module Data.UUID.V1(nextUUID)
where
import Data.Bits
import Data.Maybe
import Data.Time
import Data.Word
import Control.Applicative ((<$>),(<*>))
import Control.Concurrent.MVar
import System.IO.Unsafe
import qualified System.Random as R
import Network.Info
import Data.UUID.Types.Internal.Builder
import Data.UUID.Types.Internal
nextUUID :: IO (Maybe UUID)
nextUUID = do
res <- stepTime
case res of
Just (mac', c, t) -> return $ Just $ makeUUID t c mac'
_ -> return Nothing
makeUUID :: Word64 -> Word16 -> MAC -> UUID
makeUUID time clock mac' =
buildFromBytes 1 /-/ tLow /-/ tMid /-/ tHigh /-/ clock /-/ (MACSource mac')
where tLow = (fromIntegral time) :: Word32
tMid = (fromIntegral (time `shiftR` 32)) :: Word16
tHigh = (fromIntegral (time `shiftR` 48)) :: Word16
newtype MACSource = MACSource MAC
instance ByteSource MACSource where
z /-/ (MACSource (MAC a b c d e f)) = z a b c d e f
type instance ByteSink MACSource g = Takes3Bytes (Takes3Bytes g)
stepTime :: IO (Maybe (MAC, Word16, Word64))
stepTime = do
h1 <- fmap hundredsOfNanosSinceGregorianReform getCurrentTime
modifyMVar state $ \s@(State mac' c0 h0) ->
if h1 > h0
then
return (State mac' c0 h1, Just (mac', c0, h1))
else
let
c1 = succ c0
in if c1 <= 0x3fff
then
return (State mac' c1 h1, Just (mac', c1, h1))
else
return (s, Nothing)
state :: MVar State
state = unsafePerformIO $ do
h0 <- fmap hundredsOfNanosSinceGregorianReform getCurrentTime
mac' <- getMac
newMVar $ State mac' 0 h0
getMac :: IO MAC
getMac =
getNetworkInterfaces >>=
return . listToMaybe . filter (minBound /=) . map mac >>=
\macM -> case macM of
Just m -> return m
Nothing -> randomMac
randomMac :: IO MAC
randomMac =
MAC
<$> (R.randomIO >>= return . (1 .|.))
<*> R.randomIO
<*> R.randomIO
<*> R.randomIO
<*> R.randomIO
<*> R.randomIO
data State = State
!MAC
!Word16
!Word64
deriving (Show)
hundredsOfNanosSinceGregorianReform :: UTCTime -> Word64
hundredsOfNanosSinceGregorianReform t = floor $ 10000000 * dt
where
gregorianReform = UTCTime (fromGregorian 1582 10 15) 0
dt = t `diffUTCTime` gregorianReform