// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // Package sniffer provides the implementation of data-link layer endpoints that // wrap another endpoint and logs inbound and outbound packets. // // Sniffer endpoints can be used in the networking stack by calling New(eID) to // create a new endpoint, where eID is the ID of the endpoint being wrapped, // and then passing it as an argument to Stack.CreateNIC(). package sniffer import ( "encoding/binary" "fmt" "io" "sync/atomic" "time" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/header/parse" "gvisor.dev/gvisor/pkg/tcpip/link/nested" "gvisor.dev/gvisor/pkg/tcpip/stack" ) // LogPackets is a flag used to enable or disable packet logging via the log // package. Valid values are 0 or 1. // // LogPackets must be accessed atomically. var LogPackets uint32 = 1 // LogPacketsToPCAP is a flag used to enable or disable logging packets to a // pcap writer. Valid values are 0 or 1. A writer must have been specified when the // sniffer was created for this flag to have effect. // // LogPacketsToPCAP must be accessed atomically. var LogPacketsToPCAP uint32 = 1 type endpoint struct { nested.Endpoint writer io.Writer maxPCAPLen uint32 logPrefix string } var _ stack.GSOEndpoint = (*endpoint)(nil) var _ stack.LinkEndpoint = (*endpoint)(nil) var _ stack.NetworkDispatcher = (*endpoint)(nil) type direction int const ( directionSend = iota directionRecv ) // New creates a new sniffer link-layer endpoint. It wraps around another // endpoint and logs packets and they traverse the endpoint. func New(lower stack.LinkEndpoint) stack.LinkEndpoint { return NewWithPrefix(lower, "") } // NewWithPrefix creates a new sniffer link-layer endpoint. It wraps around // another endpoint and logs packets prefixed with logPrefix as they traverse // the endpoint. // // logPrefix is prepended to the log line without any separators. // E.g. logPrefix = "NIC:en0/" will produce log lines like // "NIC:en0/send udp [...]". func NewWithPrefix(lower stack.LinkEndpoint, logPrefix string) stack.LinkEndpoint { sniffer := &endpoint{logPrefix: logPrefix} sniffer.Endpoint.Init(lower, sniffer) return sniffer } func zoneOffset() (int32, error) { date := time.Date(0, 0, 0, 0, 0, 0, 0, time.Local) _, offset := date.Zone() return int32(offset), nil } func writePCAPHeader(w io.Writer, maxLen uint32) error { offset, err := zoneOffset() if err != nil { return err } return binary.Write(w, binary.BigEndian, pcapHeader{ // From https://wiki.wireshark.org/Development/LibpcapFileFormat MagicNumber: 0xa1b2c3d4, VersionMajor: 2, VersionMinor: 4, Thiszone: offset, Sigfigs: 0, Snaplen: maxLen, Network: 101, // LINKTYPE_RAW }) } // NewWithWriter creates a new sniffer link-layer endpoint. It wraps around // another endpoint and logs packets as they traverse the endpoint. // // Each packet is written to writer in the pcap format in a single Write call // without synchronization. A sniffer created with this function will not emit // packets using the standard log package. // // snapLen is the maximum amount of a packet to be saved. Packets with a length // less than or equal to snapLen will be saved in their entirety. Longer // packets will be truncated to snapLen. func NewWithWriter(lower stack.LinkEndpoint, writer io.Writer, snapLen uint32) (stack.LinkEndpoint, error) { if err := writePCAPHeader(writer, snapLen); err != nil { return nil, err } sniffer := &endpoint{ writer: writer, maxPCAPLen: snapLen, } sniffer.Endpoint.Init(lower, sniffer) return sniffer, nil } // DeliverNetworkPacket implements the stack.NetworkDispatcher interface. It is // called by the link-layer endpoint being wrapped when a packet arrives, and // logs the packet before forwarding to the actual dispatcher. func (e *endpoint) DeliverNetworkPacket(remote, local tcpip.LinkAddress, protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) { e.dumpPacket(directionRecv, protocol, pkt) e.Endpoint.DeliverNetworkPacket(remote, local, protocol, pkt) } func (e *endpoint) dumpPacket(dir direction, protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) { writer := e.writer if writer == nil && atomic.LoadUint32(&LogPackets) == 1 { logPacket(e.logPrefix, dir, protocol, pkt) } if writer != nil && atomic.LoadUint32(&LogPacketsToPCAP) == 1 { packet := pcapPacket{ timestamp: time.Now(), packet: pkt, maxCaptureLen: int(e.maxPCAPLen), } b, err := packet.MarshalBinary() if err != nil { panic(err) } if _, err := writer.Write(b); err != nil { panic(err) } } } // WritePacket implements the stack.LinkEndpoint interface. It is called by // higher-level protocols to write packets; it just logs the packet and // forwards the request to the lower endpoint. func (e *endpoint) WritePacket(r stack.RouteInfo, protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) tcpip.Error { e.dumpPacket(directionSend, protocol, pkt) return e.Endpoint.WritePacket(r, protocol, pkt) } // WritePackets implements the stack.LinkEndpoint interface. It is called by // higher-level protocols to write packets; it just logs the packet and // forwards the request to the lower endpoint. func (e *endpoint) WritePackets(r stack.RouteInfo, pkts stack.PacketBufferList, protocol tcpip.NetworkProtocolNumber) (int, tcpip.Error) { for pkt := pkts.Front(); pkt != nil; pkt = pkt.Next() { e.dumpPacket(directionSend, protocol, pkt) } return e.Endpoint.WritePackets(r, pkts, protocol) } func logPacket(prefix string, dir direction, protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) { // Figure out the network layer info. var transProto uint8 src := tcpip.Address("unknown") dst := tcpip.Address("unknown") var size uint16 var id uint32 var fragmentOffset uint16 var moreFragments bool var directionPrefix string switch dir { case directionSend: directionPrefix = "send" case directionRecv: directionPrefix = "recv" default: panic(fmt.Sprintf("unrecognized direction: %d", dir)) } // Clone the packet buffer to not modify the original. // // We don't clone the original packet buffer so that the new packet buffer // does not have any of its headers set. // // We trim the link headers from the cloned buffer as the sniffer doesn't // handle link headers. vv := buffer.NewVectorisedView(pkt.Size(), pkt.Views()) vv.TrimFront(len(pkt.LinkHeader().View())) pkt = stack.NewPacketBuffer(stack.PacketBufferOptions{Data: vv}) switch protocol { case header.IPv4ProtocolNumber: if ok := parse.IPv4(pkt); !ok { return } ipv4 := header.IPv4(pkt.NetworkHeader().View()) fragmentOffset = ipv4.FragmentOffset() moreFragments = ipv4.Flags()&header.IPv4FlagMoreFragments == header.IPv4FlagMoreFragments src = ipv4.SourceAddress() dst = ipv4.DestinationAddress() transProto = ipv4.Protocol() size = ipv4.TotalLength() - uint16(ipv4.HeaderLength()) id = uint32(ipv4.ID()) case header.IPv6ProtocolNumber: proto, fragID, fragOffset, fragMore, ok := parse.IPv6(pkt) if !ok { return } ipv6 := header.IPv6(pkt.NetworkHeader().View()) src = ipv6.SourceAddress() dst = ipv6.DestinationAddress() transProto = uint8(proto) size = ipv6.PayloadLength() id = fragID moreFragments = fragMore fragmentOffset = fragOffset case header.ARPProtocolNumber: if !parse.ARP(pkt) { return } arp := header.ARP(pkt.NetworkHeader().View()) log.Infof( "%s%s arp %s (%s) -> %s (%s) valid:%t", prefix, directionPrefix, tcpip.Address(arp.ProtocolAddressSender()), tcpip.LinkAddress(arp.HardwareAddressSender()), tcpip.Address(arp.ProtocolAddressTarget()), tcpip.LinkAddress(arp.HardwareAddressTarget()), arp.IsValid(), ) return default: log.Infof("%s%s unknown network protocol", prefix, directionPrefix) return } // Figure out the transport layer info. transName := "unknown" srcPort := uint16(0) dstPort := uint16(0) details := "" switch tcpip.TransportProtocolNumber(transProto) { case header.ICMPv4ProtocolNumber: transName = "icmp" hdr, ok := pkt.Data().PullUp(header.ICMPv4MinimumSize) if !ok { break } icmp := header.ICMPv4(hdr) icmpType := "unknown" if fragmentOffset == 0 { switch icmp.Type() { case header.ICMPv4EchoReply: icmpType = "echo reply" case header.ICMPv4DstUnreachable: icmpType = "destination unreachable" case header.ICMPv4SrcQuench: icmpType = "source quench" case header.ICMPv4Redirect: icmpType = "redirect" case header.ICMPv4Echo: icmpType = "echo" case header.ICMPv4TimeExceeded: icmpType = "time exceeded" case header.ICMPv4ParamProblem: icmpType = "param problem" case header.ICMPv4Timestamp: icmpType = "timestamp" case header.ICMPv4TimestampReply: icmpType = "timestamp reply" case header.ICMPv4InfoRequest: icmpType = "info request" case header.ICMPv4InfoReply: icmpType = "info reply" } } log.Infof("%s%s %s %s -> %s %s len:%d id:%04x code:%d", prefix, directionPrefix, transName, src, dst, icmpType, size, id, icmp.Code()) return case header.ICMPv6ProtocolNumber: transName = "icmp" hdr, ok := pkt.Data().PullUp(header.ICMPv6MinimumSize) if !ok { break } icmp := header.ICMPv6(hdr) icmpType := "unknown" switch icmp.Type() { case header.ICMPv6DstUnreachable: icmpType = "destination unreachable" case header.ICMPv6PacketTooBig: icmpType = "packet too big" case header.ICMPv6TimeExceeded: icmpType = "time exceeded" case header.ICMPv6ParamProblem: icmpType = "param problem" case header.ICMPv6EchoRequest: icmpType = "echo request" case header.ICMPv6EchoReply: icmpType = "echo reply" case header.ICMPv6RouterSolicit: icmpType = "router solicit" case header.ICMPv6RouterAdvert: icmpType = "router advert" case header.ICMPv6NeighborSolicit: icmpType = "neighbor solicit" case header.ICMPv6NeighborAdvert: icmpType = "neighbor advert" case header.ICMPv6RedirectMsg: icmpType = "redirect message" } log.Infof("%s%s %s %s -> %s %s len:%d id:%04x code:%d", prefix, directionPrefix, transName, src, dst, icmpType, size, id, icmp.Code()) return case header.UDPProtocolNumber: transName = "udp" if ok := parse.UDP(pkt); !ok { break } udp := header.UDP(pkt.TransportHeader().View()) if fragmentOffset == 0 { srcPort = udp.SourcePort() dstPort = udp.DestinationPort() details = fmt.Sprintf("xsum: 0x%x", udp.Checksum()) size -= header.UDPMinimumSize } case header.TCPProtocolNumber: transName = "tcp" if ok := parse.TCP(pkt); !ok { break } tcp := header.TCP(pkt.TransportHeader().View()) if fragmentOffset == 0 { offset := int(tcp.DataOffset()) if offset < header.TCPMinimumSize { details += fmt.Sprintf("invalid packet: tcp data offset too small %d", offset) break } if size := pkt.Data().Size() + len(tcp); offset > size && !moreFragments { details += fmt.Sprintf("invalid packet: tcp data offset %d larger than tcp packet length %d", offset, size) break } srcPort = tcp.SourcePort() dstPort = tcp.DestinationPort() size -= uint16(offset) // Initialize the TCP flags. flags := tcp.Flags() details = fmt.Sprintf("flags: %s seqnum: %d ack: %d win: %d xsum:0x%x", flags, tcp.SequenceNumber(), tcp.AckNumber(), tcp.WindowSize(), tcp.Checksum()) if flags&header.TCPFlagSyn != 0 { details += fmt.Sprintf(" options: %+v", header.ParseSynOptions(tcp.Options(), flags&header.TCPFlagAck != 0)) } else { details += fmt.Sprintf(" options: %+v", tcp.ParsedOptions()) } } default: log.Infof("%s%s %s -> %s unknown transport protocol: %d", prefix, directionPrefix, src, dst, transProto) return } if pkt.GSOOptions.Type != stack.GSONone { details += fmt.Sprintf(" gso: %#v", pkt.GSOOptions) } log.Infof("%s%s %s %s:%d -> %s:%d len:%d id:%04x %s", prefix, directionPrefix, transName, src, srcPort, dst, dstPort, size, id, details) }