Files
tailscale/ipn/ipnlocal/node_backend_test.go
Brad Fitzpatrick 7e609b2581 ipn/ipnlocal,net/dns/resolver: serve MagicDNS names from live indexes
Every netmap change, including an incremental delta of a single peer,
rebuilt the full MagicDNS state twice: dnsConfigForNetmap walked all
peers to build the dns.Config.Hosts map, and resolver.SetConfig then
walked that map again to build its reverse (PTR) index. On a tailnet
with 10k peers that is a lot of garbage per delta.

Instead, add a resolver.MagicDNSHosts hook, installed once by
LocalBackend, that the quad-100 resolver consults on demand at query
time. It is backed by nodeBackend's nodeByName, nodeByAddr, and peers
indexes, which are already maintained incrementally as netmap deltas
arrive. The subdomain-resolve capability check also moves to the hook
(checking the node's CapMap at query time), so dns.Config's
SubdomainHosts is no longer populated.

dns.Config.Hosts remains for control's DNS.ExtraRecords, which are
few and which feed the split-DNS decisions in dns.Manager's
compileConfig, and on Windows it still carries every node's records
because the hosts-file fallback path (compileHostEntries) needs the
complete enumerable set. Those compileConfig decisions also consulted
the per-node Hosts entries (hasHostsWithoutSplitDNSRoutes), so a new
Config.MagicDNSHostsUnrouted bit preserves that signal now that node
records are not listed: with MagicDNS names present but MagicDNS
domain routing off, quad-100 stays in the OS resolver path.

One small behavior change: reverse (PTR) lookups now also answer for
node addresses whose forward records are filtered out by the
IPv6-suppression rule (issue #1152), since nodeByAddr indexes all node
addresses. Previously such addresses were absent from the pushed
Hosts map and thus from the reverse index.

Updates #12542
Updates tailscale/corp#43949

Change-Id: I63b99199c2b3b124c08cb8bbaea1f63165095294
Signed-off-by: Brad Fitzpatrick <bradfitz@tailscale.com>
2026-07-14 07:26:41 -07:00

642 lines
21 KiB
Go

// Copyright (c) Tailscale Inc & contributors
// SPDX-License-Identifier: BSD-3-Clause
package ipnlocal
import (
"context"
"errors"
"maps"
"net/netip"
"slices"
"testing"
"time"
"tailscale.com/net/routecheck/peernode"
"tailscale.com/tailcfg"
"tailscale.com/tstest"
"tailscale.com/types/key"
"tailscale.com/types/netmap"
"tailscale.com/types/views"
"tailscale.com/util/dnsname"
"tailscale.com/util/eventbus"
"tailscale.com/util/mak"
"tailscale.com/util/set"
)
func TestNodeBackendReadiness(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
// The node backend is not ready until [nodeBackend.ready] is called,
// and [nodeBackend.Wait] should fail with [context.DeadlineExceeded].
ctx, cancelCtx := context.WithTimeout(context.Background(), 100*time.Millisecond)
defer cancelCtx()
if err := nb.Wait(ctx); err != ctx.Err() {
t.Fatalf("Wait: got %v; want %v", err, ctx.Err())
}
// Start a goroutine to wait for the node backend to become ready.
waitDone := make(chan struct{})
go func() {
if err := nb.Wait(context.Background()); err != nil {
t.Errorf("Wait: got %v; want nil", err)
}
close(waitDone)
}()
// Call [nodeBackend.ready] to indicate that the node backend is now ready.
go nb.ready()
// Once the backend is called, [nodeBackend.Wait] should return immediately without error.
if err := nb.Wait(context.Background()); err != nil {
t.Fatalf("Wait: got %v; want nil", err)
}
// And any pending waiters should also be unblocked.
<-waitDone
}
func TestNodeBackendShutdown(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
shutdownCause := errors.New("test shutdown")
// Start a goroutine to wait for the node backend to become ready.
// This test expects it to block until the node backend shuts down
// and then return the specified shutdown cause.
waitDone := make(chan struct{})
go func() {
if err := nb.Wait(context.Background()); err != shutdownCause {
t.Errorf("Wait: got %v; want %v", err, shutdownCause)
}
close(waitDone)
}()
// Call [nodeBackend.shutdown] to indicate that the node backend is shutting down.
nb.shutdown(shutdownCause)
// Calling it again is fine, but should not change the shutdown cause.
nb.shutdown(errors.New("test shutdown again"))
// After shutdown, [nodeBackend.Wait] should return with the specified shutdown cause.
if err := nb.Wait(context.Background()); err != shutdownCause {
t.Fatalf("Wait: got %v; want %v", err, shutdownCause)
}
// The context associated with the node backend should also be cancelled
// and its cancellation cause should match the shutdown cause.
if err := nb.Context().Err(); !errors.Is(err, context.Canceled) {
t.Fatalf("Context.Err: got %v; want %v", err, context.Canceled)
}
if cause := context.Cause(nb.Context()); cause != shutdownCause {
t.Fatalf("Cause: got %v; want %v", cause, shutdownCause)
}
// And any pending waiters should also be unblocked.
<-waitDone
}
func TestNodeBackendReadyAfterShutdown(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
shutdownCause := errors.New("test shutdown")
nb.shutdown(shutdownCause)
nb.ready() // Calling ready after shutdown is a no-op, but should not panic, etc.
if err := nb.Wait(context.Background()); err != shutdownCause {
t.Fatalf("Wait: got %v; want %v", err, shutdownCause)
}
}
func TestNodeBackendParentContextCancellation(t *testing.T) {
ctx, cancelCtx := context.WithCancel(context.Background())
nb := newNodeBackend(ctx, tstest.WhileTestRunningLogger(t), eventbus.New())
cancelCtx()
// Cancelling the parent context should cause [nodeBackend.Wait]
// to return with [context.Canceled].
if err := nb.Wait(context.Background()); !errors.Is(err, context.Canceled) {
t.Fatalf("Wait: got %v; want %v", err, context.Canceled)
}
// And the node backend's context should also be cancelled.
if err := nb.Context().Err(); !errors.Is(err, context.Canceled) {
t.Fatalf("Context.Err: got %v; want %v", err, context.Canceled)
}
}
func TestNodeBackendConcurrentReadyAndShutdown(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
// Calling [nodeBackend.ready] and [nodeBackend.shutdown] concurrently
// should not cause issues, and [nodeBackend.Wait] should unblock,
// but the result of [nodeBackend.Wait] is intentionally undefined.
go nb.ready()
go nb.shutdown(errors.New("test shutdown"))
nb.Wait(context.Background())
}
func TestNodeBackendReachability(t *testing.T) {
for _, tc := range []struct {
name string
// Cap sets [tailcfg.NodeAttrClientSideReachability] on the self
// node.
//
// When disabled, the client relies on the control plane sending
// an accurate peer.Online flag. When enabled, the client
// ignores peer.Online and is forced to return true.
cap bool
// rchk sets [tailcfg.NodeAttrClientSideReachabilityRouteCheck]
// on the self node.
//
// When enabled with [tailcfg.NodeAttrClientSideReachability]
// above, the client ignores peer.Online and determines whether
// it can reach the peer node using [routecheck] reports.
rchk bool
online bool
pong peernode.Reachability
want bool
}{
{
name: "disabled/offline",
cap: false,
online: false,
want: false,
},
{
name: "disabled/online",
cap: false,
online: true,
want: true,
},
{
name: "forced/offline",
cap: true,
rchk: false,
online: false,
want: true,
},
{
name: "forced/online",
cap: true,
rchk: false,
online: true,
want: true,
},
{
name: "routecheck/offline/needs-probe",
cap: true,
rchk: true,
online: false,
pong: peernode.Unknown,
want: false,
},
{
name: "routecheck/offline/unreachable",
cap: true,
rchk: true,
online: false,
pong: peernode.Unreachable,
want: false,
},
{
name: "routecheck/offline/reachable",
cap: true,
rchk: true,
online: false,
pong: peernode.Reachable,
want: true,
},
{
name: "routecheck/online/needs-probe",
cap: true,
rchk: true,
online: true,
pong: peernode.Unknown,
want: true,
},
{
name: "routecheck/online/unreachable",
cap: true,
rchk: true,
online: true,
pong: peernode.Unreachable,
want: false,
},
{
name: "routecheck/online/reachable",
cap: true,
rchk: true,
online: true,
pong: peernode.Reachable,
want: true,
},
} {
t.Run(tc.name, func(t *testing.T) {
self := &tailcfg.Node{
ID: 1,
StableID: "stable1",
Name: "self",
}
if tc.cap {
mak.Set(&self.CapMap, tailcfg.NodeAttrClientSideReachability, nil)
}
if tc.rchk {
mak.Set(&self.CapMap, tailcfg.NodeAttrClientSideReachabilityRouteCheck, nil)
}
peer := &tailcfg.Node{
ID: 2,
StableID: "stable2",
Name: "peer",
Online: &tc.online,
}
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
nb.netMap = &netmap.NetworkMap{
SelfNode: self.View(),
Peers: []tailcfg.NodeView{peer.View()},
// HACK: AllCaps is usually populated by Control
AllCaps: set.SetOf(slices.Collect(maps.Keys(self.CapMap))),
}
got := nb.PeerIsReachable(routecheckReport(tc.pong), peer.View())
if got != tc.want {
t.Errorf("got %v, want %v", got, tc.want)
}
})
}
}
type routecheckReport peernode.Reachability
var _ RouteCheckReport = *new(routecheckReport)
func (rp routecheckReport) IsReachable(_ tailcfg.NodeID) peernode.Reachability {
return peernode.Reachability(rp)
}
func TestNodeBackendRouteManager(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
mkPeer := func(id tailcfg.NodeID, stableID tailcfg.StableNodeID, addr4 string, extra ...string) tailcfg.NodeView {
n := &tailcfg.Node{
ID: id,
StableID: stableID,
Key: key.NewNode().Public(),
HomeDERP: 1, // required by the route manager's reachability filter
Addresses: []netip.Prefix{
netip.MustParsePrefix(addr4),
},
}
n.AllowedIPs = append(n.AllowedIPs, n.Addresses...)
for _, s := range extra {
n.AllowedIPs = append(n.AllowedIPs, netip.MustParsePrefix(s))
}
return n.View()
}
wantPeerFor := func(ip string, want tailcfg.NodeView) {
t.Helper()
got, ok := nb.routeMgr.Outbound().Lookup(netip.MustParseAddr(ip))
if !want.Valid() {
if ok {
t.Errorf("Outbound lookup %s = %v; want no match", ip, got)
}
return
}
if !ok || got.Key != want.Key() {
t.Errorf("Outbound lookup %s = %v, %v; want %v", ip, got, ok, want.Key())
}
}
p1 := mkPeer(1, "stable1", "100.64.0.1/32")
p2 := mkPeer(2, "stable2", "100.64.0.2/32", "0.0.0.0/0", "::/0")
// A full netmap populates the route manager.
nb.SetNetMap(&netmap.NetworkMap{Peers: []tailcfg.NodeView{p1, p2}})
wantPeerFor("100.64.0.1", p1)
wantPeerFor("100.64.0.2", p2)
wantPeerFor("8.8.8.8", tailcfg.NodeView{}) // exit node not selected
// Selecting peer 2 as the exit node resolves its stable ID and
// installs its /0 routes. The commit reports peer 2's allowed
// prefixes as changed.
if changed := nb.updateRouteManagerPrefs(routePrefs{ExitNodeID: "stable2", ExitNodeSelected: true}); len(changed) != 1 || changed[p2.Key()] == nil {
t.Errorf("updateRouteManagerPrefs(exit=stable2) changed = %v; want just %v", changed, p2.Key())
}
wantPeerFor("8.8.8.8", p2)
// A selected exit node that resolves to no current peer must
// blackhole internet traffic, not fall back to "no exit node":
// the default routes stay in the OS route set with no outbound
// peer to carry them. Peer 2's allowed prefixes lose the /0s,
// which the commit reports.
if changed := nb.updateRouteManagerPrefs(routePrefs{ExitNodeID: "no-such-node", ExitNodeSelected: true}); len(changed) != 1 || changed[p2.Key()] == nil {
t.Errorf("updateRouteManagerPrefs(exit=unresolved) changed = %v; want just %v", changed, p2.Key())
}
wantPeerFor("8.8.8.8", tailcfg.NodeView{})
if !nb.routeMgr.OSRoutes().Get(netip.MustParsePrefix("0.0.0.0/0")) {
t.Error("unresolved exit node: OSRoutes missing 0.0.0.0/0 blackhole route")
}
nb.updateRouteManagerPrefs(routePrefs{})
wantPeerFor("8.8.8.8", tailcfg.NodeView{})
if nb.routeMgr.OSRoutes().Get(netip.MustParsePrefix("0.0.0.0/0")) {
t.Error("no exit node: OSRoutes unexpectedly contains 0.0.0.0/0")
}
// Incremental deltas: add peer 3, remove peer 1.
p3 := mkPeer(3, "stable3", "100.64.0.3/32")
deltaRes, handled := nb.UpdateNetmapDelta([]netmap.NodeMutation{
netmap.NodeMutationUpsert{Node: p3},
netmap.MakeNodeMutationRemove(1),
})
if !handled {
t.Fatal("UpdateNetmapDelta not handled")
}
if changed := deltaRes.ChangedAllowedIPs; len(changed) != 2 || changed[p3.Key()] == nil {
t.Errorf("UpdateNetmapDelta changed = %v; want entries for %v and %v", changed, p3.Key(), p1.Key())
}
if v, ok := deltaRes.ChangedAllowedIPs[p1.Key()]; !ok || v != nil {
t.Errorf("UpdateNetmapDelta changed[%v] = %v, %v; want nil, true for removed peer", p1.Key(), v, ok)
}
wantPeerFor("100.64.0.3", p3)
wantPeerFor("100.64.0.1", tailcfg.NodeView{})
// A full netmap that drops a peer removes it from the route manager.
nb.SetNetMap(&netmap.NetworkMap{Peers: []tailcfg.NodeView{p2}})
wantPeerFor("100.64.0.3", tailcfg.NodeView{})
wantPeerFor("100.64.0.2", p2)
}
// TestNodeBackendDiscoChanged exercises the full-netmap disco change
// detection: a peer whose disco key changes has restarted and needs its
// WireGuard session reset, unless the new key was already learned over
// TSMP (that is, over a working WireGuard session with the peer).
func TestNodeBackendDiscoChanged(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
nk := key.NewNode().Public()
mkNetMap := func(disco key.DiscoPublic) *netmap.NetworkMap {
n := &tailcfg.Node{
ID: 1,
Key: nk,
DiscoKey: disco,
HomeDERP: 1,
}
return &netmap.NetworkMap{Peers: []tailcfg.NodeView{n.View()}}
}
newDisco := func() key.DiscoPublic { return key.NewDisco().Public() }
// A brand-new peer is not a disco change.
d1 := newDisco()
if got := nb.SetNetMap(mkNetMap(d1)); len(got) != 0 {
t.Errorf("SetNetMap(new peer) discoChanged = %v; want none", got)
}
// A changed disco key requires a session reset.
d2 := newDisco()
if got := nb.SetNetMap(mkNetMap(d2)); !slices.Contains(got, nk) {
t.Errorf("SetNetMap(changed disco) discoChanged = %v; want %v", got, nk)
}
// An unchanged disco key does not.
if got := nb.SetNetMap(mkNetMap(d2)); len(got) != 0 {
t.Errorf("SetNetMap(same disco) discoChanged = %v; want none", got)
}
// A change already learned via TSMP is suppressed...
d3 := newDisco()
nb.recordTSMPLearnedDisco(nk, d3)
if got := nb.SetNetMap(mkNetMap(d3)); len(got) != 0 {
t.Errorf("SetNetMap(TSMP-learned disco) discoChanged = %v; want none", got)
}
// ...but the TSMP entry is consumed, so the next change resets again.
d4 := newDisco()
if got := nb.SetNetMap(mkNetMap(d4)); !slices.Contains(got, nk) {
t.Errorf("SetNetMap(after TSMP entry consumed) discoChanged = %v; want %v", got, nk)
}
// A TSMP-learned key that doesn't match the netmap's new key still
// resets the session and bumps the mismatch metric.
before := metricTSMPLearnedKeyMismatch.Value()
nb.recordTSMPLearnedDisco(nk, newDisco())
d5 := newDisco()
if got := nb.SetNetMap(mkNetMap(d5)); !slices.Contains(got, nk) {
t.Errorf("SetNetMap(TSMP mismatch) discoChanged = %v; want %v", got, nk)
}
if delta := metricTSMPLearnedKeyMismatch.Value() - before; delta != 1 {
t.Errorf("metricTSMPLearnedKeyMismatch delta = %d; want 1", delta)
}
// Removing the peer garbage-collects its TSMP entry: after the peer
// comes back, a change to the once-recorded key is a normal reset.
d6 := newDisco()
nb.recordTSMPLearnedDisco(nk, d6)
nb.SetNetMap(&netmap.NetworkMap{})
nb.SetNetMap(mkNetMap(d5))
if got := nb.SetNetMap(mkNetMap(d6)); !slices.Contains(got, nk) {
t.Errorf("SetNetMap(after TSMP entry GC) discoChanged = %v; want %v", got, nk)
}
// Transitions to or from a zero disco key never reset.
if got := nb.SetNetMap(mkNetMap(key.DiscoPublic{})); len(got) != 0 {
t.Errorf("SetNetMap(to zero disco) discoChanged = %v; want none", got)
}
if got := nb.SetNetMap(mkNetMap(d1)); len(got) != 0 {
t.Errorf("SetNetMap(from zero disco) discoChanged = %v; want none", got)
}
}
// TestNodeBackendDiscoChangedDelta is like TestNodeBackendDiscoChanged
// but for the incremental path: disco changes arriving as
// [netmap.NodeMutationUpsert] deltas.
func TestNodeBackendDiscoChangedDelta(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
mkNode := func(k key.NodePublic, disco key.DiscoPublic) tailcfg.NodeView {
return (&tailcfg.Node{ID: 1, Key: k, DiscoKey: disco, HomeDERP: 1}).View()
}
newDisco := func() key.DiscoPublic { return key.NewDisco().Public() }
apply := func(muts ...netmap.NodeMutation) set.Set[key.NodePublic] {
t.Helper()
deltaRes, handled := nb.UpdateNetmapDelta(muts)
if !handled {
t.Fatal("UpdateNetmapDelta not handled")
}
return deltaRes.DiscoChanged
}
nk := key.NewNode().Public()
d1 := newDisco()
nb.SetNetMap(&netmap.NetworkMap{Peers: []tailcfg.NodeView{mkNode(nk, d1)}})
// An upserted peer with a changed disco key needs a session reset.
d2 := newDisco()
if got := apply(netmap.NodeMutationUpsert{Node: mkNode(nk, d2)}); !got.Contains(nk) {
t.Errorf("upsert(changed disco) discoChanged = %v; want %v", got, nk)
}
// An unchanged disco key does not.
if got := apply(netmap.NodeMutationUpsert{Node: mkNode(nk, d2)}); len(got) != 0 {
t.Errorf("upsert(same disco) discoChanged = %v; want none", got)
}
// A change already learned via TSMP is suppressed.
d3 := newDisco()
nb.recordTSMPLearnedDisco(nk, d3)
if got := apply(netmap.NodeMutationUpsert{Node: mkNode(nk, d3)}); len(got) != 0 {
t.Errorf("upsert(TSMP-learned disco) discoChanged = %v; want none", got)
}
// A node key rotation replaces the WireGuard peer outright, so no
// disco-based reset is reported.
nk2 := key.NewNode().Public()
if got := apply(netmap.NodeMutationUpsert{Node: mkNode(nk2, newDisco())}); len(got) != 0 {
t.Errorf("upsert(rotated node key) discoChanged = %v; want none", got)
}
// Removing the peer garbage-collects its TSMP entry: after the peer
// comes back, a change to the once-recorded key is a normal reset.
d4 := newDisco()
nb.recordTSMPLearnedDisco(nk2, d4)
apply(netmap.MakeNodeMutationRemove(1))
apply(netmap.NodeMutationUpsert{Node: mkNode(nk2, newDisco())})
if got := apply(netmap.NodeMutationUpsert{Node: mkNode(nk2, d4)}); !got.Contains(nk2) {
t.Errorf("upsert(after TSMP entry GC) discoChanged = %v; want %v", got, nk2)
}
}
func TestNodeBackendRouteManagerExtras(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
n := &tailcfg.Node{
ID: 1,
Key: key.NewNode().Public(),
HomeDERP: 1,
Addresses: []netip.Prefix{
netip.MustParsePrefix("100.64.0.1/32"),
},
}
n.AllowedIPs = n.Addresses
p1 := n.View()
nb.SetNetMap(&netmap.NetworkMap{Peers: []tailcfg.NodeView{p1}})
transit := netip.MustParsePrefix("fe80::1234/128")
extrasFor := func(k key.NodePublic) views.Slice[netip.Prefix] {
if k == p1.Key() {
return views.SliceOf([]netip.Prefix{transit})
}
return views.Slice[netip.Prefix]{}
}
// Installing extras reports the peer's allowed prefixes as
// changed and adds the transit IP to the outbound table.
changed := nb.updateRouteManagerExtras(extrasFor)
if len(changed) != 1 || !slices.Contains(changed[p1.Key()], transit) {
t.Errorf("updateRouteManagerExtras changed = %v; want %v including %v", changed, p1.Key(), transit)
}
if pr, ok := nb.routeMgr.Outbound().Lookup(transit.Addr()); !ok || pr.Key != p1.Key() {
t.Errorf("Outbound lookup %v = %v, %v; want %v", transit.Addr(), pr, ok, p1.Key())
}
if nb.routeMgr.OSRoutes().Get(transit) {
t.Errorf("OSRoutes contains %v; extras must not reach the OS route set", transit)
}
// An unchanged hook result is a no-op.
if changed := nb.updateRouteManagerExtras(extrasFor); changed != nil {
t.Errorf("unchanged extras reported changes: %v", changed)
}
// A hook that no longer returns extras removes them.
changed = nb.updateRouteManagerExtras(func(key.NodePublic) views.Slice[netip.Prefix] {
return views.Slice[netip.Prefix]{}
})
if len(changed) != 1 {
t.Errorf("clearing extras changed = %v; want just %v", changed, p1.Key())
}
if _, ok := nb.routeMgr.Outbound().Lookup(transit.Addr()); ok {
t.Errorf("Outbound still routes %v after extras cleared", transit.Addr())
}
}
// Tests the live MagicDNS lookup methods backing
// [resolver.MagicDNSHosts]: forward, reverse, and subdomain-cap
// lookups must serve from the node indexes and stay correct across
// netmap deltas without any full Hosts map rebuild.
func TestNodeBackendMagicDNSHosts(t *testing.T) {
nb := newNodeBackend(t.Context(), tstest.WhileTestRunningLogger(t), eventbus.New())
self := &tailcfg.Node{
ID: 1,
Name: "self.example.ts.net.",
Addresses: []netip.Prefix{netip.MustParsePrefix("100.64.0.1/32")},
}
p1 := &tailcfg.Node{
ID: 2,
Key: key.NewNode().Public(),
Name: "p1.example.ts.net.",
Addresses: []netip.Prefix{
netip.MustParsePrefix("100.64.0.2/32"),
netip.MustParsePrefix("fd7a:115c:a1e0::2/128"),
},
CapMap: tailcfg.NodeCapMap{tailcfg.NodeAttrDNSSubdomainResolve: nil},
}
nb.SetNetMap(&netmap.NetworkMap{
SelfNode: self.View(),
Peers: []tailcfg.NodeView{p1.View()},
})
wantHost := func(fqdn dnsname.FQDN, want ...netip.Addr) {
t.Helper()
ips, ok := nb.magicDNSHostAddrs(fqdn)
if len(want) == 0 {
if ok {
t.Errorf("magicDNSHostAddrs(%q) = %v; want no match", fqdn, ips)
}
return
}
if !ok || !slices.Equal(ips, want) {
t.Errorf("magicDNSHostAddrs(%q) = %v, %v; want %v", fqdn, ips, ok, want)
}
}
// The self node has IPv4, so the peer's IPv6 address is
// filtered out (issue 1152).
wantHost("p1.example.ts.net.", netip.MustParseAddr("100.64.0.2"))
wantHost("self.example.ts.net.", netip.MustParseAddr("100.64.0.1"))
wantHost("unknown.example.ts.net.")
if fqdn, ok := nb.magicDNSPTR(netip.MustParseAddr("100.64.0.2")); !ok || fqdn != "p1.example.ts.net." {
t.Errorf("magicDNSPTR(100.64.0.2) = %q, %v; want p1's name", fqdn, ok)
}
if got, want := nb.magicDNSSubdomainHost("p1.example.ts.net."), true; got != want {
t.Errorf("magicDNSSubdomainHost(p1) = %v; want %v", got, want)
}
if got, want := nb.magicDNSSubdomainHost("self.example.ts.net."), false; got != want {
t.Errorf("magicDNSSubdomainHost(self) = %v; want %v", got, want)
}
// Removing the peer via a delta drops its records.
if _, handled := nb.UpdateNetmapDelta([]netmap.NodeMutation{netmap.MakeNodeMutationRemove(2)}); !handled {
t.Fatal("UpdateNetmapDelta not handled")
}
wantHost("p1.example.ts.net.")
if fqdn, ok := nb.magicDNSPTR(netip.MustParseAddr("100.64.0.2")); ok {
t.Errorf("magicDNSPTR(100.64.0.2) after removal = %q; want no match", fqdn)
}
// Adding a peer via a delta serves it immediately.
p3 := &tailcfg.Node{
ID: 3,
Key: key.NewNode().Public(),
Name: "p3.example.ts.net.",
Addresses: []netip.Prefix{netip.MustParsePrefix("100.64.0.3/32")},
}
if _, handled := nb.UpdateNetmapDelta([]netmap.NodeMutation{netmap.NodeMutationUpsert{Node: p3.View()}}); !handled {
t.Fatal("UpdateNetmapDelta not handled")
}
wantHost("p3.example.ts.net.", netip.MustParseAddr("100.64.0.3"))
}