func handleTCP(conn *net.TCPConn, timeouted, rehandshaking, termination chan struct{}) {
hs := govpn.HandshakeStart(*remoteAddr, conn, conf)
buf := make([]byte, govpn.MTU)
var n int
var err error
var prev int
var peer *govpn.Peer
var terminator chan struct{}
HandshakeCycle:
for {
select {
case <-termination:
break HandshakeCycle
default:
}
if prev == govpn.MTU {
log.Println("Timeouted waiting for the packet")
timeouted <- struct{}{}
break HandshakeCycle
}
conn.SetReadDeadline(time.Now().Add(time.Duration(timeout) * time.Second))
n, err = conn.Read(buf[prev:])
if err != nil {
log.Println("Connection timeouted")
timeouted <- struct{}{}
break HandshakeCycle
}
prev += n
peerId := idsCache.Find(buf[:prev])
if peerId == nil {
continue
}
peer = hs.Client(buf[:prev])
prev = 0
if peer == nil {
continue
}
log.Println("Handshake completed")
knownPeers = govpn.KnownPeers(map[string]**govpn.Peer{*remoteAddr: &peer})
if firstUpCall {
go govpn.ScriptCall(*upPath, *ifaceName)
firstUpCall = false
}
hs.Zero()
terminator = make(chan struct{})
go func() {
heartbeat := time.NewTicker(peer.Timeout)
var data []byte
Processor:
for {
select {
case <-heartbeat.C:
peer.EthProcess(nil)
case <-terminator:
break Processor
case data = <-tap.Sink:
peer.EthProcess(data)
}
}
heartbeat.Stop()
peer.Zero()
}()
break HandshakeCycle
}
if hs != nil {
hs.Zero()
}
if peer == nil {
return
}
nonceExpectation := make([]byte, govpn.NonceSize)
peer.NonceExpectation(nonceExpectation)
prev = 0
var i int
TransportCycle:
for {
select {
case <-termination:
break TransportCycle
default:
}
if prev == govpn.MTU {
log.Println("Timeouted waiting for the packet")
timeouted <- struct{}{}
break TransportCycle
}
conn.SetReadDeadline(time.Now().Add(time.Duration(timeout) * time.Second))
n, err = conn.Read(buf[prev:])
if err != nil {
log.Println("Connection timeouted")
timeouted <- struct{}{}
break TransportCycle
}
prev += n
CheckMore:
if prev < govpn.MinPktLength {
continue
}
i = bytes.Index(buf[:prev], nonceExpectation)
if i == -1 {
continue
}
if !peer.PktProcess(buf[:i+govpn.NonceSize], tap, false) {
log.Println("Unauthenticated packet, dropping connection")
timeouted <- struct{}{}
break TransportCycle
}
if atomic.LoadInt64(&peer.BytesIn)+atomic.LoadInt64(&peer.BytesOut) > govpn.MaxBytesPerKey {
log.Println("Need rehandshake")
rehandshaking <- struct{}{}
break TransportCycle
}
peer.NonceExpectation(nonceExpectation)
copy(buf, buf[i+govpn.NonceSize:prev])
prev = prev - i - govpn.NonceSize
goto CheckMore
}
if terminator != nil {
terminator <- struct{}{}
}
peer.Zero()
conn.Close()
}
func handleTCP(conn net.Conn) {
addr := conn.RemoteAddr().String()
buf := make([]byte, govpn.MTU)
var n int
var err error
var prev int
var hs *govpn.Handshake
var ps *PeerState
var peer *govpn.Peer
var tap *govpn.TAP
var conf *govpn.PeerConf
for {
if prev == govpn.MTU {
break
}
conn.SetReadDeadline(time.Now().Add(time.Duration(govpn.TimeoutDefault) * time.Second))
n, err = conn.Read(buf[prev:])
if err != nil {
// Either EOFed or timeouted
break
}
prev += n
peerId := idsCache.Find(buf[:prev])
if peerId == nil {
continue
}
if hs == nil {
conf = confs[*peerId]
if conf == nil {
log.Println("Can not get peer configuration:", peerId.String())
break
}
hs = govpn.NewHandshake(addr, conn, conf)
}
peer = hs.Server(buf[:prev])
prev = 0
if peer == nil {
continue
}
hs.Zero()
log.Println("Peer handshake finished:", addr, peer.Id.String())
peersByIdLock.RLock()
addrPrev, exists := peersById[*peer.Id]
peersByIdLock.RUnlock()
if exists {
peersLock.Lock()
peers[addrPrev].terminator <- struct{}{}
tap = peers[addrPrev].tap
ps = &PeerState{
peer: peer,
tap: tap,
terminator: make(chan struct{}),
}
go peerReady(*ps)
peersByIdLock.Lock()
kpLock.Lock()
delete(peers, addrPrev)
delete(knownPeers, addrPrev)
peers[addr] = ps
knownPeers[addr] = &peer
peersById[*peer.Id] = addr
peersLock.Unlock()
peersByIdLock.Unlock()
kpLock.Unlock()
log.Println("Rehandshake processed:", peer.Id.String())
} else {
ifaceName, err := callUp(peer.Id)
if err != nil {
break
}
tap, err = govpn.TAPListen(ifaceName)
if err != nil {
log.Println("Unable to create TAP:", err)
break
}
ps = &PeerState{
peer: peer,
tap: tap,
terminator: make(chan struct{}, 1),
}
go peerReady(*ps)
peersLock.Lock()
peersByIdLock.Lock()
kpLock.Lock()
peers[addr] = ps
peersById[*peer.Id] = addr
knownPeers[addr] = &peer
peersLock.Unlock()
peersByIdLock.Unlock()
kpLock.Unlock()
log.Println("Peer created:", peer.Id.String())
}
break
}
if hs != nil {
hs.Zero()
}
if peer == nil {
return
}
nonceExpectation := make([]byte, govpn.NonceSize)
peer.NonceExpectation(nonceExpectation)
prev = 0
var i int
for {
if prev == govpn.MTU {
break
}
conn.SetReadDeadline(time.Now().Add(conf.Timeout))
n, err = conn.Read(buf[prev:])
if err != nil {
// Either EOFed or timeouted
break
}
prev += n
CheckMore:
if prev < govpn.MinPktLength {
continue
}
i = bytes.Index(buf[:prev], nonceExpectation)
if i == -1 {
continue
}
if !peer.PktProcess(buf[:i+govpn.NonceSize], tap, false) {
log.Println(
"Unauthenticated packet, dropping connection",
addr, peer.Id.String(),
)
break
}
peer.NonceExpectation(nonceExpectation)
copy(buf, buf[i+govpn.NonceSize:prev])
prev = prev - i - govpn.NonceSize
goto CheckMore
}
peer.Zero()
}