// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause package vnet import ( "bytes" "encoding/binary" "errors" "fmt" "net" "net/netip" "path/filepath" "runtime" "strings" "testing" "time" "github.com/google/gopacket" "github.com/google/gopacket/layers" "tailscale.com/util/must" ) // TestPacketSideEffects tests that upon receiving certain // packets, other packets and/or log statements are generated. func TestPacketSideEffects(t *testing.T) { type netTest struct { name string pkt []byte // to send check func(*sideEffects) error } tests := []struct { netName string // name of the Server returned by setup setup func() (*Server, error) tests []netTest // to run against setup's Server }{ { netName: "basic", setup: newTwoNodesSameNetworkServer, tests: []netTest{ { name: "drop-rando-ethertype", pkt: mkEth(nodeMac(2), nodeMac(1), 0x4321, []byte("hello")), check: all( logSubstr("Dropping non-IP packet"), ), }, { name: "dst-mac-between-nodes", pkt: mkEth(nodeMac(2), nodeMac(1), testingEthertype, []byte("hello")), check: all( numPkts(1), pktSubstr("SrcMAC=52:cc:cc:cc:cc:01 DstMAC=52:cc:cc:cc:cc:02 EthernetType=UnknownEthernetType"), pktSubstr("Unable to decode EthernetType 4660"), ), }, { name: "broadcast-mac", pkt: mkEth(macBroadcast, nodeMac(1), testingEthertype, []byte("hello")), check: all( numPkts(1), pktSubstr("SrcMAC=52:cc:cc:cc:cc:01 DstMAC=ff:ff:ff:ff:ff:ff EthernetType=UnknownEthernetType"), pktSubstr("Unable to decode EthernetType 4660"), ), }, }, }, { netName: "v6", setup: func() (*Server, error) { var c Config c.AddNode(c.AddNetwork("2000:52::1/64")) return New(&c) }, tests: []netTest{ { name: "router-solicit", pkt: mkIPv6RouterSolicit(nodeMac(1), netip.MustParseAddr("fe80::50cc:ccff:fecc:cc01")), check: all( logSubstr("sending IPv6 router advertisement to 52:cc:cc:cc:cc:01 from 52:ee:ee:ee:ee:01"), numPkts(1), pktSubstr("TypeCode=RouterAdvertisement"), pktSubstr("= ICMPv6RouterAdvertisement"), pktSubstr("SrcMAC=52:ee:ee:ee:ee:01 DstMAC=52:cc:cc:cc:cc:01 EthernetType=IPv6"), ), }, }, }, } for _, tt := range tests { t.Run(tt.netName, func(t *testing.T) { s, err := tt.setup() if err != nil { t.Fatal(err) } defer s.Close() for _, tt := range tt.tests { t.Run(tt.name, func(t *testing.T) { se := &sideEffects{} s.SetLoggerForTest(se.logf) for mac := range s.MACs() { s.RegisterSinkForTest(mac, func(eth []byte) { se.got = append(se.got, eth) }) } s.handleEthernetFrameFromVM(tt.pkt) if tt.check != nil { if err := tt.check(se); err != nil { t.Fatal(err) } } }) } }) } } // mkEth encodes an ethernet frame with the given payload. func mkEth(dst, src MAC, ethType layers.EthernetType, payload []byte) []byte { ret := make([]byte, 0, 14+len(payload)) ret = append(ret, dst.HWAddr()...) ret = append(ret, src.HWAddr()...) ret = binary.BigEndian.AppendUint16(ret, uint16(ethType)) return append(ret, payload...) } // mkLenPrefixed prepends a uint32 length to the given packet. func mkLenPrefixed(pkt []byte) []byte { ret := make([]byte, 4+len(pkt)) binary.BigEndian.PutUint32(ret, uint32(len(pkt))) copy(ret[4:], pkt) return ret } // mkIPv6RouterSolicit makes a IPv6 router solicitation packet // ethernet frame. func mkIPv6RouterSolicit(srcMAC MAC, srcIP netip.Addr) []byte { ip := &layers.IPv6{ Version: 6, HopLimit: 255, NextHeader: layers.IPProtocolICMPv6, SrcIP: srcIP.AsSlice(), DstIP: net.ParseIP("ff02::2"), // all routers } icmp := &layers.ICMPv6{ TypeCode: layers.CreateICMPv6TypeCode(layers.ICMPv6TypeRouterSolicitation, 0), } ra := &layers.ICMPv6RouterSolicitation{ Options: []layers.ICMPv6Option{{ Type: layers.ICMPv6OptSourceAddress, Data: srcMAC.HWAddr(), }}, } icmp.SetNetworkLayerForChecksum(ip) buf := gopacket.NewSerializeBuffer() options := gopacket.SerializeOptions{FixLengths: true, ComputeChecksums: true} if err := gopacket.SerializeLayers(buf, options, ip, icmp, ra); err != nil { panic(fmt.Sprintf("serializing ICMPv6 RA: %v", err)) } return mkEth(macAllRouters, srcMAC, layers.EthernetTypeIPv6, buf.Bytes()) } // sideEffects gathers side effects as a result of sending a packet and tests // whether those effects were as desired. type sideEffects struct { logs []string got [][]byte // ethernet packets received } func (se *sideEffects) logf(format string, args ...any) { se.logs = append(se.logs, fmt.Sprintf(format, args...)) } // all aggregates several side effects checkers into one. func all(checks ...func(*sideEffects) error) func(*sideEffects) error { return func(se *sideEffects) error { var errs []error for _, check := range checks { if err := check(se); err != nil { errs = append(errs, err) } } return errors.Join(errs...) } } // logSubstr returns a side effect checker func that checks // whether a log statement was output containing substring sub. func logSubstr(sub string) func(*sideEffects) error { return func(se *sideEffects) error { for _, log := range se.logs { if strings.Contains(log, sub) { return nil } } return fmt.Errorf("expected log substring %q not found; log statements were %q", sub, se.logs) } } // pkgSubstr returns a side effect checker func that checks whether an ethernet // packet was received that, once decoded and stringified by gopacket, contains // substring sub. func pktSubstr(sub string) func(*sideEffects) error { return func(se *sideEffects) error { var pkts bytes.Buffer for i, pkt := range se.got { pkt := gopacket.NewPacket(pkt, layers.LayerTypeEthernet, gopacket.Lazy) got := pkt.String() fmt.Fprintf(&pkts, "[pkt%d]:\n%s\n", i, got) if strings.Contains(got, sub) { return nil } } return fmt.Errorf("packet summary with substring %q not found; packets were:\n%s", sub, pkts.Bytes()) } } // numPkts returns a side effect checker func that checks whether // the received number of ethernet packets was the given number. func numPkts(want int) func(*sideEffects) error { return func(se *sideEffects) error { if len(se.got) == want { return nil } var pkts bytes.Buffer for i, pkt := range se.got { pkt := gopacket.NewPacket(pkt, layers.LayerTypeEthernet, gopacket.Lazy) got := pkt.String() fmt.Fprintf(&pkts, "[pkt%d]:\n%s\n", i, got) } return fmt.Errorf("got %d packets, want %d. packets were:\n%s", len(se.got), want, pkts.Bytes()) } } func newTwoNodesSameNetworkServer() (*Server, error) { var c Config nw := c.AddNetwork("192.168.0.1/24") c.AddNode(nw) c.AddNode(nw) return New(&c) } // TestProtocolQEMU tests the protocol that qemu uses to connect to natlab's // vnet. (uint32-length prefixed ethernet frames over a unix stream socket) // // This test makes two clients (as qemu would act) and has one send an ethernet // packet to the other virtual LAN segment. func TestProtocolQEMU(t *testing.T) { if runtime.GOOS == "windows" { t.Skipf("skipping on %s", runtime.GOOS) } s := must.Get(newTwoNodesSameNetworkServer()) defer s.Close() s.SetLoggerForTest(t.Logf) td := t.TempDir() serverSock := filepath.Join(td, "vnet.sock") ln, err := net.Listen("unix", serverSock) if err != nil { t.Fatal(err) } defer ln.Close() var clientc [2]*net.UnixConn for i := range clientc { c, err := net.Dial("unix", serverSock) if err != nil { t.Fatal(err) } defer c.Close() clientc[i] = c.(*net.UnixConn) } for range clientc { conn, err := ln.Accept() if err != nil { t.Fatal(err) } go s.ServeUnixConn(conn.(*net.UnixConn), ProtocolQEMU) } sendBetweenClients(t, clientc, s, mkLenPrefixed) } // TestProtocolUnixDgram tests the protocol that macOS Virtualization.framework // uses to connect to vnet. (unix datagram sockets) // // It is similar to TestProtocolQEMU but uses unix datagram sockets instead of // streams. func TestProtocolUnixDgram(t *testing.T) { if runtime.GOOS == "windows" { t.Skipf("skipping on %s", runtime.GOOS) } s := must.Get(newTwoNodesSameNetworkServer()) defer s.Close() s.SetLoggerForTest(t.Logf) td := t.TempDir() serverSock := filepath.Join(td, "vnet.sock") serverAddr := must.Get(net.ResolveUnixAddr("unixgram", serverSock)) var clientSock [2]string for i := range clientSock { clientSock[i] = filepath.Join(td, fmt.Sprintf("c%d.sock", i)) } uc, err := net.ListenUnixgram("unixgram", serverAddr) if err != nil { t.Fatal(err) } go s.ServeUnixConn(uc, ProtocolUnixDGRAM) var clientc [2]*net.UnixConn for i := range clientc { c, err := net.DialUnix("unixgram", must.Get(net.ResolveUnixAddr("unixgram", clientSock[i])), serverAddr) if err != nil { t.Fatal(err) } defer c.Close() clientc[i] = c } sendBetweenClients(t, clientc, s, nil) } // sendBetweenClients is a test helper that tries to send an ethernet frame from // one client to another. // // It first makes the two clients send a packet to a fictitious node 3, which // forces their src MACs to be registered with a networkWriter internally so // they can receive traffic. // // Normally a node starts up spamming DHCP + NDP but we don't get that as a side // effect here, so this does it manually. // // It also then waits for them to be registered. // // wrap is an optional function that wraps the packet before sending it. func sendBetweenClients(t testing.TB, clientc [2]*net.UnixConn, s *Server, wrap func([]byte) []byte) { t.Helper() if wrap == nil { wrap = func(b []byte) []byte { return b } } for i, c := range clientc { must.Get(c.Write(wrap(mkEth(nodeMac(3), nodeMac(i+1), testingEthertype, []byte("hello"))))) } awaitCond(t, 5*time.Second, func() error { if n := s.RegisteredWritersForTest(); n != 2 { return fmt.Errorf("got %d registered writers, want 2", n) } return nil }) // Now see if node1 can write to node2 and node2 receives it. pkt := wrap(mkEth(nodeMac(2), nodeMac(1), testingEthertype, []byte("test-msg"))) t.Logf("writing % 02x", pkt) must.Get(clientc[0].Write(pkt)) buf := make([]byte, len(pkt)) clientc[1].SetReadDeadline(time.Now().Add(5 * time.Second)) n, err := clientc[1].Read(buf) if err != nil { t.Fatal(err) } got := buf[:n] if !bytes.Equal(got, pkt) { t.Errorf("bad packet\n got: % 02x\nwant: % 02x", got, pkt) } } func awaitCond(t testing.TB, timeout time.Duration, cond func() error) { t.Helper() t0 := time.Now() for { if err := cond(); err == nil { return } if time.Since(t0) > timeout { t.Fatalf("timed out after %v", timeout) } time.Sleep(10 * time.Millisecond) } }