func tryCapture(iface net.Interface) error { if iface.Name[:2] == "lo" { return fmt.Errorf("skipping loopback") } var h *pcap.Handle var err error switch *mode { case "basic": h, err = pcap.OpenLive(iface.Name, 65536, false, time.Second*3) if err != nil { return fmt.Errorf("openlive: %v", err) } defer h.Close() case "filtered": h, err = pcap.OpenLive(iface.Name, 65536, false, time.Second*3) if err != nil { return fmt.Errorf("openlive: %v", err) } defer h.Close() if err := h.SetBPFFilter("port 80 or port 443"); err != nil { return fmt.Errorf("setbpf: %v", err) } case "timestamp": u, err := pcap.NewInactiveHandle(iface.Name) if err != nil { return err } defer u.CleanUp() if err = u.SetSnapLen(65536); err != nil { return err } else if err = u.SetPromisc(false); err != nil { return err } else if err = u.SetTimeout(time.Second * 3); err != nil { return err } sources := u.SupportedTimestamps() if len(sources) == 0 { return fmt.Errorf("no supported timestamp sources") } else if err := u.SetTimestampSource(sources[0]); err != nil { return fmt.Errorf("settimestampsource(%v): %v", sources[0], err) } else if h, err = u.Activate(); err != nil { return fmt.Errorf("could not activate: %v", err) } defer h.Close() default: panic("Invalid --mode: " + *mode) } go generatePackets() h.ReadPacketData() // Do one dummy read to clear any timeouts. data, ci, err := h.ReadPacketData() if err != nil { return fmt.Errorf("readpacketdata: %v", err) } log.Printf("Read packet, %v bytes, CI: %+v", len(data), ci) return nil }
func main() { defer util.Run()() var handle *pcap.Handle var err error // Set up pcap packet capture if *fname != "" { log.Printf("Reading from pcap dump %q", *fname) handle, err = pcap.OpenOffline(*fname) } else { log.Printf("Starting capture on interface %q", *iface) handle, err = pcap.OpenLive(*iface, int32(*snaplen), true, pcap.BlockForever) } if err != nil { log.Fatal(err) } if err := handle.SetBPFFilter(*filter); err != nil { log.Fatal(err) } // Set up assembly streamFactory := &httpStreamFactory{} streamPool := tcpassembly.NewStreamPool(streamFactory) assembler := tcpassembly.NewAssembler(streamPool) log.Println("reading in packets") // Read in packets, pass to assembler. packetSource := gopacket.NewPacketSource(handle, handle.LinkType()) packets := packetSource.Packets() ticker := time.Tick(time.Minute) for { select { case packet := <-packets: // A nil packet indicates the end of a pcap file. if packet == nil { return } if *logAllPackets { log.Println(packet) } if packet.NetworkLayer() == nil || packet.TransportLayer() == nil || packet.TransportLayer().LayerType() != layers.LayerTypeTCP { log.Println("Unusable packet") continue } tcp := packet.TransportLayer().(*layers.TCP) assembler.AssembleWithTimestamp(packet.NetworkLayer().NetworkFlow(), tcp, packet.Metadata().Timestamp) case <-ticker: // Every minute, flush connections that haven't seen activity in the past 2 minutes. assembler.FlushOlderThan(time.Now().Add(time.Minute * -2)) } } }
// scan scans an individual interface's local network for machines using ARP requests/replies. // // scan loops forever, sending packets out regularly. It returns an error if // it's ever unable to write a packet. func scan(iface *net.Interface) error { // We just look for IPv4 addresses, so try to find if the interface has one. var addr *net.IPNet if addrs, err := iface.Addrs(); err != nil { return err } else { for _, a := range addrs { if ipnet, ok := a.(*net.IPNet); ok { if ip4 := ipnet.IP.To4(); ip4 != nil { addr = &net.IPNet{ IP: ip4, Mask: ipnet.Mask[len(ipnet.Mask)-4:], } break } } } } // Sanity-check that the interface has a good address. if addr == nil { return fmt.Errorf("no good IP network found") } else if addr.IP[0] == 127 { return fmt.Errorf("skipping localhost") } else if addr.Mask[0] != 0xff || addr.Mask[1] != 0xff { return fmt.Errorf("mask means network is too large") } log.Printf("Using network range %v for interface %v", addr, iface.Name) // Open up a pcap handle for packet reads/writes. handle, err := pcap.OpenLive(iface.Name, 65536, true, pcap.BlockForever) if err != nil { return err } defer handle.Close() // Start up a goroutine to read in packet data. stop := make(chan struct{}) go readARP(handle, iface, stop) defer close(stop) for { // Write our scan packets out to the handle. if err := writeARP(handle, iface, addr); err != nil { log.Printf("error writing packets on %v: %v", iface.Name, err) return err } // We don't know exactly how long it'll take for packets to be // sent back to us, but 10 seconds should be more than enough // time ;) time.Sleep(10 * time.Second) } }
func main() { defer util.Run()() log.Printf("starting capture on interface %q", *iface) // Set up pcap packet capture handle, err := pcap.OpenLive(*iface, int32(*snaplen), true, pcap.BlockForever) if err != nil { panic(err) } if err := handle.SetBPFFilter(*filter); err != nil { panic(err) } // Set up assembly streamFactory := &myFactory{bidiMap: make(map[key]*bidi)} streamPool := tcpassembly.NewStreamPool(streamFactory) assembler := tcpassembly.NewAssembler(streamPool) log.Println("reading in packets") // Read in packets, pass to assembler. packetSource := gopacket.NewPacketSource(handle, handle.LinkType()) packets := packetSource.Packets() ticker := time.Tick(timeout / 4) for { select { case packet := <-packets: if *logAllPackets { log.Println(packet) } if packet.NetworkLayer() == nil || packet.TransportLayer() == nil || packet.TransportLayer().LayerType() != layers.LayerTypeTCP { log.Println("Unusable packet") continue } tcp := packet.TransportLayer().(*layers.TCP) assembler.AssembleWithTimestamp(packet.NetworkLayer().NetworkFlow(), tcp, packet.Metadata().Timestamp) case <-ticker: // Every minute, flush connections that haven't seen activity in the past minute. log.Println("---- FLUSHING ----") assembler.FlushOlderThan(time.Now().Add(-timeout)) streamFactory.collectOldStreams() } } }
func main() { defer util.Run()() flushDuration, err := time.ParseDuration(*flushAfter) if err != nil { log.Fatal("invalid flush duration: ", *flushAfter) } log.Printf("starting capture on interface %q", *iface) // Set up pcap packet capture handle, err := pcap.OpenLive(*iface, int32(*snaplen), true, flushDuration/2) if err != nil { log.Fatal("error opening pcap handle: ", err) } if err := handle.SetBPFFilter(*filter); err != nil { log.Fatal("error setting BPF filter: ", err) } // Set up assembly streamFactory := &statsStreamFactory{} streamPool := tcpassembly.NewStreamPool(streamFactory) assembler := tcpassembly.NewAssembler(streamPool) assembler.MaxBufferedPagesPerConnection = *bufferedPerConnection assembler.MaxBufferedPagesTotal = *bufferedTotal log.Println("reading in packets") // We use a DecodingLayerParser here instead of a simpler PacketSource. // This approach should be measurably faster, but is also more rigid. // PacketSource will handle any known type of packet safely and easily, // but DecodingLayerParser will only handle those packet types we // specifically pass in. This trade-off can be quite useful, though, in // high-throughput situations. var eth layers.Ethernet var dot1q layers.Dot1Q var ip4 layers.IPv4 var ip6 layers.IPv6 var ip6extensions layers.IPv6ExtensionSkipper var tcp layers.TCP var payload gopacket.Payload parser := gopacket.NewDecodingLayerParser(layers.LayerTypeEthernet, ð, &dot1q, &ip4, &ip6, &ip6extensions, &tcp, &payload) decoded := make([]gopacket.LayerType, 0, 4) nextFlush := time.Now().Add(flushDuration / 2) var byteCount int64 start := time.Now() loop: for ; *packetCount != 0; *packetCount-- { // Check to see if we should flush the streams we have // that haven't seen any new data in a while. Note we set a // timeout on our PCAP handle, so this should happen even if we // never see packet data. if time.Now().After(nextFlush) { stats, _ := handle.Stats() log.Printf("flushing all streams that haven't seen packets in the last 2 minutes, pcap stats: %+v", stats) assembler.FlushOlderThan(time.Now().Add(flushDuration)) nextFlush = time.Now().Add(flushDuration / 2) } // To speed things up, we're also using the ZeroCopy method for // reading packet data. This method is faster than the normal // ReadPacketData, but the returned bytes in 'data' are // invalidated by any subsequent ZeroCopyReadPacketData call. // Note that tcpassembly is entirely compatible with this packet // reading method. This is another trade-off which might be // appropriate for high-throughput sniffing: it avoids a packet // copy, but its cost is much more careful handling of the // resulting byte slice. data, ci, err := handle.ZeroCopyReadPacketData() if err != nil { log.Printf("error getting packet: %v", err) continue } err = parser.DecodeLayers(data, &decoded) if err != nil { log.Printf("error decoding packet: %v", err) continue } if *logAllPackets { log.Printf("decoded the following layers: %v", decoded) } byteCount += int64(len(data)) // Find either the IPv4 or IPv6 address to use as our network // layer. foundNetLayer := false var netFlow gopacket.Flow for _, typ := range decoded { switch typ { case layers.LayerTypeIPv4: netFlow = ip4.NetworkFlow() foundNetLayer = true case layers.LayerTypeIPv6: netFlow = ip6.NetworkFlow() foundNetLayer = true case layers.LayerTypeTCP: if foundNetLayer { assembler.AssembleWithTimestamp(netFlow, &tcp, ci.Timestamp) } else { log.Println("could not find IPv4 or IPv6 layer, inoring") } continue loop } } log.Println("could not find TCP layer") } assembler.FlushAll() log.Printf("processed %d bytes in %v", byteCount, time.Since(start)) }