package tunnel import ( "crypto/sha256" "errors" "fmt" "sync" "github.com/google/uuid" "github.com/micro/go-micro/transport" "github.com/micro/go-micro/util/log" ) // tun represents a network tunnel type tun struct { options Options sync.RWMutex // to indicate if we're connected or not connected bool // the send channel for all messages send chan *message // close channel closed chan bool // a map of sockets based on Micro-Tunnel-Id sockets map[string]*socket // outbound links links map[string]*link // listener listener transport.Listener } type link struct { transport.Socket id string } // create new tunnel on top of a link func newTunnel(opts ...Option) *tun { options := DefaultOptions() for _, o := range opts { o(&options) } return &tun{ options: options, send: make(chan *message, 128), closed: make(chan bool), sockets: make(map[string]*socket), links: make(map[string]*link), } } // getSocket returns a socket from the internal socket map. // It does this based on the Micro-Tunnel-Id and Micro-Tunnel-Session func (t *tun) getSocket(id, session string) (*socket, bool) { // get the socket t.RLock() s, ok := t.sockets[id+session] t.RUnlock() return s, ok } // newSocket creates a new socket and saves it func (t *tun) newSocket(id, session string) (*socket, bool) { // hash the id h := sha256.New() h.Write([]byte(id)) id = fmt.Sprintf("%x", h.Sum(nil)) // new socket s := &socket{ id: id, session: session, closed: make(chan bool), recv: make(chan *message, 128), send: t.send, wait: make(chan bool), } // save socket t.Lock() _, ok := t.sockets[id+session] if ok { // socket already exists t.Unlock() return nil, false } t.sockets[id+session] = s t.Unlock() // return socket return s, true } // TODO: use tunnel id as part of the session func (t *tun) newSession() string { return uuid.New().String() } // process outgoing messages sent by all local sockets func (t *tun) process() { // manage the send buffer // all pseudo sockets throw everything down this for { select { case msg := <-t.send: nmsg := &transport.Message{ Header: msg.data.Header, Body: msg.data.Body, } if nmsg.Header == nil { nmsg.Header = make(map[string]string) } // set the tunnel id on the outgoing message nmsg.Header["Micro-Tunnel-Id"] = msg.id // set the session id nmsg.Header["Micro-Tunnel-Session"] = msg.session // send the message via the interface t.RLock() for _, link := range t.links { link.Send(nmsg) } t.RUnlock() case <-t.closed: return } } } // process incoming messages func (t *tun) listen(link transport.Socket, listener bool) { for { // process anything via the net interface msg := new(transport.Message) err := link.Recv(msg) if err != nil { return } switch msg.Header["Micro-Tunnel"] { case "connect", "close": continue } // the tunnel id id := msg.Header["Micro-Tunnel-Id"] // the session id session := msg.Header["Micro-Tunnel-Session"] // if the session id is blank there's nothing we can do // TODO: check this is the case, is there any reason // why we'd have a blank session? Is the tunnel // used for some other purpose? if len(id) == 0 || len(session) == 0 { continue } var s *socket var exists bool // if its a local listener then we use that as the session id // e.g we're using a loopback connecting to ourselves if listener { s, exists = t.getSocket(id, "listener") } else { // get the socket based on the tunnel id and session // this could be something we dialed in which case // we have a session for it otherwise its a listener s, exists = t.getSocket(id, session) if !exists { // try get it based on just the tunnel id // the assumption here is that a listener // has no session but its set a listener session s, exists = t.getSocket(id, "listener") } } // no socket in existence if !exists { // drop it, we don't care about // messages we don't know about continue } // is the socket closed? select { case <-s.closed: // closed delete(t.sockets, id) continue default: // process } // is the socket new? select { // if its new the socket is actually blocked waiting // for a connection. so we check if its waiting. case <-s.wait: // if its waiting e.g its new then we close it default: // set remote address of the socket s.remote = msg.Header["Remote"] close(s.wait) } // construct a new transport message tmsg := &transport.Message{ Header: msg.Header, Body: msg.Body, } // construct the internal message imsg := &message{ id: id, session: session, data: tmsg, } // append to recv backlog // we don't block if we can't pass it on select { case s.recv <- imsg: default: } } } func (t *tun) connect() error { l, err := t.options.Transport.Listen(t.options.Address) if err != nil { return err } // save the listener t.listener = l go func() { // accept inbound connections err := l.Accept(func(sock transport.Socket) { // save the link id := uuid.New().String() t.Lock() t.links[id] = &link{ Socket: sock, id: id, } t.Unlock() // delete the link defer func() { t.Lock() delete(t.links, id) t.Unlock() }() // listen for inbound messages t.listen(sock, true) }) t.Lock() defer t.Unlock() // still connected but the tunnel died if err != nil && t.connected { log.Logf("Tunnel listener died: %v", err) } }() for _, node := range t.options.Nodes { c, err := t.options.Transport.Dial(node) if err != nil { log.Debugf("Tunnel failed to connect to %s: %v", node, err) continue } if err := c.Send(&transport.Message{ Header: map[string]string{ "Micro-Tunnel": "connect", }, }); err != nil { continue } // process incoming messages go t.listen(c, false) // save the link id := uuid.New().String() t.links[id] = &link{ Socket: c, id: id, } } // process outbound messages to be sent // process sends to all links go t.process() return nil } func (t *tun) close() error { // close all the links for id, link := range t.links { link.Send(&transport.Message{ Header: map[string]string{ "Micro-Tunnel": "close", }, }) link.Close() delete(t.links, id) } // close the listener return t.listener.Close() } // Close the tunnel func (t *tun) Close() error { t.Lock() defer t.Unlock() if !t.connected { return nil } select { case <-t.closed: return nil default: // close all the sockets for _, s := range t.sockets { s.Close() } // close the connection close(t.closed) t.connected = false // send a close message // we don't close the link // just the tunnel return t.close() } return nil } // Connect the tunnel func (t *tun) Connect() error { t.Lock() defer t.Unlock() // already connected if t.connected { return nil } // send the connect message if err := t.connect(); err != nil { return err } // set as connected t.connected = true // create new close channel t.closed = make(chan bool) return nil } func (t *tun) Init(opts ...Option) error { for _, o := range opts { o(&t.options) } return nil } // Dial an address func (t *tun) Dial(addr string) (Conn, error) { c, ok := t.newSocket(addr, t.newSession()) if !ok { return nil, errors.New("error dialing " + addr) } // set remote c.remote = addr // set local c.local = "local" return c, nil } // Accept a connection on the address func (t *tun) Listen(addr string) (Listener, error) { // create a new socket by hashing the address c, ok := t.newSocket(addr, "listener") if !ok { return nil, errors.New("already listening on " + addr) } // set remote. it will be replaced by the first message received c.remote = "remote" // set local c.local = addr tl := &tunListener{ addr: addr, // the accept channel accept: make(chan *socket, 128), // the channel to close closed: make(chan bool), // the connection conn: c, // the listener socket socket: c, } // this kicks off the internal message processor // for the listener so it can create pseudo sockets // per session if they do not exist or pass messages // to the existign sessions go tl.process() // return the listener return tl, nil }