&. 0xffffffff) in IP6 (a,b,c,d) where integerToWord32 :: Integer -> Word32 integerToWord32 = toEnum . fromEnum ---------------------------------------------------------------- -- -- Show -- instance Show IPv4 where show ip = showIPv4 ip "" instance Show IPv6 where show ip = showIPv6 ip "" -- | Show an IPv4 address in the dot-decimal notation. showIPv4 :: IPv4 -> ShowS showIPv4 = foldr1 (.) . intersperse (showChar '.') . map showInt . fromIPv4 -- | Show an IPv6 address in the most appropriate notation, based on recommended -- representation proposed by . -- -- /The implementation is completely compatible with the current implementation -- of the `inet_ntop` function in glibc./ showIPv6 :: IPv6 -> ShowS showIPv6 ip@(IP6 (a1,a2,a3,a4)) -- IPv4-Mapped IPv6 Address | a1 == 0 && a2 == 0 && a3 == 0xffff = showString "::ffff:" . showIPv4 (IP4 a4) -- IPv4-Compatible IPv6 Address (exclude IPRange ::/112) | a1 == 0 && a2 == 0 && a3 == 0 && a4 >= 0x10000 = showString "::" . showIPv4 (IP4 a4) -- length of longest run > 1, replace it with "::" | end - begin > 1 = showFields prefix . showString "::" . showFields suffix -- length of longest run <= 1, don't use "::" | otherwise = showFields fields where fields = fromIPv6 ip showFields = foldr (.) id . intersperse (showChar ':') . map showHex prefix = take begin fields -- fields before "::" suffix = drop end fields -- fields after "::" begin = end + diff -- the longest run of zeros (diff, end) = minimum $ scanl (\c i -> if i == 0 then c - 1 else 0) 0 fields `zip` [0..] ---------------------------------------------------------------- -- -- IntToIP -- {-| The 'toIPv4' function returns the 'IPv4' address corresponding to the given list of 'Int' octets. The function is strict in the four elements of the list. An error is returned if the list has a differnet length. The input elements are silently truncated to their 8 least-significant bits before they are combined to form the IPv4 address. >>> toIPv4 [192,0,2,1] 192.0.2.1 -} toIPv4 :: [Int] -> IPv4 toIPv4 [a1, a2, a3, a4] = IP4 w where w = (fromIntegral a1 .&. 0xff) `unsafeShiftL` 24 .|. (fromIntegral a2 .&. 0xff) `unsafeShiftL` 16 .|. (fromIntegral a3 .&. 0xff) `unsafeShiftL` 8 .|. (fromIntegral a4 .&. 0xff) toIPv4 _ = error "IPv4 field list length != 4" {-# INLINE toIPv4 #-} {-| The 'toIPv4w' function constructs the 'IPv4' address corresponding to the given 'Word32' value. Unlike the 'fromHostAddress' function, it is strict in the input value, which here is in host byte order. >>> toIPv4w 0xc0000201 192.0.2.1 @since 1.7.9 -} toIPv4w :: Word32 -> IPv4 toIPv4w w = IP4 w {-# INLINE toIPv4w #-} {-| The 'toIPv6' function returns the 'IPv6' address corresponding to the given list of eight 16-bit 'Int's. The function is strict in the eight elements of the list. An error is returned if the list has a differnet length. The input elements are in host byte order and are silently truncated to their 16 least-signicant bits before they are combined to form the IPv6 address. >>> toIPv6 [0x2001,0xDB8,0,0,0,0,0,1] 2001:db8::1 -} toIPv6 :: [Int] -> IPv6 toIPv6 [i1,i2,i3,i4,i5,i6,i7,i8] = IP6 (x1,x2,x3,x4) where !x1 = fromIntegral $ (i1 .&. 0xffff) `unsafeShiftL` 16 .|. (i2 .&. 0xffff) !x2 = fromIntegral $ (i3 .&. 0xffff) `unsafeShiftL` 16 .|. (i4 .&. 0xffff) !x3 = fromIntegral $ (i5 .&. 0xffff) `unsafeShiftL` 16 .|. (i6 .&. 0xffff) !x4 = fromIntegral $ (i7 .&. 0xffff) `unsafeShiftL` 16 .|. (i8 .&. 0xffff) toIPv6 _ = error "toIPv6 field list length != 8" {-# INLINE toIPv6 #-} {-| The 'toIPv6b' function returns the IPv6 address corresponding to the given list of sixteen 'Int' octets. The function is strict in the sixteen elements of the list. An error is returned if the list has a differnet length. The input elements are silently truncated to their 8 least-signicant bits before they are combined to form the IPv6 address. >>> toIPv6b [0x20,0x01,0xD,0xB8,0,0,0,0,0,0,0,0,0,0,0,1] 2001:db8::1 -} toIPv6b :: [Int] -> IPv6 toIPv6b [ h11, h12, l11, l12, h21, h22, l21, l22 , h31, h32, l31, l32, h41, h42, l41, l42 ] = IP6 (x1,x2,x3,x4) where !x1 = fromIntegral $ (h11 .&. 0xff) `unsafeShiftL` 24 .|. (h12 .&. 0xff) `unsafeShiftL` 16 .|. (l11 .&. 0xff) `unsafeShiftL` 8 .|. (l12 .&. 0xff) !x2 = fromIntegral $ (h21 .&. 0xff) `unsafeShiftL` 24 .|. (h22 .&. 0xff) `unsafeShiftL` 16 .|. (l21 .&. 0xff) `unsafeShiftL` 8 .|. (l22 .&. 0xff) !x3 = fromIntegral $ (h31 .&. 0xff) `unsafeShiftL` 24 .|. (h32 .&. 0xff) `unsafeShiftL` 16 .|. (l31 .&. 0xff) `unsafeShiftL` 8 .|. (l32 .&. 0xff) !x4 = fromIntegral $ (h41 .&. 0xff) `unsafeShiftL` 24 .|. (h42 .&. 0xff) `unsafeShiftL` 16 .|. (l41 .&. 0xff) `unsafeShiftL` 8 .|. (l42 .&. 0xff) toIPv6b _ = error "toIPv6b field list length != 16" {-| The 'toIPv6w' function constructs the 'IPv6' address corresponding to the given four-tuple of host byte order 'Word32' values. This function differs from the 'fromHostAddress6' function only in the fact that it is strict in the elements of the tuple. >>> toIPv6w (0x20010DB8,0x0,0x0,0x1) 2001:db8::1 @since 1.7.9 -} toIPv6w :: (Word32, Word32, Word32, Word32) -> IPv6 toIPv6w w@(!_, !_, !_, !_) = IP6 w {-# INLINE toIPv6w #-} ---------------------------------------------------------------- -- -- IPToInt -- {-| The 'fromIPv4' function returns the list of four 'Int' octets corresponding to the given 'IPv4' address. >>> fromIPv4 (toIPv4 [192,0,2,1]) [192,0,2,1] -} fromIPv4 :: IPv4 -> [Int] fromIPv4 (IP4 w) = split w 0o30 : split w 0o20 : split w 0o10 : split w 0 : [] where split :: Word32 -> Int -> Int split a n = fromIntegral $ a `unsafeShiftR` n .&. 0xff {-# INLINE fromIPv4 #-} {-| The 'fromIPv4w' function returns a single 'Word32' value corresponding to the given the 'IPv4' address. Unlike the 'toHostAddress' function, the returned value is strictly evaluated, and is not converted to network byte order. >>> fromIPv4w (toIPv4 [0xc0,0,2,1]) == 0xc0000201 True @since 1.7.9 -} fromIPv4w :: IPv4 -> Word32 fromIPv4w (IP4 !ip4rep) = ip4rep {-# INLINE fromIPv4w #-} {-| The 'fromIPv6' function returns a list eight 'Int's in host byte order corresponding to the eight 16-bit fragments of the given IPv6 address. >>> fromIPv6 (toIPv6 [0x2001,0xDB8,0,0,0,0,0,1]) [8193,3512,0,0,0,0,0,1] -} fromIPv6 :: IPv6 -> [Int] fromIPv6 (IP6 (w1, w2, w3, w4)) = split w1 . split w2 . split w3 . split w4 $ [] where split :: Word32 -> [Int] -> [Int] split n acc = fromIntegral (n `unsafeShiftR` 0x10 .&. 0xffff) : fromIntegral (n .&. 0xffff) : acc {-# INLINE fromIPv6 #-} {-| The 'fromIPv6b' function returns the 16 'Int' octets corresponding to the 16 bytes of the given IPv6 address. >>> fromIPv6b (toIPv6b [0x20,0x01,0xD,0xB8,0,0,0,0,0,0,0,0,0,0,0,1]) [32,1,13,184,0,0,0,0,0,0,0,0,0,0,0,1] -} fromIPv6b :: IPv6 -> [Int] fromIPv6b (IP6 (w1, w2, w3, w4)) = split w1 . split w2 . split w3 . split w4 $ [] where split :: Word32 -> [Int] -> [Int] split n acc = fromIntegral (n `unsafeShiftR` 24 .&. 0xff) : fromIntegral (n `unsafeShiftR` 16 .&. 0xff) : fromIntegral (n `unsafeShiftR` 8 .&. 0xff) : fromIntegral (n .&. 0xff) : acc {-| The 'fromIPv6w' function returns a four-tuple of 'Word32' values in host byte order corresponding to the given 'IPv6' address. This is identical to the 'toHostAddress6' function, except that the elements of four-tuple are first strictly evaluated. >>> fromIPv6w (toIPv6 [0x2001,0xDB8,0,0,0,0,0,1]) == (0x20010DB8, 0, 0, 1) True @since 1.7.9 -} fromIPv6w :: IPv6 -> (Word32, Word32, Word32, Word32) fromIPv6w (IP6 ip6rep) = ip6rep {-# INLINE fromIPv6w #-} ---------------------------------------------------------------- -- -- Read -- instance Read IP where readsPrec _ = parseIP instance Read IPv4 where readsPrec _ = parseIPv4 instance Read IPv6 where readsPrec _ = parseIPv6 parseIP :: String -> [(IP,String)] parseIP cs = case runParser ip4 cs of (Just ip,rest) -> [(IPv4 ip,rest)] (Nothing,_) -> case runParser ip6 cs of (Just ip,rest) -> [(IPv6 ip,rest)] (Nothing,_) -> [] parseIPv4 :: String -> [(IPv4,String)] parseIPv4 cs = case runParser ip4 cs of (Nothing,_) -> [] (Just a4,rest) -> [(a4,rest)] parseIPv6 :: String -> [(IPv6,String)] parseIPv6 cs = case runParser ip6 cs of (Nothing,_) -> [] (Just a6,rest) -> [(a6,rest)] ---------------------------------------------------------------- -- -- IsString -- instance IsString IP where fromString = read instance IsString IPv4 where fromString = read instance IsString IPv6 where fromString = read ---------------------------------------------------------------- -- -- IPv4 Parser -- octet :: Parser Int octet = 0 <$ char '0' <|> (toInt =<< (:) <$> oneOf ['1'..'9'] <*> many digit) where toInt ds = maybe (fail "IPv4 address") pure $ foldr go Just ds 0 go !d !f !n = let n' = n * 10 + ord d - 48 in if n' <= 255 then f n' else Nothing ip4 :: Parser IPv4 ip4 = skipSpaces >> toIPv4 <$> ip4' ip4' :: Parser [Int] ip4' = do as <- octet `sepBy1` char '.' when (length as /= 4) (fail "IPv4 address") return as skipSpaces :: Parser () skipSpaces = void $ many (char ' ') ---------------------------------------------------------------- -- -- IPv6 Parser (RFC 4291) -- hex :: Parser Int hex = do ns <- some hexDigit check ns let ms = map digitToInt ns val = foldl' (\x y -> x * 16 + y) 0 ms return val where check ns = when (length ns > 4) (fail "IPv6 address -- more than 4 hex") colon2 :: Parser () colon2 = void $ string "::" format :: [Int] -> [Int] -> Parser [Int] format bs1 bs2 = do let len1 = length bs1 len2 = length bs2 when (len1 > 7) (fail "IPv6 address1") when (len2 > 7) (fail "IPv6 address2") let len = 8 - len1 - len2 when (len <= 0) (fail "IPv6 address3") let spring = replicate len 0 return $ bs1 ++ spring ++ bs2 ip6 :: Parser IPv6 ip6 = skipSpaces >> toIPv6 <$> ip6' ip6' :: Parser [Int] ip6' = ip4Embedded <|> do colon2 bs <- option [] hexcolon format [] bs <|> try (do rs <- hexcolon check rs return rs) <|> do bs1 <- hexcolon2 bs2 <- option [] hexcolon format bs1 bs2 where hexcolon = hex `sepBy1` char ':' hexcolon2 = manyTill (hex <* char ':') (char ':') check bs = when (length bs /= 8) (fail "IPv6 address4") ip4Embedded :: Parser [Int] ip4Embedded = try (do colon2 bs <- beforeEmbedded embedded <- ip4' format [] (bs ++ ip4ToIp6 embedded)) -- matches 2001:db8::192.0.2.1 <|> try (do bs1 <- manyTill (try $ hex <* char ':') (char ':') bs2 <- option [] beforeEmbedded embedded <- ip4' format bs1 (bs2 ++ ip4ToIp6 embedded)) -- matches 2001:db8:11e:c00:aa:bb:192.0.2.1 <|> try (do bs <- beforeEmbedded embedded <- ip4' let rs = bs ++ ip4ToIp6 embedded check rs return rs) where beforeEmbedded = many $ try $ hex <* char ':' ip4ToIp6 [a,b,c,d] = [ a `shiftL` 8 .|. b , c `shiftL` 8 .|. d ] ip4ToIp6 _ = error "ip4ToIp6" check bs = when (length bs /= 8) (fail "IPv6 address4") ---------------------------------------------------------------- -- -- HostAddress and HostAddress6 -- -- | The 'fromHostAddress' function converts 'HostAddress' to 'IPv4'. fromHostAddress :: HostAddress -> IPv4 fromHostAddress addr4 | byteOrder == LittleEndian = IP4 $ fixByteOrder addr4 | otherwise = IP4 addr4 -- | The 'toHostAddress' function converts 'IPv4' to 'HostAddress'. toHostAddress :: IPv4 -> HostAddress toHostAddress (IP4 addr4) | byteOrder == LittleEndian = fixByteOrder addr4 | otherwise = addr4 -- | The 'fromHostAddress6' function converts 'HostAddress6' to 'IPv6'. fromHostAddress6 :: HostAddress6 -> IPv6 fromHostAddress6 = IP6 -- | The 'toHostAddress6' function converts 'IPv6' to 'HostAddress6'. toHostAddress6 :: IPv6 -> HostAddress6 toHostAddress6 (IP6 addr6) = addr6 fixByteOrder :: Word32 -> Word32 fixByteOrder s = d1 .|. d2 .|. d3 .|. d4 where d1 = shiftL s 24 d2 = shiftL s 8 .&. 0x00ff0000 d3 = shiftR s 8 .&. 0x0000ff00 d4 = shiftR s 24 .&. 0x000000ff -- | Convert IPv4 address to IPv4-embedded-in-IPv6 ipv4ToIPv6 :: IPv4 -> IPv6 ipv4ToIPv6 ip = toIPv6b [0,0,0,0,0,0,0,0,0,0,0xff,0xff,i1,i2,i3,i4] where [i1,i2,i3,i4] = fromIPv4 ip -- | Convert 'SockAddr' to 'IP'. -- -- Since: 1.7.4. fromSockAddr :: SockAddr -> Maybe (IP, PortNumber) fromSockAddr (SockAddrInet pn ha) = Just (IPv4 (fromHostAddress ha), pn) fromSockAddr (SockAddrInet6 pn _ ha6 _) = Just (IPv6 (fromHostAddress6 ha6), pn) fromSockAddr _ = Nothing -- | Convert 'IP' to 'SockAddr'. -- -- Since: 1.7.8. toSockAddr :: (IP, PortNumber) -> SockAddr toSockAddr (IPv4 addr4, pn) = SockAddrInet pn (toHostAddress addr4) toSockAddr (IPv6 addr6, pn) = SockAddrInet6 pn 0 (toHostAddress6 addr6) 0