tstest/natlab/vnet: add start of IPv6 support

Updates #13038

Change-Id: Ic3d095f167daf6c7129463e881b18f2e0d5693f5
Signed-off-by: Brad Fitzpatrick <bradfitz@tailscale.com>
pull/13264/head
Brad Fitzpatrick 3 months ago committed by Brad Fitzpatrick
parent 31b5239a2f
commit b78df4d48a

@ -28,6 +28,7 @@ import (
"sync" "sync"
"time" "time"
"tailscale.com/atomicfile"
"tailscale.com/client/tailscale" "tailscale.com/client/tailscale"
"tailscale.com/hostinfo" "tailscale.com/hostinfo"
"tailscale.com/util/must" "tailscale.com/util/must"
@ -85,6 +86,17 @@ func main() {
flag.Parse() flag.Parse()
if distro.Get() == distro.Gokrazy { if distro.Get() == distro.Gokrazy {
cmdLine, _ := os.ReadFile("/proc/cmdline")
explicitNS := false
for _, s := range strings.Fields(string(cmdLine)) {
if ns, ok := strings.CutPrefix(s, "tta.nameserver="); ok {
err := atomicfile.WriteFile("/tmp/resolv.conf", []byte("nameserver "+ns+"\n"), 0644)
log.Printf("Wrote /tmp/resolv.conf: %v", err)
explicitNS = true
break
}
}
if !explicitNS {
nsRx := regexp.MustCompile(`(?m)^nameserver (.*)`) nsRx := regexp.MustCompile(`(?m)^nameserver (.*)`)
for t := time.Now(); time.Since(t) < 10*time.Second; time.Sleep(10 * time.Millisecond) { for t := time.Now(); time.Since(t) < 10*time.Second; time.Sleep(10 * time.Millisecond) {
all, _ := os.ReadFile("/etc/resolv.conf") all, _ := os.ReadFile("/etc/resolv.conf")
@ -93,6 +105,7 @@ func main() {
} }
} }
} }
}
log.Printf("Tailscale Test Agent running.") log.Printf("Tailscale Test Agent running.")

@ -2,12 +2,18 @@
echo "Type 'C-a c' to enter monitor; q to quit." echo "Type 'C-a c' to enter monitor; q to quit."
# If the USE_V6 environment is set to 1, set the nameserver explicitly to.
EXTRA_ARG=""
if [ "$USE_V6" = "1" ]; then
EXTRA_ARG="tta.nameserver=2411::411"
fi
set -eux set -eux
qemu-system-x86_64 -M microvm,isa-serial=off \ qemu-system-x86_64 -M microvm,isa-serial=off \
-m 1G \ -m 1G \
-nodefaults -no-user-config -nographic \ -nodefaults -no-user-config -nographic \
-kernel $HOME/src/github.com/tailscale/gokrazy-kernel/vmlinuz \ -kernel $HOME/src/github.com/tailscale/gokrazy-kernel/vmlinuz \
-append "console=hvc0 root=PARTUUID=60c24cc1-f3f9-427a-8199-76baa2d60001/PARTNROFF=1 ro init=/gokrazy/init panic=10 oops=panic pci=off nousb tsc=unstable clocksource=hpet tailscale-tta=1 tailscaled.env=TS_DEBUG_RAW_DISCO=1" \ -append "console=hvc0 root=PARTUUID=60c24cc1-f3f9-427a-8199-76baa2d60001/PARTNROFF=1 ro init=/gokrazy/init panic=10 oops=panic pci=off nousb tsc=unstable clocksource=hpet tailscale-tta=1 tailscaled.env=TS_DEBUG_RAW_DISCO=1 ${EXTRA_ARG}" \
-drive id=blk0,file=$HOME/src/tailscale.com/gokrazy/natlabapp.img,format=raw \ -drive id=blk0,file=$HOME/src/tailscale.com/gokrazy/natlabapp.img,format=raw \
-device virtio-blk-device,drive=blk0 \ -device virtio-blk-device,drive=blk0 \
-device virtio-rng-device \ -device virtio-rng-device \

@ -25,10 +25,12 @@ var (
listen = flag.String("listen", "/tmp/qemu.sock", "path to listen on") listen = flag.String("listen", "/tmp/qemu.sock", "path to listen on")
nat = flag.String("nat", "easy", "type of NAT to use") nat = flag.String("nat", "easy", "type of NAT to use")
nat2 = flag.String("nat2", "hard", "type of NAT to use for second network") nat2 = flag.String("nat2", "hard", "type of NAT to use for second network")
portmap = flag.Bool("portmap", false, "enable portmapping") portmap = flag.Bool("portmap", false, "enable portmapping; requires --v4")
dgram = flag.Bool("dgram", false, "enable datagram mode; for use with macOS Hypervisor.Framework and VZFileHandleNetworkDeviceAttachment") dgram = flag.Bool("dgram", false, "enable datagram mode; for use with macOS Hypervisor.Framework and VZFileHandleNetworkDeviceAttachment")
blend = flag.Bool("blend", true, "blend reality (controlplane.tailscale.com and DERPs) into the virtual network") blend = flag.Bool("blend", true, "blend reality (controlplane.tailscale.com and DERPs) into the virtual network")
pcapFile = flag.String("pcap", "", "if non-empty, filename to write pcap") pcapFile = flag.String("pcap", "", "if non-empty, filename to write pcap")
v4 = flag.Bool("v4", true, "enable IPv4")
v6 = flag.Bool("v6", true, "enable IPv6")
) )
func main() { func main() {
@ -61,9 +63,18 @@ func main() {
var c vnet.Config var c vnet.Config
c.SetPCAPFile(*pcapFile) c.SetPCAPFile(*pcapFile)
c.SetBlendReality(*blend) c.SetBlendReality(*blend)
node1 := c.AddNode(c.AddNetwork("2.1.1.1", "192.168.1.1/24", vnet.NAT(*nat)))
var net1opt = []any{vnet.NAT(*nat)}
if *v4 {
net1opt = append(net1opt, "2.1.1.1", "192.168.1.1/24")
}
if *v6 {
net1opt = append(net1opt, "2000:52::1/64")
}
node1 := c.AddNode(c.AddNetwork(net1opt...))
c.AddNode(c.AddNetwork("2.2.2.2", "10.2.0.1/16", vnet.NAT(*nat2))) c.AddNode(c.AddNetwork("2.2.2.2", "10.2.0.1/16", vnet.NAT(*nat2)))
if *portmap { if *portmap && *v4 {
node1.Network().AddService(vnet.NATPMP) node1.Network().AddService(vnet.NATPMP)
} }
@ -72,9 +83,11 @@ func main() {
log.Fatalf("newServer: %v", err) log.Fatalf("newServer: %v", err)
} }
if *blend {
if err := s.PopulateDERPMapIPs(); err != nil { if err := s.PopulateDERPMapIPs(); err != nil {
log.Printf("warning: ignoring failure to populate DERP map: %v", err) log.Printf("warning: ignoring failure to populate DERP map: %v", err)
} }
}
s.WriteStartingBanner(os.Stdout) s.WriteStartingBanner(os.Stdout)
nc := s.NodeAgentClient(node1) nc := s.NodeAgentClient(node1)

@ -95,6 +95,10 @@ func findKernelPath(goMod string) (string, error) {
type addNodeFunc func(c *vnet.Config) *vnet.Node // returns nil to omit test type addNodeFunc func(c *vnet.Config) *vnet.Node // returns nil to omit test
func v6cidr(n int) string {
return fmt.Sprintf("2000:%d::1/64", n)
}
func easy(c *vnet.Config) *vnet.Node { func easy(c *vnet.Config) *vnet.Node {
n := c.NumNodes() + 1 n := c.NumNodes() + 1
return c.AddNode(c.AddNetwork( return c.AddNode(c.AddNetwork(
@ -102,6 +106,20 @@ func easy(c *vnet.Config) *vnet.Node {
fmt.Sprintf("192.168.%d.1/24", n), vnet.EasyNAT)) fmt.Sprintf("192.168.%d.1/24", n), vnet.EasyNAT))
} }
func easyAnd6(c *vnet.Config) *vnet.Node {
n := c.NumNodes() + 1
return c.AddNode(c.AddNetwork(
fmt.Sprintf("2.%d.%d.%d", n, n, n), // public IP
fmt.Sprintf("192.168.%d.1/24", n),
v6cidr(n),
vnet.EasyNAT))
}
func just6(c *vnet.Config) *vnet.Node {
n := c.NumNodes() + 1
return c.AddNode(c.AddNetwork(v6cidr(n))) // public IPv6 prefix
}
// easy + host firewall // easy + host firewall
func easyFW(c *vnet.Config) *vnet.Node { func easyFW(c *vnet.Config) *vnet.Node {
n := c.NumNodes() + 1 n := c.NumNodes() + 1
@ -255,6 +273,11 @@ func (nt *natTest) runTest(node1, node2 addNodeFunc) pingRoute {
for _, e := range node.Env() { for _, e := range node.Env() {
fmt.Fprintf(&envBuf, " tailscaled.env=%s=%s", e.Key, e.Value) fmt.Fprintf(&envBuf, " tailscaled.env=%s=%s", e.Key, e.Value)
} }
sysLogAddr := net.JoinHostPort(vnet.FakeSyslogIPv4().String(), "995")
if node.IsV6Only() {
fmt.Fprintf(&envBuf, " tta.nameserver=%s", vnet.FakeDNSIPv6())
sysLogAddr = net.JoinHostPort(vnet.FakeSyslogIPv6().String(), "995")
}
envStr := envBuf.String() envStr := envBuf.String()
cmd := exec.Command("qemu-system-x86_64", cmd := exec.Command("qemu-system-x86_64",
@ -262,7 +285,7 @@ func (nt *natTest) runTest(node1, node2 addNodeFunc) pingRoute {
"-m", "384M", "-m", "384M",
"-nodefaults", "-no-user-config", "-nographic", "-nodefaults", "-no-user-config", "-nographic",
"-kernel", nt.kernel, "-kernel", nt.kernel,
"-append", "console=hvc0 root=PARTUUID=60c24cc1-f3f9-427a-8199-76baa2d60001/PARTNROFF=1 ro init=/gokrazy/init panic=10 oops=panic pci=off nousb tsc=unstable clocksource=hpet gokrazy.remote_syslog.target=52.52.0.9:995 tailscale-tta=1"+envStr, "-append", "console=hvc0 root=PARTUUID=60c24cc1-f3f9-427a-8199-76baa2d60001/PARTNROFF=1 ro init=/gokrazy/init panic=10 oops=panic pci=off nousb tsc=unstable clocksource=hpet gokrazy.remote_syslog.target="+sysLogAddr+" tailscale-tta=1"+envStr,
"-drive", "id=blk0,file="+disk+",format=qcow2", "-drive", "id=blk0,file="+disk+",format=qcow2",
"-device", "virtio-blk-device,drive=blk0", "-device", "virtio-blk-device,drive=blk0",
"-netdev", "stream,id=net0,addr.type=unix,addr.path="+sockAddr, "-netdev", "stream,id=net0,addr.type=unix,addr.path="+sockAddr,
@ -445,6 +468,20 @@ func TestEasyEasy(t *testing.T) {
nt.want(routeDirect) nt.want(routeDirect)
} }
func TestJustIPv6(t *testing.T) {
t.Skip("TODO: get this working")
nt := newNatTest(t)
nt.runTest(just6, just6)
nt.want(routeDirect)
}
func TestEasy4AndJust6(t *testing.T) {
t.Skip("TODO: get this working")
nt := newNatTest(t)
nt.runTest(easyAnd6, just6)
nt.want(routeDirect)
}
func TestSameLAN(t *testing.T) { func TestSameLAN(t *testing.T) {
nt := newNatTest(t) nt := newNatTest(t)
nt.runTest(easy, sameLAN) nt.runTest(easy, sameLAN)

@ -132,6 +132,7 @@ type TailscaledEnv struct {
func (c *Config) AddNetwork(opts ...any) *Network { func (c *Config) AddNetwork(opts ...any) *Network {
num := len(c.networks) num := len(c.networks)
n := &Network{ n := &Network{
num: num + 1,
mac: MAC{0x52, 0xee, 0xee, 0xee, 0xee, byte(num) + 1}, // 52=TS then 0xee for 'etwork mac: MAC{0x52, 0xee, 0xee, 0xee, 0xee, byte(num) + 1}, // 52=TS then 0xee for 'etwork
} }
c.networks = append(c.networks, n) c.networks = append(c.networks, n)
@ -139,9 +140,15 @@ func (c *Config) AddNetwork(opts ...any) *Network {
switch o := o.(type) { switch o := o.(type) {
case string: case string:
if ip, err := netip.ParseAddr(o); err == nil { if ip, err := netip.ParseAddr(o); err == nil {
n.wanIP = ip n.wanIP4 = ip
} else if ip, err := netip.ParsePrefix(o); err == nil { } else if ip, err := netip.ParsePrefix(o); err == nil {
n.lanIP = ip // If the prefix is IPv4, treat it as the router's internal IPv4 address + CIDR.
// If the prefix is IPv6, treat it as the router's WAN IPv6 + CIDR (typically a /64).
if ip.Addr().Is4() {
n.lanIP4 = ip
} else if ip.Addr().Is6() {
n.wanIP6 = ip
}
} else { } else {
if n.err == nil { if n.err == nil {
n.err = fmt.Errorf("unknown string option %q", o) n.err = fmt.Errorf("unknown string option %q", o)
@ -208,6 +215,21 @@ func (n *Node) SetVerboseSyslog(v bool) {
n.verboseSyslog = v n.verboseSyslog = v
} }
// IsV6Only reports whether this node is only connected to IPv6 networks.
func (n *Node) IsV6Only() bool {
for _, net := range n.nets {
if net.CanV4() {
return false
}
}
for _, net := range n.nets {
if net.CanV6() {
return true
}
}
return false
}
// Network returns the first network this node is connected to, // Network returns the first network this node is connected to,
// or nil if none. // or nil if none.
func (n *Node) Network() *Network { func (n *Node) Network() *Network {
@ -219,11 +241,14 @@ func (n *Node) Network() *Network {
// Network is the configuration of a network in the virtual network. // Network is the configuration of a network in the virtual network.
type Network struct { type Network struct {
num int // 1-based
mac MAC // MAC address of the router/gateway mac MAC // MAC address of the router/gateway
natType NAT natType NAT
wanIP netip.Addr wanIP6 netip.Prefix // global unicast router in host bits; CIDR is /64 delegated to LAN
lanIP netip.Prefix
wanIP4 netip.Addr // IPv4 WAN IP, if any
lanIP4 netip.Prefix
nodes []*Node nodes []*Node
svcs set.Set[NetworkService] svcs set.Set[NetworkService]
@ -232,6 +257,14 @@ type Network struct {
err error // carried error err error // carried error
} }
func (n *Network) CanV4() bool {
return n.lanIP4.IsValid() || n.wanIP4.IsValid()
}
func (n *Network) CanV6() bool {
return n.wanIP6.IsValid()
}
func (n *Network) CanTakeMoreNodes() bool { func (n *Network) CanTakeMoreNodes() bool {
if n.natType == One2OneNAT { if n.natType == One2OneNAT {
return len(n.nodes) == 0 return len(n.nodes) == 0
@ -282,24 +315,43 @@ func (s *Server) initFromConfig(c *Config) error {
if conf.err != nil { if conf.err != nil {
return conf.err return conf.err
} }
if !conf.lanIP.IsValid() { if !conf.lanIP4.IsValid() && !conf.wanIP6.IsValid() {
conf.lanIP = netip.MustParsePrefix("192.168.0.0/24") conf.lanIP4 = netip.MustParsePrefix("192.168.0.0/24")
} }
n := &network{ n := &network{
num: conf.num,
s: s, s: s,
mac: conf.mac, mac: conf.mac,
portmap: conf.svcs.Contains(NATPMP), // TODO: expand network.portmap portmap: conf.svcs.Contains(NATPMP), // TODO: expand network.portmap
wanIP: conf.wanIP, wanIP6: conf.wanIP6,
lanIP: conf.lanIP, v4: conf.lanIP4.IsValid(),
v6: conf.wanIP6.IsValid(),
wanIP4: conf.wanIP4,
lanIP4: conf.lanIP4,
nodesByIP: map[netip.Addr]*node{}, nodesByIP: map[netip.Addr]*node{},
nodesByMAC: map[MAC]*node{},
logf: logger.WithPrefix(log.Printf, fmt.Sprintf("[net-%v] ", conf.mac)), logf: logger.WithPrefix(log.Printf, fmt.Sprintf("[net-%v] ", conf.mac)),
} }
netOfConf[conf] = n netOfConf[conf] = n
s.networks.Add(n) s.networks.Add(n)
if _, ok := s.networkByWAN[conf.wanIP]; ok { if conf.wanIP4.IsValid() {
return fmt.Errorf("two networks have the same WAN IP %v; Anycast not (yet?) supported", conf.wanIP) if conf.wanIP4.Is6() {
return fmt.Errorf("invalid IPv6 address in wanIP")
}
if _, ok := s.networkByWAN.Lookup(conf.wanIP4); ok {
return fmt.Errorf("two networks have the same WAN IP %v; Anycast not (yet?) supported", conf.wanIP4)
}
s.networkByWAN.Insert(netip.PrefixFrom(conf.wanIP4, 32), n)
}
if conf.wanIP6.IsValid() {
if conf.wanIP6.Addr().Is4() {
return fmt.Errorf("invalid IPv4 address in wanIP6")
}
if _, ok := s.networkByWAN.LookupPrefix(conf.wanIP6); ok {
return fmt.Errorf("two networks have the same WAN IPv6 %v; Anycast not (yet?) supported", conf.wanIP6)
}
s.networkByWAN.Insert(conf.wanIP6, n)
} }
s.networkByWAN[conf.wanIP] = n
n.lanInterfaceID = must.Get(s.pcapWriter.AddInterface(pcapgo.NgInterface{ n.lanInterfaceID = must.Get(s.pcapWriter.AddInterface(pcapgo.NgInterface{
Name: fmt.Sprintf("network%d-lan", i+1), Name: fmt.Sprintf("network%d-lan", i+1),
LinkType: layers.LinkTypeIPv4, LinkType: layers.LinkTypeIPv4,
@ -330,14 +382,17 @@ func (s *Server) initFromConfig(c *Config) error {
s.nodes = append(s.nodes, n) s.nodes = append(s.nodes, n)
s.nodeByMAC[n.mac] = n s.nodeByMAC[n.mac] = n
if n.net.v4 {
// Allocate a lanIP for the node. Use the network's CIDR and use final // Allocate a lanIP for the node. Use the network's CIDR and use final
// octet 101 (for first node), 102, etc. The node number comes from the // octet 101 (for first node), 102, etc. The node number comes from the
// last octent of the MAC address (0-based) // last octent of the MAC address (0-based)
ip4 := n.net.lanIP.Addr().As4() ip4 := n.net.lanIP4.Addr().As4()
ip4[3] = 100 + n.mac[5] ip4[3] = 100 + n.mac[5]
n.lanIP = netip.AddrFrom4(ip4) n.lanIP = netip.AddrFrom4(ip4)
n.net.nodesByIP[n.lanIP] = n n.net.nodesByIP[n.lanIP] = n
} }
n.net.nodesByMAC[n.mac] = n
}
// Now that nodes are populated, set up NAT: // Now that nodes are populated, set up NAT:
for _, conf := range c.networks { for _, conf := range c.networks {

@ -11,7 +11,7 @@ import (
var vips = map[string]virtualIP{} // DNS name => details var vips = map[string]virtualIP{} // DNS name => details
var ( var (
fakeDNS = newVIP("dns", "4.11.4.11", "2000:4:11::4:11") fakeDNS = newVIP("dns", "4.11.4.11", "2411::411")
fakeProxyControlplane = newVIP("controlplane.tailscale.com", 1) fakeProxyControlplane = newVIP("controlplane.tailscale.com", 1)
fakeTestAgent = newVIP("test-driver.tailscale", 2) fakeTestAgent = newVIP("test-driver.tailscale", 2)
fakeControl = newVIP("control.tailscale", 3) fakeControl = newVIP("control.tailscale", 3)
@ -31,6 +31,18 @@ func (v virtualIP) Match(a netip.Addr) bool {
return v.v4 == a.Unmap() || v.v6 == a return v.v4 == a.Unmap() || v.v6 == a
} }
// FakeDNSIPv4 returns the fake DNS IPv4 address.
func FakeDNSIPv4() netip.Addr { return fakeDNS.v4 }
// FakeDNSIPv6 returns the fake DNS IPv6 address.
func FakeDNSIPv6() netip.Addr { return fakeDNS.v6 }
// FakeSyslogIPv4 returns the fake syslog IPv4 address.
func FakeSyslogIPv4() netip.Addr { return fakeSyslog.v4 }
// FakeSyslogIPv6 returns the fake syslog IPv6 address.
func FakeSyslogIPv6() netip.Addr { return fakeSyslog.v6 }
// newVIP returns a new virtual IP. // newVIP returns a new virtual IP.
// //
// opts may be an IPv4 an IPv6 (in string form) or an int (bounded by uint8) to // opts may be an IPv4 an IPv6 (in string form) or an int (bounded by uint8) to
@ -67,8 +79,14 @@ func newVIP(name string, opts ...any) (v virtualIP) {
} }
if !v.v6.IsValid() && v.v4.IsValid() { if !v.v6.IsValid() && v.v4.IsValid() {
// Map 1.2.3.4 to 2052::0102:0304 // Map 1.2.3.4 to 2052::0102:0304
a := [16]byte{0: 2, 2: 5, 3: 2} // 2052:: // But make 52.52.0.x map to 2052::x
a := [16]byte{0: 0x20, 1: 0x52} // 2052::
v4 := v.v4.As4()
if v4[0] == 52 && v4[1] == 52 && v4[2] == 0 {
a[15] = v4[3]
} else {
copy(a[12:], v.v4.AsSlice()) copy(a[12:], v.v4.AsSlice())
}
v.v6 = netip.AddrFrom16(a) v.v6 = netip.AddrFrom16(a)
} }
for _, b := range vips { for _, b := range vips {

@ -35,6 +35,7 @@ import (
"sync/atomic" "sync/atomic"
"time" "time"
"github.com/gaissmai/bart"
"github.com/google/gopacket" "github.com/google/gopacket"
"github.com/google/gopacket/layers" "github.com/google/gopacket/layers"
"go4.org/mem" "go4.org/mem"
@ -45,6 +46,7 @@ import (
"gvisor.dev/gvisor/pkg/tcpip/link/channel" "gvisor.dev/gvisor/pkg/tcpip/link/channel"
"gvisor.dev/gvisor/pkg/tcpip/network/arp" "gvisor.dev/gvisor/pkg/tcpip/network/arp"
"gvisor.dev/gvisor/pkg/tcpip/network/ipv4" "gvisor.dev/gvisor/pkg/tcpip/network/ipv4"
"gvisor.dev/gvisor/pkg/tcpip/network/ipv6"
"gvisor.dev/gvisor/pkg/tcpip/stack" "gvisor.dev/gvisor/pkg/tcpip/stack"
"gvisor.dev/gvisor/pkg/tcpip/transport/icmp" "gvisor.dev/gvisor/pkg/tcpip/transport/icmp"
"gvisor.dev/gvisor/pkg/tcpip/transport/tcp" "gvisor.dev/gvisor/pkg/tcpip/transport/tcp"
@ -99,7 +101,7 @@ func (n *network) InitNAT(natType NAT) error {
} }
t, err := ctor(n) t, err := ctor(n)
if err != nil { if err != nil {
return fmt.Errorf("error creating NAT type %q for network %v: %w", natType, n.wanIP, err) return fmt.Errorf("error creating NAT type %q for network %v: %w", natType, n.wanIP4, err)
} }
n.setNATTable(t) n.setNATTable(t)
n.natStyle.Store(natType) n.natStyle.Store(natType)
@ -124,12 +126,13 @@ func (n *network) SoleLANIP() (netip.Addr, bool) {
} }
// WANIP implements [IPPool]. // WANIP implements [IPPool].
func (n *network) WANIP() netip.Addr { return n.wanIP } func (n *network) WANIP() netip.Addr { return n.wanIP4 }
func (n *network) initStack() error { func (n *network) initStack() error {
n.ns = stack.New(stack.Options{ n.ns = stack.New(stack.Options{
NetworkProtocols: []stack.NetworkProtocolFactory{ NetworkProtocols: []stack.NetworkProtocolFactory{
ipv4.NewProtocol, ipv4.NewProtocol,
ipv6.NewProtocol,
arp.NewProtocol, arp.NewProtocol,
}, },
TransportProtocols: []stack.TransportProtocolFactory{ TransportProtocols: []stack.TransportProtocolFactory{
@ -149,8 +152,11 @@ func (n *network) initStack() error {
n.ns.SetPromiscuousMode(nicID, true) n.ns.SetPromiscuousMode(nicID, true)
n.ns.SetSpoofing(nicID, true) n.ns.SetSpoofing(nicID, true)
prefix := tcpip.AddrFrom4Slice(n.lanIP.Addr().AsSlice()).WithPrefix() var routes []tcpip.Route
prefix.PrefixLen = n.lanIP.Bits()
if n.v4 {
prefix := tcpip.AddrFrom4Slice(n.lanIP4.Addr().AsSlice()).WithPrefix()
prefix.PrefixLen = n.lanIP4.Bits()
if tcpProb := n.ns.AddProtocolAddress(nicID, tcpip.ProtocolAddress{ if tcpProb := n.ns.AddProtocolAddress(nicID, tcpip.ProtocolAddress{
Protocol: ipv4.ProtocolNumber, Protocol: ipv4.ProtocolNumber,
AddressWithPrefix: prefix, AddressWithPrefix: prefix,
@ -162,12 +168,32 @@ func (n *network) initStack() error {
if err != nil { if err != nil {
return fmt.Errorf("could not create IPv4 subnet: %v", err) return fmt.Errorf("could not create IPv4 subnet: %v", err)
} }
n.ns.SetRouteTable([]tcpip.Route{ routes = append(routes, tcpip.Route{
{
Destination: ipv4Subnet, Destination: ipv4Subnet,
NIC: nicID, NIC: nicID,
},
}) })
}
if n.v6 {
prefix := tcpip.AddrFrom16(n.wanIP6.Addr().As16()).WithPrefix()
prefix.PrefixLen = n.wanIP6.Bits()
if tcpProb := n.ns.AddProtocolAddress(nicID, tcpip.ProtocolAddress{
Protocol: ipv6.ProtocolNumber,
AddressWithPrefix: prefix,
}, stack.AddressProperties{}); tcpProb != nil {
return errors.New(tcpProb.String())
}
ipv6Subnet, err := tcpip.NewSubnet(tcpip.AddrFromSlice(make([]byte, 16)), tcpip.MaskFromBytes(make([]byte, 16)))
if err != nil {
return fmt.Errorf("could not create IPv6 subnet: %v", err)
}
routes = append(routes, tcpip.Route{
Destination: ipv6Subnet,
NIC: nicID,
})
}
n.ns.SetRouteTable(routes)
const tcpReceiveBufferSize = 0 // default const tcpReceiveBufferSize = 0 // default
const maxInFlightConnectionAttempts = 8192 const maxInFlightConnectionAttempts = 8192
@ -186,23 +212,43 @@ func (n *network) initStack() error {
} }
continue continue
} }
n.handleIPPacketFromGvisor(pkt.ToView().AsSlice())
}
}()
return nil
}
ipRaw := pkt.ToView().AsSlice() func (n *network) handleIPPacketFromGvisor(ipRaw []byte) {
goPkt := gopacket.NewPacket( if len(ipRaw) == 0 {
panic("empty packet from gvisor")
}
var goPkt gopacket.Packet
ipVer := ipRaw[0] >> 4 // 4 or 6
switch ipVer {
case 4:
goPkt = gopacket.NewPacket(
ipRaw, ipRaw,
layers.LayerTypeIPv4, gopacket.Lazy) layers.LayerTypeIPv4, gopacket.Lazy)
layerV4 := goPkt.Layer(layers.LayerTypeIPv4).(*layers.IPv4) case 6:
goPkt = gopacket.NewPacket(
dstIP, _ := netip.AddrFromSlice(layerV4.DstIP) ipRaw,
node, ok := n.nodesByIP[dstIP] layers.LayerTypeIPv6, gopacket.Lazy)
default:
return
}
flow, ok := flow(goPkt)
if !ok { if !ok {
log.Printf("no MAC for dest IP %v", dstIP) panic("unexpected gvisor packet")
continue }
node, ok := n.nodeForDestIP(flow.dst)
if !ok {
n.logf("no node for netstack dest IP %v", flow.dst)
return
} }
eth := &layers.Ethernet{ eth := &layers.Ethernet{
SrcMAC: n.mac.HWAddr(), SrcMAC: n.mac.HWAddr(),
DstMAC: node.mac.HWAddr(), DstMAC: node.mac.HWAddr(),
EthernetType: layers.EthernetTypeIPv4, EthernetType: flow.etherType(),
} }
buffer := gopacket.NewSerializeBuffer() buffer := gopacket.NewSerializeBuffer()
options := gopacket.SerializeOptions{FixLengths: true, ComputeChecksums: true} options := gopacket.SerializeOptions{FixLengths: true, ComputeChecksums: true}
@ -216,25 +262,22 @@ func (n *network) initStack() error {
} }
switch gl := layer.(type) { switch gl := layer.(type) {
case *layers.TCP: case *layers.TCP:
gl.SetNetworkLayerForChecksum(layerV4) gl.SetNetworkLayerForChecksum(goPkt.NetworkLayer())
case *layers.UDP: case *layers.UDP:
gl.SetNetworkLayerForChecksum(layerV4) gl.SetNetworkLayerForChecksum(goPkt.NetworkLayer())
} }
sls = append(sls, sl) sls = append(sls, sl)
} }
if err := gopacket.SerializeLayers(buffer, options, sls...); err != nil { if err := gopacket.SerializeLayers(buffer, options, sls...); err != nil {
log.Printf("Serialize error: %v", err) n.logf("gvisor: serialize error: %v", err)
continue return
} }
if nw, ok := n.writers.Load(node.mac); ok { if nw, ok := n.writers.Load(node.mac); ok {
nw.write(buffer.Bytes()) nw.write(buffer.Bytes())
} else { } else {
log.Printf("No writeFunc for %v", node.mac) n.logf("gvisor write: no writeFunc for %v", node.mac)
}
} }
}()
return nil
} }
func netaddrIPFromNetstackIP(s tcpip.Address) netip.Addr { func netaddrIPFromNetstackIP(s tcpip.Address) netip.Addr {
@ -264,6 +307,8 @@ func (n *network) acceptTCP(r *tcp.ForwarderRequest) {
return return
} }
log.Printf("vnet-AcceptTCP: %v", stringifyTEI(reqDetails))
var wq waiter.Queue var wq waiter.Queue
ep, err := r.CreateEndpoint(&wq) ep, err := r.CreateEndpoint(&wq)
if err != nil { if err != nil {
@ -327,8 +372,6 @@ func (n *network) acceptTCP(r *tcp.ForwarderRequest) {
return return
} }
log.Printf("vnet-AcceptTCP: %v", stringifyTEI(reqDetails))
var targetDial string var targetDial string
if n.s.derpIPs.Contains(destIP) { if n.s.derpIPs.Contains(destIP) {
targetDial = destIP.String() + ":" + strconv.Itoa(int(destPort)) targetDial = destIP.String() + ":" + strconv.Itoa(int(destPort))
@ -419,6 +462,12 @@ func (m MAC) IsBroadcast() bool {
return m == MAC{0xff, 0xff, 0xff, 0xff, 0xff, 0xff} return m == MAC{0xff, 0xff, 0xff, 0xff, 0xff, 0xff}
} }
// IsIPv6Multicast reports whether m is an IPv6 multicast MAC address,
// typically one containing a solicited-node multicast address.
func (m MAC) IsIPv6Multicast() bool {
return m[0] == 0x33 && m[1] == 0x33
}
func macOf(hwa net.HardwareAddr) (_ MAC, ok bool) { func macOf(hwa net.HardwareAddr) (_ MAC, ok bool) {
if len(hwa) != 6 { if len(hwa) != 6 {
return MAC{}, false return MAC{}, false
@ -455,13 +504,18 @@ func (nw *networkWriter) write(b []byte) {
type network struct { type network struct {
s *Server s *Server
mac MAC num int // 1-based
mac MAC // of router
portmap bool portmap bool
lanInterfaceID int lanInterfaceID int
wanInterfaceID int wanInterfaceID int
wanIP netip.Addr v4 bool // network supports IPv4
lanIP netip.Prefix // with host bits set (e.g. 192.168.2.1/24) v6 bool // network support IPv6
nodesByIP map[netip.Addr]*node wanIP6 netip.Prefix // router's WAN IPv6, if any, as a /64.
wanIP4 netip.Addr // router's LAN IPv4, if any
lanIP4 netip.Prefix // router's LAN IP + CIDR (e.g. 192.168.2.1/24)
nodesByIP map[netip.Addr]*node // by LAN IPv4
nodesByMAC map[MAC]*node
logf func(format string, args ...any) logf func(format string, args ...any)
ns *stack.Stack ns *stack.Stack
@ -473,6 +527,9 @@ type network struct {
portMap map[netip.AddrPort]portMapping // WAN ip:port -> LAN ip:port portMap map[netip.AddrPort]portMapping // WAN ip:port -> LAN ip:port
portMapFlow map[portmapFlowKey]netip.AddrPort // (lanAP, peerWANAP) -> portmapped wanAP portMapFlow map[portmapFlowKey]netip.AddrPort // (lanAP, peerWANAP) -> portmapped wanAP
macMu sync.Mutex
macOfIPv6 map[netip.Addr]MAC // IPv6 source IP -> MAC
// writers is a map of MAC -> networkWriters to write packets to that MAC. // writers is a map of MAC -> networkWriters to write packets to that MAC.
// It contains entries for connected nodes only. // It contains entries for connected nodes only.
writers syncs.Map[MAC, networkWriter] // MAC -> to networkWriter for that MAC writers syncs.Map[MAC, networkWriter] // MAC -> to networkWriter for that MAC
@ -494,7 +551,7 @@ func (n *network) registerWriter(mac MAC, raddr *net.UnixAddr, interfaceID int,
} }
func (n *network) MACOfIP(ip netip.Addr) (_ MAC, ok bool) { func (n *network) MACOfIP(ip netip.Addr) (_ MAC, ok bool) {
if n.lanIP.Addr() == ip { if n.lanIP4.Addr() == ip {
return n.mac, true return n.mac, true
} }
if n, ok := n.nodesByIP[ip]; ok { if n, ok := n.nodesByIP[ip]; ok {
@ -559,7 +616,7 @@ type Server struct {
nodes []*node nodes []*node
nodeByMAC map[MAC]*node nodeByMAC map[MAC]*node
networks set.Set[*network] networks set.Set[*network]
networkByWAN map[netip.Addr]*network networkByWAN *bart.Table[*network]
control *testcontrol.Server control *testcontrol.Server
derps []*derpServer derps []*derpServer
@ -621,10 +678,11 @@ func New(c *Config) (*Server, error) {
ExplicitBaseURL: "http://control.tailscale", ExplicitBaseURL: "http://control.tailscale",
}, },
blendReality: c.blendReality,
derpIPs: set.Of[netip.Addr](), derpIPs: set.Of[netip.Addr](),
nodeByMAC: map[MAC]*node{}, nodeByMAC: map[MAC]*node{},
networkByWAN: map[netip.Addr]*network{}, networkByWAN: &bart.Table[*network]{},
networks: set.Of[*network](), networks: set.Of[*network](),
} }
for range 2 { for range 2 {
@ -655,15 +713,6 @@ func (s *Server) HWAddr(mac MAC) net.HardwareAddr {
return net.HardwareAddr(mac[:]) return net.HardwareAddr(mac[:])
} }
// IPv4ForDNS returns the IP address for the given DNS query name (for IPv4 A
// queries only).
func (s *Server) IPv4ForDNS(qname string) (netip.Addr, bool) {
if v, ok := vips[qname]; ok {
return v.v4, v.v4.IsValid()
}
return netip.Addr{}, false
}
type Protocol int type Protocol int
const ( const (
@ -767,6 +816,7 @@ func (s *Server) ServeUnixConn(uc *net.UnixConn, proto Protocol) {
packet := gopacket.NewPacket(packetRaw, layers.LayerTypeEthernet, gopacket.Lazy) packet := gopacket.NewPacket(packetRaw, layers.LayerTypeEthernet, gopacket.Lazy)
le, ok := packet.LinkLayer().(*layers.Ethernet) le, ok := packet.LinkLayer().(*layers.Ethernet)
if !ok || len(le.SrcMAC) != 6 || len(le.DstMAC) != 6 { if !ok || len(le.SrcMAC) != 6 || len(le.DstMAC) != 6 {
log.Printf("ignoring non-Ethernet packet: % 02x", packetRaw)
continue continue
} }
ep := EthernetPacket{le, packet} ep := EthernetPacket{le, packet}
@ -815,7 +865,7 @@ func (s *Server) routeUDPPacket(up UDPPacket) {
} }
dstIP := up.Dst.Addr() dstIP := up.Dst.Addr()
netw, ok := s.networkByWAN[dstIP] netw, ok := s.networkByWAN.Lookup(dstIP)
if !ok { if !ok {
if dstIP.IsPrivate() { if dstIP.IsPrivate() {
// Not worth spamming logs. RFC 1918 space doesn't route. // Not worth spamming logs. RFC 1918 space doesn't route.
@ -832,34 +882,59 @@ func (s *Server) routeUDPPacket(up UDPPacket) {
// //
// This only delivers to client devices and not the virtual router/gateway // This only delivers to client devices and not the virtual router/gateway
// device. // device.
func (n *network) writeEth(res []byte) { //
// It reports whether a packet was written to any clients.
func (n *network) writeEth(res []byte) bool {
if len(res) < 12 { if len(res) < 12 {
return return false
} }
dstMAC := MAC(res[0:6]) dstMAC := MAC(res[0:6])
srcMAC := MAC(res[6:12]) srcMAC := MAC(res[6:12])
if dstMAC.IsBroadcast() { if dstMAC.IsBroadcast() {
num := 0
n.writers.Range(func(mac MAC, nw networkWriter) bool { n.writers.Range(func(mac MAC, nw networkWriter) bool {
num++
nw.write(res) nw.write(res)
return true return true
}) })
return return num > 0
} }
if srcMAC == dstMAC { if srcMAC == dstMAC {
n.logf("dropping write of packet from %v to itself", srcMAC) n.logf("dropping write of packet from %v to itself", srcMAC)
return return false
} }
if nw, ok := n.writers.Load(dstMAC); ok { if nw, ok := n.writers.Load(dstMAC); ok {
nw.write(res) nw.write(res)
return return true
} }
const debugMiss = false
if debugMiss {
gp := gopacket.NewPacket(res, layers.LayerTypeEthernet, gopacket.Lazy)
n.logf("no writeFunc for dst %v from src %v; pkt=%v", dstMAC, srcMAC, gp)
}
return false
} }
var (
macAllRouters = MAC{0: 0x33, 1: 0x33, 5: 0x02}
)
func (n *network) HandleEthernetPacket(ep EthernetPacket) { func (n *network) HandleEthernetPacket(ep EthernetPacket) {
packet := ep.gp packet := ep.gp
dstMAC := ep.DstMAC() dstMAC := ep.DstMAC()
isBroadcast := dstMAC.IsBroadcast() isBroadcast := dstMAC.IsBroadcast()
forRouter := dstMAC == n.mac || isBroadcast isV6SpecialMAC := dstMAC[0] == 0x33 && dstMAC[1] == 0x33
// forRouter is whether the packet is destined for the router itself
// or if it's a special thing (like V6 NDP) that the router should handle.
forRouter := dstMAC == n.mac || isBroadcast || isV6SpecialMAC
const debug = false
if debug {
n.logf("HandleEthernetPacket: %v => %v; type %v, forRouter=%v", ep.SrcMAC(), ep.DstMAC(), ep.le.EthernetType, forRouter)
}
switch ep.le.EthernetType { switch ep.le.EthernetType {
default: default:
@ -874,9 +949,38 @@ func (n *network) HandleEthernetPacket(ep EthernetPacket) {
} }
return return
case layers.EthernetTypeIPv6: case layers.EthernetTypeIPv6:
// One day. Low value for now. IPv4 NAT modes is the main thing if !n.v6 {
// this project wants to test. n.logf("dropping IPv6 packet on v4-only network")
return return
}
if dstMAC == macAllRouters {
if rs, ok := ep.gp.Layer(layers.LayerTypeICMPv6RouterSolicitation).(*layers.ICMPv6RouterSolicitation); ok {
n.handleIPv6RouterSolicitation(ep, rs)
} else {
n.logf("unexpected IPv6 packet to all-routers: %v", ep.gp)
}
return
}
isMcast := dstMAC.IsIPv6Multicast()
if isMcast || dstMAC == n.mac {
if ns, ok := ep.gp.Layer(layers.LayerTypeICMPv6NeighborSolicitation).(*layers.ICMPv6NeighborSolicitation); ok {
n.handleIPv6NeighborSolicitation(ep, ns)
return
}
if ep.gp.Layer(layers.LayerTypeMLDv2MulticastListenerReport) != nil {
// We don't care about these (yet?) and Linux spams a bunch
// a bunch of them out, so explicitly ignore them to prevent
// log spam when verbose logging is enabled.
return
}
if isMcast {
return
}
}
// TODO(bradfitz): handle packets to e.g. [fe80::50cc:ccff:fecc:cc01]:43619
// and don't fall through to the router below.
case layers.EthernetTypeIPv4: case layers.EthernetTypeIPv4:
// Below // Below
} }
@ -884,10 +988,12 @@ func (n *network) HandleEthernetPacket(ep EthernetPacket) {
// Send ethernet broadcasts and unicast ethernet frames to peers // Send ethernet broadcasts and unicast ethernet frames to peers
// on the same network. This is all LAN traffic that isn't meant // on the same network. This is all LAN traffic that isn't meant
// for the router/gw itself: // for the router/gw itself:
if isBroadcast || !forRouter {
n.writeEth(ep.gp.Data()) n.writeEth(ep.gp.Data())
}
if forRouter { if forRouter {
n.HandleEthernetIPv4PacketForRouter(ep) n.HandleEthernetPacketForRouter(ep)
} }
} }
@ -927,6 +1033,25 @@ func (n *network) HandleUDPPacket(p UDPPacket) {
n.WriteUDPPacketNoNAT(p) n.WriteUDPPacketNoNAT(p)
} }
func (n *network) nodeForDestIP(ip netip.Addr) (node *node, ok bool) {
node, ok = n.nodesByIP[ip]
if !ok && ip.Is6() {
var mac MAC
n.macMu.Lock()
mac, ok = n.macOfIPv6[ip]
n.macMu.Unlock()
if !ok {
log.Printf("XXX no MAC for IPv6 %v", ip)
return nil, false
}
node, ok = n.nodesByMAC[mac]
if !ok {
log.Printf("XXX no node for MAC %v", mac)
}
}
return node, ok
}
// WriteUDPPacketNoNAT writes a UDP packet to the network, without // WriteUDPPacketNoNAT writes a UDP packet to the network, without
// doing any NAT translation. // doing any NAT translation.
// //
@ -935,7 +1060,7 @@ func (n *network) HandleUDPPacket(p UDPPacket) {
// same ethernet segment. // same ethernet segment.
func (n *network) WriteUDPPacketNoNAT(p UDPPacket) { func (n *network) WriteUDPPacketNoNAT(p UDPPacket) {
src, dst := p.Src, p.Dst src, dst := p.Src, p.Dst
node, ok := n.nodesByIP[dst.Addr()] node, ok := n.nodeForDestIP(dst.Addr())
if !ok { if !ok {
n.logf("no node for dest IP %v in UDP packet %v=>%v", dst.Addr(), p.Src, p.Dst) n.logf("no node for dest IP %v in UDP packet %v=>%v", dst.Addr(), p.Src, p.Dst)
return return
@ -944,7 +1069,7 @@ func (n *network) WriteUDPPacketNoNAT(p UDPPacket) {
eth := &layers.Ethernet{ eth := &layers.Ethernet{
SrcMAC: n.mac.HWAddr(), // of gateway SrcMAC: n.mac.HWAddr(), // of gateway
DstMAC: node.mac.HWAddr(), DstMAC: node.mac.HWAddr(),
EthernetType: layers.EthernetTypeIPv4, EthernetType: p.etherType(),
} }
ethRaw, err := n.serializedUDPPacket(src, dst, p.Payload, eth) ethRaw, err := n.serializedUDPPacket(src, dst, p.Payload, eth)
if err != nil { if err != nil {
@ -954,19 +1079,40 @@ func (n *network) WriteUDPPacketNoNAT(p UDPPacket) {
n.writeEth(ethRaw) n.writeEth(ethRaw)
} }
type serializableNetworkLayer interface {
gopacket.SerializableLayer
gopacket.NetworkLayer
}
func mkIPLayer(proto layers.IPProtocol, src, dst netip.Addr) serializableNetworkLayer {
if src.Is4() {
return &layers.IPv4{
Version: 4,
TTL: 64,
Protocol: proto,
SrcIP: src.AsSlice(),
DstIP: dst.AsSlice(),
}
}
if src.Is6() {
return &layers.IPv6{
Version: 6,
HopLimit: 64,
NextHeader: proto,
SrcIP: src.AsSlice(),
DstIP: dst.AsSlice(),
}
}
panic("invalid src IP")
}
// serializedUDPPacket serializes a UDP packet with the given source and // serializedUDPPacket serializes a UDP packet with the given source and
// destination IP:port pairs, and payload. // destination IP:port pairs, and payload.
// //
// If eth is non-nil, it will be used as the Ethernet layer, otherwise the // If eth is non-nil, it will be used as the Ethernet layer, otherwise the
// Ethernet layer will be omitted from the serialization. // Ethernet layer will be omitted from the serialization.
func (n *network) serializedUDPPacket(src, dst netip.AddrPort, payload []byte, eth *layers.Ethernet) ([]byte, error) { func (n *network) serializedUDPPacket(src, dst netip.AddrPort, payload []byte, eth *layers.Ethernet) ([]byte, error) {
ip := &layers.IPv4{ ip := mkIPLayer(layers.IPProtocolUDP, src.Addr(), dst.Addr())
Version: 4,
TTL: 64,
Protocol: layers.IPProtocolUDP,
SrcIP: src.Addr().AsSlice(),
DstIP: dst.Addr().AsSlice(),
}
udp := &layers.UDP{ udp := &layers.UDP{
SrcPort: layers.UDPPort(src.Port()), SrcPort: layers.UDPPort(src.Port()),
DstPort: layers.UDPPort(dst.Port()), DstPort: layers.UDPPort(dst.Port()),
@ -980,27 +1126,34 @@ func (n *network) serializedUDPPacket(src, dst netip.AddrPort, payload []byte, e
layers = layers[1:] layers = layers[1:]
} }
if err := gopacket.SerializeLayers(buffer, options, layers...); err != nil { if err := gopacket.SerializeLayers(buffer, options, layers...); err != nil {
return nil, fmt.Errorf("serializing UDP: %v", err) return nil, fmt.Errorf("serializing UDP from %v to %v: %v", src, dst, err)
} }
return buffer.Bytes(), nil return buffer.Bytes(), nil
} }
// HandleEthernetIPv4PacketForRouter handles an IPv4 packet that is // HandleEthernetPacketForRouter handles an IPv4 packet that is
// directed to the router/gateway itself. The packet may be to the // directed to the router/gateway itself. The packet may be to the
// broadcast MAC address, or to the router's MAC address. The target // broadcast MAC address, or to the router's MAC address. The target
// IP may be the router's IP, or an internet (routed) IP. // IP may be the router's IP, or an internet (routed) IP.
func (n *network) HandleEthernetIPv4PacketForRouter(ep EthernetPacket) { func (n *network) HandleEthernetPacketForRouter(ep EthernetPacket) {
packet := ep.gp packet := ep.gp
flow, ok := flow(packet)
v4, ok := packet.Layer(layers.LayerTypeIPv4).(*layers.IPv4)
if !ok { if !ok {
n.logf("dropping non-IP packet: %v", packet)
return return
} }
srcIP, _ := netip.AddrFromSlice(v4.SrcIP) srcIP, dstIP := flow.src, flow.dst
dstIP, _ := netip.AddrFromSlice(v4.DstIP)
toForward := dstIP != n.lanIP.Addr() && dstIP != netip.IPv4Unspecified() toForward := dstIP != n.lanIP4.Addr() && dstIP != netip.IPv4Unspecified() && !dstIP.IsLinkLocalUnicast()
udp, isUDP := packet.Layer(layers.LayerTypeUDP).(*layers.UDP) udp, isUDP := packet.Layer(layers.LayerTypeUDP).(*layers.UDP)
// Pre-NAT mapping, for DNS/etc responses:
if srcIP.Is6() {
n.macMu.Lock()
mak.Set(&n.macOfIPv6, srcIP, ep.SrcMAC())
n.macMu.Unlock()
}
if isDHCPRequest(packet) { if isDHCPRequest(packet) {
res, err := n.s.createDHCPResponse(packet) res, err := n.s.createDHCPResponse(packet)
if err != nil { if err != nil {
@ -1017,8 +1170,6 @@ func (n *network) HandleEthernetIPv4PacketForRouter(ep EthernetPacket) {
} }
if isDNSRequest(packet) { if isDNSRequest(packet) {
// TODO(bradfitz): restrict this to 4.11.4.11? add DNS
// on gateway instead?
res, err := n.s.createDNSResponse(packet) res, err := n.s.createDNSResponse(packet)
if err != nil { if err != nil {
n.logf("createDNSResponse: %v", err) n.logf("createDNSResponse: %v", err)
@ -1029,7 +1180,7 @@ func (n *network) HandleEthernetIPv4PacketForRouter(ep EthernetPacket) {
} }
if isUDP && fakeSyslog.Match(dstIP) { if isUDP && fakeSyslog.Match(dstIP) {
node, ok := n.nodesByIP[srcIP] node, ok := n.nodeForDestIP(srcIP)
if !ok { if !ok {
return return
} }
@ -1083,6 +1234,12 @@ func (n *network) HandleEthernetIPv4PacketForRouter(ep EthernetPacket) {
InterfaceIndex: n.wanInterfaceID, InterfaceIndex: n.wanInterfaceID,
}, buf) }, buf)
if src.Addr().Is6() {
n.macMu.Lock()
mak.Set(&n.macOfIPv6, src.Addr(), ep.SrcMAC())
n.macMu.Unlock()
}
n.s.routeUDPPacket(UDPPacket{ n.s.routeUDPPacket(UDPPacket{
Src: src, Src: src,
Dst: dst, Dst: dst,
@ -1092,14 +1249,23 @@ func (n *network) HandleEthernetIPv4PacketForRouter(ep EthernetPacket) {
} }
if toForward && n.s.shouldInterceptTCP(packet) { if toForward && n.s.shouldInterceptTCP(packet) {
ipp := packet.Layer(layers.LayerTypeIPv4).(*layers.IPv4) var base *layers.BaseLayer
pktCopy := make([]byte, 0, len(ipp.Contents)+len(ipp.Payload)) proto := header.IPv4ProtocolNumber
pktCopy = append(pktCopy, ipp.Contents...) if v4, ok := packet.Layer(layers.LayerTypeIPv4).(*layers.IPv4); ok {
pktCopy = append(pktCopy, ipp.Payload...) base = &v4.BaseLayer
} else if v6, ok := packet.Layer(layers.LayerTypeIPv6).(*layers.IPv6); ok {
base = &v6.BaseLayer
proto = header.IPv6ProtocolNumber
} else {
panic("not v4, not v6")
}
pktCopy := make([]byte, 0, len(base.Contents)+len(base.Payload))
pktCopy = append(pktCopy, base.Contents...)
pktCopy = append(pktCopy, base.Payload...)
packetBuf := stack.NewPacketBuffer(stack.PacketBufferOptions{ packetBuf := stack.NewPacketBuffer(stack.PacketBufferOptions{
Payload: buffer.MakeWithData(pktCopy), Payload: buffer.MakeWithData(pktCopy),
}) })
n.linkEP.InjectInbound(header.IPv4ProtocolNumber, packetBuf) n.linkEP.InjectInbound(proto, packetBuf)
packetBuf.DecRef() packetBuf.DecRef()
return return
} }
@ -1111,9 +1277,116 @@ func (n *network) HandleEthernetIPv4PacketForRouter(ep EthernetPacket) {
return return
} }
//log.Printf("Got packet: %v", packet) n.logf("router got unknown packet: %v", packet)
}
func (n *network) handleIPv6RouterSolicitation(ep EthernetPacket, rs *layers.ICMPv6RouterSolicitation) {
v6 := ep.gp.Layer(layers.LayerTypeIPv6).(*layers.IPv6)
// Send a router advertisement back.
eth := &layers.Ethernet{
SrcMAC: n.mac.HWAddr(),
DstMAC: ep.SrcMAC().HWAddr(),
EthernetType: layers.EthernetTypeIPv6,
}
n.logf("sending IPv6 router advertisement to %v from %v", eth.SrcMAC, eth.DstMAC)
ip := &layers.IPv6{
Version: 6,
HopLimit: 255,
NextHeader: layers.IPProtocolICMPv6,
SrcIP: net.ParseIP("fe80::1"),
DstIP: v6.SrcIP,
}
icmp := &layers.ICMPv6{
TypeCode: layers.CreateICMPv6TypeCode(layers.ICMPv6TypeRouterAdvertisement, 0),
}
pfx := make([]byte, 0, 30) // it's 32 on the wire, once gopacket adds two byte header
pfx = append(pfx, byte(64)) // CIDR length
pfx = append(pfx, byte(0xc0)) // flags: On-Link, Autonomous
pfx = binary.BigEndian.AppendUint32(pfx, 86400) // valid lifetime
pfx = binary.BigEndian.AppendUint32(pfx, 14400) // preferred lifetime
pfx = binary.BigEndian.AppendUint32(pfx, 0) // reserved
wanIP := n.wanIP6.Addr().As16()
pfx = append(pfx, wanIP[:]...)
ra := &layers.ICMPv6RouterAdvertisement{
RouterLifetime: 1800,
Options: []layers.ICMPv6Option{
{
Type: layers.ICMPv6OptPrefixInfo,
Data: pfx,
},
},
}
icmp.SetNetworkLayerForChecksum(ip)
buffer := gopacket.NewSerializeBuffer()
options := gopacket.SerializeOptions{FixLengths: true, ComputeChecksums: true}
if err := gopacket.SerializeLayers(buffer, options, eth, ip, icmp, ra); err != nil {
n.logf("serializing ICMPv6 RA: %v", err)
return
}
n.writeEth(buffer.Bytes())
}
func (n *network) handleIPv6NeighborSolicitation(ep EthernetPacket, ns *layers.ICMPv6NeighborSolicitation) {
v6 := ep.gp.Layer(layers.LayerTypeIPv6).(*layers.IPv6)
targetIP, ok := netip.AddrFromSlice(ns.TargetAddress)
if !ok {
return
}
var srcMAC MAC
if targetIP == netip.MustParseAddr("fe80::1") {
srcMAC = n.mac
} else {
n.logf("Ignoring IPv6 NS request from %v for target %v", ep.SrcMAC(), targetIP)
return
}
n.logf("replying to IPv6 NS %v->%v about target %v (replySrc=%v)", ep.SrcMAC(), ep.DstMAC(), targetIP, srcMAC)
// Send a neighbor advertisement back.
eth := &layers.Ethernet{
SrcMAC: srcMAC.HWAddr(),
DstMAC: ep.SrcMAC().HWAddr(),
EthernetType: layers.EthernetTypeIPv6,
}
ip := &layers.IPv6{
Version: 6,
HopLimit: 255,
NextHeader: layers.IPProtocolICMPv6,
SrcIP: ns.TargetAddress,
DstIP: v6.SrcIP,
}
icmp := &layers.ICMPv6{
TypeCode: layers.CreateICMPv6TypeCode(layers.ICMPv6TypeNeighborAdvertisement, 0),
}
var flags uint8 = 0x40 // solicited
if srcMAC == n.mac {
flags |= 0x80 // router
}
flags |= 0x20 // override
na := &layers.ICMPv6NeighborAdvertisement{
TargetAddress: ns.TargetAddress,
Flags: flags,
}
na.Options = append(na.Options, layers.ICMPv6Option{
Type: layers.ICMPv6OptTargetAddress,
Data: srcMAC.HWAddr(),
})
icmp.SetNetworkLayerForChecksum(ip)
buffer := gopacket.NewSerializeBuffer()
options := gopacket.SerializeOptions{FixLengths: true, ComputeChecksums: true}
if err := gopacket.SerializeLayers(buffer, options, eth, ip, icmp, na); err != nil {
n.logf("serializing ICMPv6 RA: %v", err)
return
}
if !n.writeEth(buffer.Bytes()) {
n.logf("failed to writeEth for IPv6 NA reply for %v", targetIP)
}
} }
// createDHCPResponse creates a DHCPv4 response for the given DHCPv4 request.
func (s *Server) createDHCPResponse(request gopacket.Packet) ([]byte, error) { func (s *Server) createDHCPResponse(request gopacket.Packet) ([]byte, error) {
ethLayer := request.Layer(layers.LayerTypeEthernet).(*layers.Ethernet) ethLayer := request.Layer(layers.LayerTypeEthernet).(*layers.Ethernet)
srcMAC, ok := macOf(ethLayer.SrcMAC) srcMAC, ok := macOf(ethLayer.SrcMAC)
@ -1125,7 +1398,7 @@ func (s *Server) createDHCPResponse(request gopacket.Packet) ([]byte, error) {
log.Printf("DHCP request from unknown node %v; ignoring", srcMAC) log.Printf("DHCP request from unknown node %v; ignoring", srcMAC)
return nil, nil return nil, nil
} }
gwIP := node.net.lanIP.Addr() gwIP := node.net.lanIP4.Addr()
ipLayer := request.Layer(layers.LayerTypeIPv4).(*layers.IPv4) ipLayer := request.Layer(layers.LayerTypeIPv4).(*layers.IPv4)
udpLayer := request.Layer(layers.LayerTypeUDP).(*layers.UDP) udpLayer := request.Layer(layers.LayerTypeUDP).(*layers.UDP)
@ -1185,7 +1458,7 @@ func (s *Server) createDHCPResponse(request gopacket.Packet) ([]byte, error) {
}, },
layers.DHCPOption{ layers.DHCPOption{
Type: layers.DHCPOptSubnetMask, Type: layers.DHCPOptSubnetMask,
Data: net.CIDRMask(node.net.lanIP.Bits(), 32), Data: net.CIDRMask(node.net.lanIP4.Bits(), 32),
Length: 4, Length: 4,
}, },
) )
@ -1194,7 +1467,7 @@ func (s *Server) createDHCPResponse(request gopacket.Packet) ([]byte, error) {
eth := &layers.Ethernet{ eth := &layers.Ethernet{
SrcMAC: node.net.mac.HWAddr(), SrcMAC: node.net.mac.HWAddr(),
DstMAC: ethLayer.SrcMAC, DstMAC: ethLayer.SrcMAC,
EthernetType: layers.EthernetTypeIPv4, EthernetType: layers.EthernetTypeIPv4, // never IPv6 for DHCP
} }
ip := &layers.IPv4{ ip := &layers.IPv4{
@ -1249,48 +1522,80 @@ func (s *Server) shouldInterceptTCP(pkt gopacket.Packet) bool {
if !ok { if !ok {
return false return false
} }
ipv4, ok := pkt.Layer(layers.LayerTypeIPv4).(*layers.IPv4)
if !ok {
return false
}
if tcp.DstPort == 123 { if tcp.DstPort == 123 {
// Test port for TCP interception. Not really useful, but cute for // Test port for TCP interception. Not really useful, but cute for
// demos. // demos.
return true return true
} }
dstIP, _ := netip.AddrFromSlice(ipv4.DstIP.To4()) flow, ok := flow(pkt)
if !ok {
return false
}
if tcp.DstPort == 80 || tcp.DstPort == 443 { if tcp.DstPort == 80 || tcp.DstPort == 443 {
for _, v := range []virtualIP{fakeControl, fakeDERP1, fakeDERP2, fakeLogCatcher} { for _, v := range []virtualIP{fakeControl, fakeDERP1, fakeDERP2, fakeLogCatcher} {
if v.Match(dstIP) { if v.Match(flow.dst) {
return true return true
} }
} }
if fakeProxyControlplane.Match(dstIP) { if fakeProxyControlplane.Match(flow.dst) {
return s.blendReality return s.blendReality
} }
if s.derpIPs.Contains(dstIP) { if s.derpIPs.Contains(flow.dst) {
return true return true
} }
} }
if tcp.DstPort == 8008 && fakeTestAgent.Match(dstIP) { if tcp.DstPort == 8008 && fakeTestAgent.Match(flow.dst) {
// Connection from cmd/tta. // Connection from cmd/tta.
return true return true
} }
return false return false
} }
type ipSrcDst struct {
src netip.Addr
dst netip.Addr
}
func (f ipSrcDst) etherType() layers.EthernetType {
if f.dst.Is6() {
return layers.EthernetTypeIPv6
}
return layers.EthernetTypeIPv4
}
func (p UDPPacket) etherType() layers.EthernetType {
if p.Dst.Addr().Is6() {
return layers.EthernetTypeIPv6
}
return layers.EthernetTypeIPv4
}
func flow(gp gopacket.Packet) (f ipSrcDst, ok bool) {
if gp == nil {
return f, false
}
n := gp.NetworkLayer()
if n == nil {
return f, false
}
sb, db := n.NetworkFlow().Endpoints()
src, _ := netip.AddrFromSlice(sb.Raw())
dst, _ := netip.AddrFromSlice(db.Raw())
return ipSrcDst{src: src, dst: dst}, src.IsValid() && dst.IsValid()
}
// isDNSRequest reports whether pkt is a DNS request to the fake DNS server. // isDNSRequest reports whether pkt is a DNS request to the fake DNS server.
func isDNSRequest(pkt gopacket.Packet) bool { func isDNSRequest(pkt gopacket.Packet) bool {
udp, ok := pkt.Layer(layers.LayerTypeUDP).(*layers.UDP) udp, ok := pkt.Layer(layers.LayerTypeUDP).(*layers.UDP)
if !ok || udp.DstPort != 53 { if !ok || udp.DstPort != 53 {
return false return false
} }
ip, ok := pkt.Layer(layers.LayerTypeIPv4).(*layers.IPv4) f, ok := flow(pkt)
if !ok { if !ok {
return false return false
} }
dstIP, ok := netip.AddrFromSlice(ip.DstIP) if !fakeDNS.Match(f.dst) {
if !ok || !fakeDNS.Match(dstIP) { // TODO(bradfitz): maybe support configs where DNS is local in the LAN
return false return false
} }
dns, ok := pkt.Layer(layers.LayerTypeDNS).(*layers.DNS) dns, ok := pkt.Layer(layers.LayerTypeDNS).(*layers.DNS)
@ -1316,8 +1621,11 @@ func makeSTUNReply(req UDPPacket) (res UDPPacket, ok bool) {
} }
func (s *Server) createDNSResponse(pkt gopacket.Packet) ([]byte, error) { func (s *Server) createDNSResponse(pkt gopacket.Packet) ([]byte, error) {
flow, ok := flow(pkt)
if !ok {
return nil, nil
}
ethLayer := pkt.Layer(layers.LayerTypeEthernet).(*layers.Ethernet) ethLayer := pkt.Layer(layers.LayerTypeEthernet).(*layers.Ethernet)
ipLayer := pkt.Layer(layers.LayerTypeIPv4).(*layers.IPv4)
udpLayer := pkt.Layer(layers.LayerTypeUDP).(*layers.UDP) udpLayer := pkt.Layer(layers.LayerTypeUDP).(*layers.UDP)
dnsLayer := pkt.Layer(layers.LayerTypeDNS).(*layers.DNS) dnsLayer := pkt.Layer(layers.LayerTypeDNS).(*layers.DNS)
@ -1349,11 +1657,16 @@ func (s *Server) createDNSResponse(pkt gopacket.Packet) ([]byte, error) {
} }
names = append(names, q.Type.String()+"/"+string(q.Name)) names = append(names, q.Type.String()+"/"+string(q.Name))
if q.Class != layers.DNSClassIN || q.Type != layers.DNSTypeA { if q.Class != layers.DNSClassIN {
continue continue
} }
if ip, ok := s.IPv4ForDNS(string(q.Name)); ok { if q.Type == layers.DNSTypeA || q.Type == layers.DNSTypeAAAA {
if v, ok := vips[string(q.Name)]; ok {
ip := v.v4
if q.Type == layers.DNSTypeAAAA {
ip = v.v6
}
response.ANCount++ response.ANCount++
response.Answers = append(response.Answers, layers.DNSResourceRecord{ response.Answers = append(response.Answers, layers.DNSResourceRecord{
Name: q.Name, Name: q.Name,
@ -1364,19 +1677,15 @@ func (s *Server) createDNSResponse(pkt gopacket.Packet) ([]byte, error) {
}) })
} }
} }
}
// Make reply layers, all reversed.
eth2 := &layers.Ethernet{ eth2 := &layers.Ethernet{
SrcMAC: ethLayer.DstMAC, SrcMAC: ethLayer.DstMAC,
DstMAC: ethLayer.SrcMAC, DstMAC: ethLayer.SrcMAC,
EthernetType: layers.EthernetTypeIPv4, EthernetType: flow.etherType(),
}
ip2 := &layers.IPv4{
Version: 4,
TTL: 64,
Protocol: layers.IPProtocolUDP,
SrcIP: ipLayer.DstIP,
DstIP: ipLayer.SrcIP,
} }
ip2 := mkIPLayer(layers.IPProtocolUDP, flow.dst, flow.src)
udp2 := &layers.UDP{ udp2 := &layers.UDP{
SrcPort: udpLayer.DstPort, SrcPort: udpLayer.DstPort,
DstPort: udpLayer.SrcPort, DstPort: udpLayer.SrcPort,
@ -1393,7 +1702,7 @@ func (s *Server) createDNSResponse(pkt gopacket.Packet) ([]byte, error) {
if debugDNS { if debugDNS {
if len(response.Answers) > 0 { if len(response.Answers) > 0 {
back := gopacket.NewPacket(buffer.Bytes(), layers.LayerTypeEthernet, gopacket.Lazy) back := gopacket.NewPacket(buffer.Bytes(), layers.LayerTypeEthernet, gopacket.Lazy)
log.Printf("Generated: %v", back) log.Printf("createDNSResponse generated answers: %v", back)
} else { } else {
log.Printf("made empty response for %q", names) log.Printf("made empty response for %q", names)
} }
@ -1409,6 +1718,11 @@ func (s *Server) createDNSResponse(pkt gopacket.Packet) ([]byte, error) {
// //
// If newSrc is invalid, the packet should be dropped. // If newSrc is invalid, the packet should be dropped.
func (n *network) doNATOut(src, dst netip.AddrPort) (newSrc netip.AddrPort) { func (n *network) doNATOut(src, dst netip.AddrPort) (newSrc netip.AddrPort) {
if src.Addr().Is6() {
// TODO(bradfitz): IPv6 NAT? For now, normal IPv6 only.
return src
}
n.natMu.Lock() n.natMu.Lock()
defer n.natMu.Unlock() defer n.natMu.Unlock()
@ -1433,6 +1747,11 @@ type portmapFlowKey struct {
// //
// If newDst is invalid, the packet should be dropped. // If newDst is invalid, the packet should be dropped.
func (n *network) doNATIn(src, dst netip.AddrPort) (newDst netip.AddrPort) { func (n *network) doNATIn(src, dst netip.AddrPort) (newDst netip.AddrPort) {
if dst.Addr().Is6() {
// TODO(bradfitz): IPv6 NAT? For now, normal IPv6 only.
return dst
}
n.natMu.Lock() n.natMu.Lock()
defer n.natMu.Unlock() defer n.natMu.Unlock()
@ -1473,7 +1792,7 @@ func (n *network) doPortMap(src netip.Addr, dstLANPort, wantExtPort uint16, sec
return 0, false return 0, false
} }
wanAP := netip.AddrPortFrom(n.wanIP, wantExtPort) wanAP := netip.AddrPortFrom(n.wanIP4, wantExtPort)
dst := netip.AddrPortFrom(src, dstLANPort) dst := netip.AddrPortFrom(src, dstLANPort)
if sec == 0 { if sec == 0 {
@ -1505,7 +1824,7 @@ func (n *network) doPortMap(src netip.Addr, dstLANPort, wantExtPort uint16, sec
return wanAP.Port(), true return wanAP.Port(), true
} }
wantExtPort = rand.N(uint16(32<<10)) + 32<<10 wantExtPort = rand.N(uint16(32<<10)) + 32<<10
wanAP = netip.AddrPortFrom(n.wanIP, wantExtPort) wanAP = netip.AddrPortFrom(n.wanIP4, wantExtPort)
} }
return 0, false return 0, false
} }
@ -1540,7 +1859,7 @@ func (n *network) createARPResponse(pkt gopacket.Packet) ([]byte, error) {
a2 := &layers.ARP{ a2 := &layers.ARP{
AddrType: layers.LinkTypeEthernet, AddrType: layers.LinkTypeEthernet,
Protocol: layers.EthernetTypeIPv4, Protocol: layers.EthernetTypeIPv4, // never IPv6; IPv6 equivalent of ARP is handleIPv6NeighborSolicitation
HwAddressSize: 6, HwAddressSize: 6,
ProtAddressSize: 4, ProtAddressSize: 4,
Operation: layers.ARPReply, Operation: layers.ARPReply,
@ -1573,7 +1892,7 @@ func (n *network) handleNATPMPRequest(req UDPPacket) {
0, 0, // result code success 0, 0, // result code success
) )
res = binary.BigEndian.AppendUint32(res, uint32(time.Now().Unix())) res = binary.BigEndian.AppendUint32(res, uint32(time.Now().Unix()))
wan4 := n.wanIP.As4() wan4 := n.wanIP4.As4()
res = append(res, wan4[:]...) res = append(res, wan4[:]...)
n.WriteUDPPacketNoNAT(UDPPacket{ n.WriteUDPPacketNoNAT(UDPPacket{
Src: req.Dst, Src: req.Dst,
@ -1637,7 +1956,7 @@ func (s *Server) WriteStartingBanner(w io.Writer) {
fmt.Fprintf(w, "vnet serving clients:\n") fmt.Fprintf(w, "vnet serving clients:\n")
for _, n := range s.nodes { for _, n := range s.nodes {
fmt.Fprintf(w, " %v %15v (%v, %v)\n", n.mac, n.lanIP, n.net.wanIP, n.net.natStyle.Load()) fmt.Fprintf(w, " %v %15v (%v, %v)\n", n.mac, n.lanIP, n.net.wanIP4, n.net.natStyle.Load())
} }
} }

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