package cli import ( "context" "encoding/binary" "errors" "fmt" "log" "net" "os" "os/signal" "path/filepath" "runtime" "strconv" "strings" "syscall" "time" "github.com/DataDrake/cli-ng/v2/cmd" "github.com/hyprspace/hyprspace/config" "github.com/hyprspace/hyprspace/p2p" "github.com/hyprspace/hyprspace/tun" "github.com/libp2p/go-libp2p-core/host" "github.com/libp2p/go-libp2p-core/network" "github.com/libp2p/go-libp2p-core/peer" "github.com/nxadm/tail" ) var ( // iface is the tun device used to pass packets between // Hyprspace and the user's machine. tunDev *tun.TUN // RevLookup allow quick lookups of an incoming stream // for security before accepting or responding to any data. RevLookup map[string]string // activeStreams is a map of active streams to a peer activeStreams map[string]network.Stream ) // Up creates and brings up a Hyprspace Interface. var Up = cmd.Sub{ Name: "up", Alias: "up", Short: "Create and Bring Up a Hyprspace Interface.", Args: &UpArgs{}, Flags: &UpFlags{}, Run: UpRun, } // UpArgs handles the specific arguments for the up command. type UpArgs struct { InterfaceName string } // UpFlags handles the specific flags for the up command. type UpFlags struct { Foreground bool `short:"f" long:"foreground" desc:"Don't Create Background Daemon."` } // UpRun handles the execution of the up command. func UpRun(r *cmd.Root, c *cmd.Sub) { // Parse Command Args args := c.Args.(*UpArgs) // Parse Command Flags flags := c.Flags.(*UpFlags) // Parse Global Config Flag for Custom Config Path configPath := r.Flags.(*GlobalFlags).Config if configPath == "" { configPath = "/etc/hyprspace/" + args.InterfaceName + ".yaml" } // Read in configuration from file. cfg, err := config.Read(configPath) checkErr(err) if !flags.Foreground { if err := createDaemon(cfg); err != nil { fmt.Println("[+] Failed to Create Hyprspace Daemon") fmt.Println(err) } else { fmt.Println("[+] Successfully Created Hyprspace Daemon") } return } // Setup reverse lookup hash map for authentication. RevLookup = make(map[string]string, len(cfg.Peers)) for ip, id := range cfg.Peers { RevLookup[id.ID] = ip } fmt.Println("[+] Creating TUN Device") if runtime.GOOS == "darwin" { if len(cfg.Peers) > 1 { checkErr(errors.New("cannot create interface macos does not support more than one peer")) } // Grab ip address of only peer in config var destPeer string for ip := range cfg.Peers { destPeer = ip } // Create new TUN device tunDev, err = tun.New( cfg.Interface.Name, tun.Address(cfg.Interface.Address), tun.DestAddress(destPeer), tun.MTU(1420), ) } else { // Create new TUN device tunDev, err = tun.New( cfg.Interface.Name, tun.Address(cfg.Interface.Address), tun.MTU(1420), ) } if err != nil { checkErr(err) } // Setup System Context ctx := context.Background() fmt.Println("[+] Creating LibP2P Node") // Check that the listener port is available. port, err := verifyPort(cfg.Interface.ListenPort) checkErr(err) // Create P2P Node host, dht, err := p2p.CreateNode( ctx, cfg.Interface.PrivateKey, port, streamHandler, ) checkErr(err) // Setup Peer Table for Quick Packet --> Dest ID lookup peerTable := make(map[string]peer.ID) for ip, id := range cfg.Peers { peerTable[ip], err = peer.Decode(id.ID) checkErr(err) } fmt.Println("[+] Setting Up Node Discovery via DHT") // Setup P2P Discovery go p2p.Discover(ctx, host, dht, peerTable) go prettyDiscovery(ctx, host, peerTable) // Configure path for lock lockPath := filepath.Join(filepath.Dir(cfg.Path), cfg.Interface.Name+".lock") // Register the application to listen for SIGINT/SIGTERM go signalExit(host, lockPath) // Write lock to filesystem to indicate an existing running daemon. err = os.WriteFile(lockPath, []byte(fmt.Sprint(os.Getpid())), os.ModePerm) checkErr(err) // Bring Up TUN Device err = tunDev.Up() if err != nil { checkErr(errors.New("unable to bring up tun device")) } fmt.Println("[+] Network Setup Complete...Waiting on Node Discovery") // + ----------------------------------------+ // | Listen For New Packets on TUN Interface | // + ----------------------------------------+ // Initialize active streams map and packet byte array. activeStreams = make(map[string]network.Stream) var packet = make([]byte, 1420) for { // Read in a packet from the tun device. plen, err := tunDev.Iface.Read(packet) if err != nil { log.Println(err) continue } // Decode the packet's destination address dst := net.IPv4(packet[16], packet[17], packet[18], packet[19]).String() // Check if we already have an open connection to the destination peer. stream, ok := activeStreams[dst] if ok { // Write out the packet's length to the libp2p stream to ensure // we know the full size of the packet at the other end. err = binary.Write(stream, binary.LittleEndian, uint16(plen)) if err == nil { // Write the packet out to the libp2p stream. // If everyting succeeds continue on to the next packet. _, err = stream.Write(packet[:plen]) if err == nil { continue } } // If we encounter an error when writing to a stream we should // close that stream and delete it from the active stream map. stream.Close() delete(activeStreams, dst) } // Check if the destination of the packet is a known peer to // the interface. if peer, ok := peerTable[dst]; ok { stream, err = host.NewStream(ctx, peer, p2p.Protocol) if err != nil { continue } // Write packet length err = binary.Write(stream, binary.LittleEndian, uint16(plen)) if err != nil { stream.Close() continue } // Write the packet _, err = stream.Write(packet[:plen]) if err != nil { stream.Close() continue } // If all succeeds when writing the packet to the stream // we should reuse this stream by adding it active streams map. activeStreams[dst] = stream } } } // singalExit registers two syscall handlers on the system so that if // an SIGINT or SIGTERM occur on the system hyprspace can gracefully // shutdown and remove the filesystem lock file. func signalExit(host host.Host, lockPath string) { // Wait for a SIGINT or SIGTERM signal ch := make(chan os.Signal, 1) signal.Notify(ch, syscall.SIGINT, syscall.SIGTERM) <-ch // Shut the node down err := host.Close() checkErr(err) // Remove daemon lock from file system. err = os.Remove(lockPath) checkErr(err) fmt.Println("Received signal, shutting down...") // Exit the application. os.Exit(0) } // createDaemon handles creating an independent background process for a // Hyprspace daemon from the original parent process. func createDaemon(cfg *config.Config) error { path, err := os.Executable() checkErr(err) // Generate log path logPath := filepath.Join(filepath.Dir(cfg.Path), cfg.Interface.Name+".log") // Create Pipe to monitor for daemon output. f, err := os.Create(logPath) checkErr(err) // Create Sub Process process, err := os.StartProcess( path, append(os.Args, "--foreground"), &os.ProcAttr{ Dir: ".", Env: os.Environ(), Files: []*os.File{nil, f, f}, }, ) checkErr(err) // Listen to the child process's log output to determine // when the daemon is setup and connected to a set of peers. count := 0 deadlineHit := false countChan := make(chan int) go func(out chan<- int) { numConnected := 0 t, err := tail.TailFile(logPath, tail.Config{Follow: true}) if err != nil { out <- numConnected return } for line := range t.Lines { fmt.Println(line.Text) if strings.HasPrefix(line.Text, "[+] Connection to") { numConnected++ if numConnected >= len(cfg.Peers) { break } } } out <- numConnected }(countChan) // Block until all clients are connected or for a maximum of 30s. select { case _, deadlineHit = <-time.After(30 * time.Second): case count = <-countChan: } // Release the created daemon err = process.Release() checkErr(err) // Check if the daemon exited prematurely if !deadlineHit && count < len(cfg.Peers) { return errors.New("failed to create daemon") } return nil } func streamHandler(stream network.Stream) { // If the remote node ID isn't in the list of known nodes don't respond. if _, ok := RevLookup[stream.Conn().RemotePeer().Pretty()]; !ok { stream.Reset() return } var packet = make([]byte, 1420) var packetSize = make([]byte, 2) for { // Read the incoming packet's size as a binary value. _, err := stream.Read(packetSize) if err != nil { stream.Close() return } // Decode the incoming packet's size from binary. size := binary.LittleEndian.Uint16(packetSize) // Read in the packet until completion. var plen uint16 = 0 for plen < size { tmp, err := stream.Read(packet[plen:size]) plen += uint16(tmp) if err != nil { stream.Close() return } } tunDev.Iface.Write(packet[:size]) } } func prettyDiscovery(ctx context.Context, node host.Host, peerTable map[string]peer.ID) { // Build a temporary map of peers to limit querying to only those // not connected. tempTable := make(map[string]peer.ID, len(peerTable)) for ip, id := range peerTable { tempTable[ip] = id } for len(tempTable) > 0 { for ip, id := range tempTable { stream, err := node.NewStream(ctx, id, p2p.Protocol) if err != nil && (strings.HasPrefix(err.Error(), "failed to dial") || strings.HasPrefix(err.Error(), "no addresses")) { // Attempt to connect to peers slowly when they aren't found. time.Sleep(5 * time.Second) continue } if err == nil { fmt.Printf("[+] Connection to %s Successful. Network Ready.\n", ip) stream.Close() } delete(tempTable, ip) } } } func verifyPort(port int) (int, error) { var ln net.Listener var err error // If a user manually sets a port don't try to automatically // find an open port. if port != 8001 { ln, err = net.Listen("tcp", ":"+strconv.Itoa(port)) if err != nil { return port, errors.New("could not create node, listen port already in use by something else") } } else { // Automatically look for an open port when a custom port isn't // selected by a user. for { ln, err = net.Listen("tcp", ":"+strconv.Itoa(port)) if err == nil { break } if port >= 65535 { return port, errors.New("failed to find open port") } port++ } } if ln != nil { ln.Close() } return port, nil }