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|
{-# LANGUAGE CPP #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE DeriveFoldable #-}
{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE DeriveGeneric #-}
{-# LANGUAGE DeriveTraversable #-}
{-# LANGUAGE ExistentialQuantification #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE LambdaCase #-}
{-# LANGUAGE NamedFieldPuns #-}
{-# LANGUAGE PatternSynonyms #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE RecursiveDo #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TupleSections #-}
{-# LANGUAGE ViewPatterns #-}
module Network.Tox where
#ifdef THREAD_DEBUG
import Control.Concurrent.Lifted.Instrument
#else
import Control.Concurrent.Lifted
#endif
import Control.Concurrent.STM
import Control.Monad
import Crypto.PubKey.Curve25519
import Crypto.Random
import Data.Bits.ByteString ()
import qualified Data.ByteString as B
;import Data.ByteString (ByteString)
import qualified Data.ByteString.Char8 as C8
import Data.Data
import Data.Functor.Contravariant
import Data.Maybe
import qualified Data.MinMaxPSQ as MinMaxPSQ
import qualified Data.Serialize as S
import Data.Time.Clock.POSIX (getPOSIXTime)
import Data.Word
import Network.Socket
import System.Endian
import Network.BitTorrent.DHT.Token as Token
import qualified Data.Wrapper.PSQ as PSQ
import System.Global6
import Network.Address (WantIP (..),IP)
import qualified Network.Kademlia.Routing as R
import Network.QueryResponse
import Crypto.Tox
import Data.Word64Map (fitsInInt)
import qualified Data.Word64Map (empty)
import Network.Kademlia.Bootstrap (forkPollForRefresh, bootstrap)
import Network.Tox.Crypto.Transport (Handshake(..),CryptoPacket)
import qualified Network.Tox.DHT.Handlers as DHT
import qualified Network.Tox.DHT.Transport as DHT
import Network.Tox.NodeId
import qualified Network.Tox.Onion.Handlers as Onion
import qualified Network.Tox.Onion.Transport as Onion
import Network.Tox.Transport
import OnionRouter
import Network.Tox.ContactInfo
import Text.XXD
import DPut
import DebugTag
import Network.Tox.Avahi
import Network.Tox.Session
import Network.SessionTransports
import Network.Kademlia.Search
import HandshakeCache
newCrypto :: IO TransportCrypto
newCrypto = do
secret <- generateSecretKey
alias <- generateSecretKey
ralias <- generateSecretKey
let pubkey = toPublic secret
aliaspub = toPublic alias
raliaspub = toPublic ralias
ukeys <- atomically $ newTVar []
(symkey, drg) <- do
drg0 <- getSystemDRG
return $ randomBytesGenerate 32 drg0 :: IO (ByteString, SystemDRG)
noncevar <- atomically $ newTVar $ fst $ withDRG drg drgNew
cookieKeys <- atomically $ newTVar []
cache <- newSecretsCache
dput XNetCrypto $ "secret(tox) = " ++ DHT.showHex secret
dput XNetCrypto $ "public(tox) = " ++ DHT.showHex pubkey
dput XNetCrypto $ "symmetric(tox) = " ++ DHT.showHex symkey
return TransportCrypto
{ transportSecret = secret
, transportPublic = pubkey
, onionAliasSecret = alias
, onionAliasPublic = aliaspub
, rendezvousSecret = ralias
, rendezvousPublic = raliaspub
, transportSymmetric = return $ SymmetricKey symkey
, transportNewNonce = do
drg1 <- readTVar noncevar
let (nonce, drg2) = withDRG drg1 (Nonce24 <$> getRandomBytes 24)
writeTVar noncevar drg2
return nonce
, transportNewKey = do
drg1 <- readTVar noncevar
let (k, drg2) = withDRG drg1 generateSecretKey
writeTVar noncevar drg2
return k
, userKeys = return []
, pendingCookies = cookieKeys
, secretsCache = cache
}
updateIP :: TVar (R.BucketList NodeInfo) -> SockAddr -> STM ()
updateIP tblvar a = do
bkts <- readTVar tblvar
case nodeInfo (nodeId (R.thisNode bkts)) a of
Right ni -> writeTVar tblvar (bkts { R.thisNode = ni })
Left _ -> return ()
genNonce24 :: DRG g =>
TVar (g, pending) -> DHT.TransactionId -> IO DHT.TransactionId
genNonce24 var (DHT.TransactionId nonce8 _) = atomically $ do
(g,pending) <- readTVar var
let (bs, g') = randomBytesGenerate 24 g
writeTVar var (g',pending)
return $ DHT.TransactionId nonce8 (Nonce24 bs)
gen :: forall gen. DRG gen => gen -> (DHT.TransactionId, gen)
gen g = let (bs, g') = randomBytesGenerate 24 g
(ws, g'') = randomBytesGenerate 8 g'
Right w = S.runGet S.getWord64be ws
in ( DHT.TransactionId (Nonce8 w) (Nonce24 bs), g'' )
intKey :: DHT.TransactionId -> Int
intKey (DHT.TransactionId (Nonce8 w) _) = fromIntegral w
w64Key :: DHT.TransactionId -> Word64
w64Key (DHT.TransactionId (Nonce8 w) _) = w
nonceKey :: DHT.TransactionId -> Nonce8
nonceKey (DHT.TransactionId n _) = n
-- | Return my own address.
myAddr :: TVar (R.BucketList NodeInfo) -- ^ IPv4 buckets
-> TVar (R.BucketList NodeInfo) -- ^ IPv6 buckets
-> Maybe NodeInfo -- ^ Interested remote address
-> IO NodeInfo
myAddr routing4 routing6 maddr = atomically $ do
let var = case flip DHT.prefer4or6 Nothing <$> maddr of
Just Want_IP6 -> routing4
_ -> routing6
a <- readTVar var
return $ R.thisNode a
newClient :: (DRG g, Show addr, Show meth) =>
g -> Transport String addr x
-> (Client String meth DHT.TransactionId addr x -> x -> MessageClass String meth DHT.TransactionId addr x)
-> (Maybe addr -> IO addr)
-> (Client String meth DHT.TransactionId addr x -> meth -> Maybe (MethodHandler String DHT.TransactionId addr x))
-> (forall d. TransactionMethods d DHT.TransactionId addr x -> TransactionMethods d DHT.TransactionId addr x)
-> (Client String meth DHT.TransactionId addr x -> Transport String addr x -> Transport String addr x)
-> IO (Client String meth DHT.TransactionId addr x)
newClient drg net classify selfAddr handlers modifytbl modifynet = do
-- If we have 8-byte keys for IntMap, then use it for transaction lookups.
-- Otherwise, use ordinary Map. The details of which will be hidden by an
-- existential closure (see mkclient below).
--
tblvar <-
if fitsInInt (Proxy :: Proxy Word64)
then do
let intmapT = transactionMethods (contramap intKey intMapMethods) gen
intmap_var <- atomically $ newTVar (drg, mempty)
return $ Right (intmapT,intmap_var)
else do
let word64mapT = transactionMethods (contramap w64Key w64MapMethods) gen
map_var <- atomically $ newTVar (drg, Data.Word64Map.empty)
return $ Left (word64mapT,map_var)
let dispatch tbl var handlers client = DispatchMethods
{ classifyInbound = classify client
, lookupHandler = handlers -- var
, tableMethods = modifytbl tbl
}
eprinter = logErrors -- printErrors stderr
mkclient (tbl,var) handlers =
let client = Client
{ clientNet = addHandler (reportParseError eprinter) (handleMessage client) $ modifynet client net
, clientDispatcher = dispatch tbl var (handlers client) client
, clientErrorReporter = eprinter { reportTimeout = reportTimeout ignoreErrors }
, clientPending = var
, clientAddress = selfAddr
, clientResponseId = genNonce24 var
, clientEnterQuery = \_ -> return ()
, clientLeaveQuery = \_ _ -> return ()
}
in client
return $ either mkclient mkclient tblvar handlers
data Tox extra = Tox
{ toxDHT :: DHT.Client
, toxOnion :: Onion.Client RouteId
, toxToRoute :: Transport String Onion.AnnouncedRendezvous (PublicKey,Onion.OnionData)
, toxCrypto :: Transport String SockAddr (CryptoPacket Encrypted)
, toxHandshakes :: Transport String SockAddr (Handshake Encrypted)
, toxHandshakeCache :: HandshakeCache
, toxCryptoKeys :: TransportCrypto
, toxRouting :: DHT.Routing
, toxTokens :: TVar SessionTokens
, toxAnnouncedKeys :: TVar Onion.AnnouncedKeys
, toxOnionRoutes :: OnionRouter
, toxContactInfo :: ContactInfo extra
, toxAnnounceToLan :: IO ()
}
-- | Create a DHTPublicKey packet to send to a remote contact.
getContactInfo :: Tox extra -> IO DHT.DHTPublicKey
getContactInfo Tox{toxCryptoKeys,toxRouting} = join $ atomically $ do
r4 <- readTVar $ DHT.routing4 toxRouting
r6 <- readTVar $ DHT.routing6 toxRouting
nonce <- transportNewNonce toxCryptoKeys
let self = nodeId n4
n4 = R.thisNode r4
n6 = R.thisNode r6
n4s = R.kclosest DHT.toxSpace 4 self r4
n6s = R.kclosest DHT.toxSpace 4 self r6
ns = filter (DHT.isGlobal . nodeIP) [n4,n6]
++ concat (zipWith (\a b -> [a,b]) n4s n6s)
return $ do
timestamp <- round . (* 1000000) <$> getPOSIXTime
return DHT.DHTPublicKey
{ dhtpkNonce = timestamp
, dhtpk = id2key self
, dhtpkNodes = DHT.SendNodes $ take 4 ns
}
isLocalHost :: SockAddr -> Bool
isLocalHost (SockAddrInet _ host32) = (fromBE32 host32 == 0x7f000001)
isLocalHost _ = False
addVerbosity :: Transport err SockAddr ByteString -> Transport err SockAddr ByteString
addVerbosity tr =
tr { awaitMessage = \kont -> awaitMessage tr $ \m -> do
forM_ m $ mapM_ $ \(msg,addr) -> do
when (not (B.null msg || elem (B.head msg) [0,1,2,4,0x81,0x82,0x8c,0x8d])) $ do
mapM_ (\x -> dput XMisc ( (show addr) ++ " --> " ++ x))
$ xxd 0 msg
kont m
, sendMessage = \addr msg -> do
when (not (B.null msg || elem (B.head msg) [0,1,2,4,0x81,0x8c,0x8d])) $ do
mapM_ (\x -> dput XMisc ( (show addr) ++ " <-- " ++ x))
$ xxd 0 msg
sendMessage tr addr msg
}
newKeysDatabase :: IO (TVar Onion.AnnouncedKeys)
newKeysDatabase =
atomically $ newTVar $ Onion.AnnouncedKeys PSQ.empty MinMaxPSQ.empty
getOnionAlias :: TransportCrypto -> STM NodeInfo -> Maybe (Onion.OnionDestination r) -> IO (Onion.OnionDestination r)
getOnionAlias crypto dhtself remoteNode = atomically $ do
ni <- dhtself
let alias = case remoteNode of
Just (Onion.OnionDestination (Onion.AnnouncingAlias _ uk) _ _)
-> ni { nodeId = key2id uk }
_ -> ni { nodeId = key2id (onionAliasPublic crypto) }
return $ Onion.OnionDestination Onion.SearchingAlias alias Nothing
newTox :: TVar Onion.AnnouncedKeys -- ^ Store of announced keys we are a rendezvous for.
-> SockAddr -- ^ Bind-address to listen on.
-> ( ContactInfo extra -> SockAddr -> Session -> IO () )
-> Maybe SecretKey -- ^ Optional DHT secret key to use.
-> ( Int -> Onion.OnionResponse Onion.N1 -> IO () ) -- ^ TCP-bound onion responses.
-> IO (Tox extra)
newTox keydb addr onsess suppliedDHTKey tcp = do
(udp,sock) <- {- addVerbosity <$> -} udpTransport' addr
tox <- newToxOverTransport keydb addr onsess suppliedDHTKey udp tcp
return tox { toxAnnounceToLan = announceToLan sock (key2id $ transportPublic $ toxCryptoKeys tox) }
-- | This version of 'newTox' is useful for automated tests using 'testPairTransport'.
newToxOverTransport :: TVar Onion.AnnouncedKeys
-> SockAddr
-> ( ContactInfo extra -> SockAddr -> Session -> IO () )
-> Maybe SecretKey
-> Onion.UDPTransport
-> ( Int -> Onion.OnionResponse Onion.N1 -> IO () ) -- ^ TCP-bound onion responses.
-> IO (Tox extra)
newToxOverTransport keydb addr onNewSession suppliedDHTKey udp tcp = do
roster <- newContactInfo
crypto0 <- newCrypto
let -- patch in supplied DHT key
crypto1 = fromMaybe crypto0 $do
k <- suppliedDHTKey
return crypto0
{ transportSecret = k
, transportPublic = toPublic k
}
-- patch in newly allocated roster state.
crypto = crypto1 { userKeys = myKeyPairs roster }
forM_ suppliedDHTKey $ \k -> do
maybe (dput XMisc "failed to encode suppliedDHTKey")
(dputB XMisc . C8.append "Using suppliedDHTKey: ")
$ encodeSecret k
drg <- drgNew
let lookupClose _ = return Nothing
mkrouting <- DHT.newRouting addr crypto updateIP updateIP
orouter <- newOnionRouter $ dput XRoutes
(cryptonet,dhtcrypt,onioncrypt,dtacrypt,handshakes) <- toxTransport crypto orouter lookupClose udp tcp
sessions <- initSessions (sendMessage cryptonet)
let dhtnet0 = layerTransportM (DHT.decrypt crypto) (DHT.encrypt crypto) dhtcrypt
tbl4 = DHT.routing4 $ mkrouting (error "missing client")
tbl6 = DHT.routing6 $ mkrouting (error "missing client")
dhtclient <- newClient drg dhtnet0 DHT.classify (myAddr tbl4 tbl6) (DHT.handlers crypto . mkrouting) id
$ \client net -> onInbound (DHT.updateRouting client (mkrouting client) orouter) net
hscache <- newHandshakeCache crypto (sendMessage handshakes)
let sparams = SessionParams
{ spCrypto = crypto
, spSessions = sessions
, spGetSentHandshake = getSentHandshake hscache
, spOnNewSession = onNewSession roster addr
}
orouter' <- forkRouteBuilder orouter
$ \nid ni -> fmap (\(_,ns,_)->ns)
<$> DHT.getNodes dhtclient (DHT.nodesOfInterest $ mkrouting dhtclient) nid ni
toks <- do
nil <- nullSessionTokens
atomically $ newTVar nil { maxInterval = 20 } -- 20 second timeout on announce ping-ids.
oniondrg <- drgNew
let onionnet = layerTransportM (Onion.decrypt crypto) (Onion.encrypt crypto) onioncrypt
onionclient <- newClient oniondrg onionnet (const Onion.classify)
(getOnionAlias crypto $ R.thisNode <$> readTVar (DHT.routing4 $ mkrouting dhtclient))
(const $ Onion.handlers onionnet (mkrouting dhtclient) toks keydb)
(hookQueries orouter' DHT.transactionKey)
(const id)
return Tox
{ toxDHT = dhtclient
, toxOnion = onionclient
, toxToRoute = onInbound (updateContactInfo roster) dtacrypt
, toxCrypto = addHandler (dput XMisc) (sessionHandler sessions) cryptonet
, toxHandshakes = addHandler (dput XMisc) (handshakeH sparams) handshakes
, toxHandshakeCache = hscache
, toxCryptoKeys = crypto
, toxRouting = mkrouting dhtclient
, toxTokens = toks
, toxAnnouncedKeys = keydb
, toxOnionRoutes = orouter
, toxContactInfo = roster
, toxAnnounceToLan = return ()
}
onionTimeout :: Tox extra -> DHT.TransactionId -> Onion.OnionDestination RouteId -> STM (Onion.OnionDestination RouteId, Int)
onionTimeout Tox { toxOnionRoutes = or } (DHT.TransactionId n8 _) od = lookupTimeout or n8 od
routing4nodeInfo :: DHT.Routing -> IO NodeInfo
routing4nodeInfo (DHT.routing4 -> tv) = R.thisNode <$> readTVarIO tv
dnssdAnnounce :: Tox extra -> IO ()
dnssdAnnounce tox = do
ni <- routing4nodeInfo (toxRouting tox)
keys <- fmap (key2id . snd) <$> atomically (userKeys $ toxCryptoKeys tox)
announceToxService (nodePort ni) (nodeId ni) (listToMaybe keys)
dnssdDiscover :: Tox extra -> NodeInfo -> (Maybe NodeId) -> IO ()
dnssdDiscover tox ni toxid = do
acts <- atomically $ readTVar $ accounts $ toxContactInfo tox
now <- getPOSIXTime
forM toxid $ \tid ->
forM acts $ \act ->
atomically $ setContactAddr now (id2key tid) ni act
void $ DHT.ping (toxDHT tox) ni
forkTox :: Tox extra -> Bool -> IO (IO (), [NodeInfo] -> [NodeInfo] -> IO (), [NodeInfo] -> [NodeInfo] -> IO ())
forkTox tox with_avahi = do
quitHs <- forkListener "toxHandshakes" (toxHandshakes tox)
quitToRoute <- forkListener "toxToRoute" (toxToRoute tox)
quitOnion <- forkListener "toxOnion" (clientNet $ toxOnion tox)
quitDHT <- forkListener "toxDHT" (clientNet $ toxDHT tox)
quitNC <- forkListener "toxCrypto" (toxCrypto tox)
quitAvahi <- if with_avahi then do
forkPollForRefresh (DHT.refresher4 $ toxRouting tox)
forkPollForRefresh (DHT.refresher6 $ toxRouting tox)
dnssdIn <- forkIO $ queryToxService (dnssdDiscover tox)
dnssdOut <- forkIO $ dnssdAnnounce tox
labelThread dnssdIn "tox-avahi-monitor"
labelThread dnssdOut "tox-avahi-publish"
return $ forM_ [dnssdIn,dnssdOut] killThread
else return $ return ()
keygc <- Onion.forkAnnouncedKeysGC (toxAnnouncedKeys tox)
return ( do quitAvahi
killThread keygc
quitNC
quitDHT
quitOnion
quitToRoute
quitHs
, bootstrap (DHT.refresher4 $ toxRouting tox)
, bootstrap (DHT.refresher6 $ toxRouting tox)
)
-- TODO: Don't export this. The exported interface is 'toxAnnounceToLan'.
announceToLan :: Socket -> NodeId -> IO ()
announceToLan sock nid = do
addrs <- broadcastAddrs
forM_ addrs $ \addr -> do
(broadcast_info:_) <- getAddrInfo (Just defaultHints { addrFlags = [AI_NUMERICHOST], addrSocketType = Datagram })
(Just addr)
(Just "33445")
let broadcast = addrAddress broadcast_info
bs = S.runPut $ DHT.putMessage (DHT.DHTLanDiscovery nid)
dput XLan $ show broadcast ++ " <-- LanAnnounce " ++ show nid
saferSendTo sock bs broadcast
toxQSearch :: Tox extra -> Search NodeId (IP, PortNumber) Nonce32 NodeInfo Onion.Rendezvous
toxQSearch tox = Onion.toxidSearch (onionTimeout tox) (toxCryptoKeys tox) (toxOnion tox)
|