nebula/lighthouse_test.go

430 lines
14 KiB
Go

package nebula
import (
"fmt"
"net"
"testing"
"github.com/slackhq/nebula/config"
"github.com/slackhq/nebula/header"
"github.com/slackhq/nebula/iputil"
"github.com/slackhq/nebula/test"
"github.com/slackhq/nebula/udp"
"github.com/stretchr/testify/assert"
)
//TODO: Add a test to ensure udpAddr is copied and not reused
func TestOldIPv4Only(t *testing.T) {
// This test ensures our new ipv6 enabled LH protobuf IpAndPorts works with the old style to enable backwards compatibility
b := []byte{8, 129, 130, 132, 80, 16, 10}
var m Ip4AndPort
err := m.Unmarshal(b)
assert.NoError(t, err)
assert.Equal(t, "10.1.1.1", iputil.VpnIp(m.GetIp()).String())
}
func TestNewLhQuery(t *testing.T) {
myIp := net.ParseIP("192.1.1.1")
myIpint := iputil.Ip2VpnIp(myIp)
// Generating a new lh query should work
a := NewLhQueryByInt(myIpint)
// The result should be a nebulameta protobuf
assert.IsType(t, &NebulaMeta{}, a)
// It should also Marshal fine
b, err := a.Marshal()
assert.Nil(t, err)
// and then Unmarshal fine
n := &NebulaMeta{}
err = n.Unmarshal(b)
assert.Nil(t, err)
}
func Test_lhStaticMapping(t *testing.T) {
l := test.NewLogger()
_, myVpnNet, _ := net.ParseCIDR("10.128.0.1/16")
lh1 := "10.128.0.2"
c := config.NewC(l)
c.Settings["lighthouse"] = map[interface{}]interface{}{"hosts": []interface{}{lh1}}
c.Settings["static_host_map"] = map[interface{}]interface{}{lh1: []interface{}{"1.1.1.1:4242"}}
_, err := NewLightHouseFromConfig(l, c, myVpnNet, nil, nil)
assert.Nil(t, err)
lh2 := "10.128.0.3"
c = config.NewC(l)
c.Settings["lighthouse"] = map[interface{}]interface{}{"hosts": []interface{}{lh1, lh2}}
c.Settings["static_host_map"] = map[interface{}]interface{}{lh1: []interface{}{"100.1.1.1:4242"}}
_, err = NewLightHouseFromConfig(l, c, myVpnNet, nil, nil)
assert.EqualError(t, err, "lighthouse 10.128.0.3 does not have a static_host_map entry")
}
func BenchmarkLighthouseHandleRequest(b *testing.B) {
l := test.NewLogger()
_, myVpnNet, _ := net.ParseCIDR("10.128.0.1/0")
c := config.NewC(l)
lh, err := NewLightHouseFromConfig(l, c, myVpnNet, nil, nil)
if !assert.NoError(b, err) {
b.Fatal()
}
hAddr := udp.NewAddrFromString("4.5.6.7:12345")
hAddr2 := udp.NewAddrFromString("4.5.6.7:12346")
lh.addrMap[3] = NewRemoteList()
lh.addrMap[3].unlockedSetV4(
3,
3,
[]*Ip4AndPort{
NewIp4AndPort(hAddr.IP, uint32(hAddr.Port)),
NewIp4AndPort(hAddr2.IP, uint32(hAddr2.Port)),
},
func(iputil.VpnIp, *Ip4AndPort) bool { return true },
)
rAddr := udp.NewAddrFromString("1.2.2.3:12345")
rAddr2 := udp.NewAddrFromString("1.2.2.3:12346")
lh.addrMap[2] = NewRemoteList()
lh.addrMap[2].unlockedSetV4(
3,
3,
[]*Ip4AndPort{
NewIp4AndPort(rAddr.IP, uint32(rAddr.Port)),
NewIp4AndPort(rAddr2.IP, uint32(rAddr2.Port)),
},
func(iputil.VpnIp, *Ip4AndPort) bool { return true },
)
mw := &mockEncWriter{}
b.Run("notfound", func(b *testing.B) {
lhh := lh.NewRequestHandler()
req := &NebulaMeta{
Type: NebulaMeta_HostQuery,
Details: &NebulaMetaDetails{
VpnIp: 4,
Ip4AndPorts: nil,
},
}
p, err := req.Marshal()
assert.NoError(b, err)
for n := 0; n < b.N; n++ {
lhh.HandleRequest(rAddr, 2, p, mw)
}
})
b.Run("found", func(b *testing.B) {
lhh := lh.NewRequestHandler()
req := &NebulaMeta{
Type: NebulaMeta_HostQuery,
Details: &NebulaMetaDetails{
VpnIp: 3,
Ip4AndPorts: nil,
},
}
p, err := req.Marshal()
assert.NoError(b, err)
for n := 0; n < b.N; n++ {
lhh.HandleRequest(rAddr, 2, p, mw)
}
})
}
func TestLighthouse_Memory(t *testing.T) {
l := test.NewLogger()
myUdpAddr0 := &udp.Addr{IP: net.ParseIP("10.0.0.2"), Port: 4242}
myUdpAddr1 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4242}
myUdpAddr2 := &udp.Addr{IP: net.ParseIP("172.16.0.2"), Port: 4242}
myUdpAddr3 := &udp.Addr{IP: net.ParseIP("100.152.0.2"), Port: 4242}
myUdpAddr4 := &udp.Addr{IP: net.ParseIP("24.15.0.2"), Port: 4242}
myUdpAddr5 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4243}
myUdpAddr6 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4244}
myUdpAddr7 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4245}
myUdpAddr8 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4246}
myUdpAddr9 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4247}
myUdpAddr10 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4248}
myUdpAddr11 := &udp.Addr{IP: net.ParseIP("192.168.0.2"), Port: 4249}
myVpnIp := iputil.Ip2VpnIp(net.ParseIP("10.128.0.2"))
theirUdpAddr0 := &udp.Addr{IP: net.ParseIP("10.0.0.3"), Port: 4242}
theirUdpAddr1 := &udp.Addr{IP: net.ParseIP("192.168.0.3"), Port: 4242}
theirUdpAddr2 := &udp.Addr{IP: net.ParseIP("172.16.0.3"), Port: 4242}
theirUdpAddr3 := &udp.Addr{IP: net.ParseIP("100.152.0.3"), Port: 4242}
theirUdpAddr4 := &udp.Addr{IP: net.ParseIP("24.15.0.3"), Port: 4242}
theirVpnIp := iputil.Ip2VpnIp(net.ParseIP("10.128.0.3"))
c := config.NewC(l)
c.Settings["lighthouse"] = map[interface{}]interface{}{"am_lighthouse": true}
c.Settings["listen"] = map[interface{}]interface{}{"port": 4242}
lh, err := NewLightHouseFromConfig(l, c, &net.IPNet{IP: net.IP{10, 128, 0, 1}, Mask: net.IPMask{255, 255, 255, 0}}, nil, nil)
assert.NoError(t, err)
lhh := lh.NewRequestHandler()
// Test that my first update responds with just that
newLHHostUpdate(myUdpAddr0, myVpnIp, []*udp.Addr{myUdpAddr1, myUdpAddr2}, lhh)
r := newLHHostRequest(myUdpAddr0, myVpnIp, myVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, myUdpAddr1, myUdpAddr2)
// Ensure we don't accumulate addresses
newLHHostUpdate(myUdpAddr0, myVpnIp, []*udp.Addr{myUdpAddr3}, lhh)
r = newLHHostRequest(myUdpAddr0, myVpnIp, myVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, myUdpAddr3)
// Grow it back to 2
newLHHostUpdate(myUdpAddr0, myVpnIp, []*udp.Addr{myUdpAddr1, myUdpAddr4}, lhh)
r = newLHHostRequest(myUdpAddr0, myVpnIp, myVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, myUdpAddr1, myUdpAddr4)
// Update a different host and ask about it
newLHHostUpdate(theirUdpAddr0, theirVpnIp, []*udp.Addr{theirUdpAddr1, theirUdpAddr2, theirUdpAddr3, theirUdpAddr4}, lhh)
r = newLHHostRequest(theirUdpAddr0, theirVpnIp, theirVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, theirUdpAddr1, theirUdpAddr2, theirUdpAddr3, theirUdpAddr4)
// Have both hosts ask about the other
r = newLHHostRequest(theirUdpAddr0, theirVpnIp, myVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, myUdpAddr1, myUdpAddr4)
r = newLHHostRequest(myUdpAddr0, myVpnIp, theirVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, theirUdpAddr1, theirUdpAddr2, theirUdpAddr3, theirUdpAddr4)
// Make sure we didn't get changed
r = newLHHostRequest(myUdpAddr0, myVpnIp, myVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, myUdpAddr1, myUdpAddr4)
// Ensure proper ordering and limiting
// Send 12 addrs, get 10 back, the last 2 removed, allowing the duplicate to remain (clients dedupe)
newLHHostUpdate(
myUdpAddr0,
myVpnIp,
[]*udp.Addr{
myUdpAddr1,
myUdpAddr2,
myUdpAddr3,
myUdpAddr4,
myUdpAddr5,
myUdpAddr5, //Duplicated on purpose
myUdpAddr6,
myUdpAddr7,
myUdpAddr8,
myUdpAddr9,
myUdpAddr10,
myUdpAddr11, // This should get cut
}, lhh)
r = newLHHostRequest(myUdpAddr0, myVpnIp, myVpnIp, lhh)
assertIp4InArray(
t,
r.msg.Details.Ip4AndPorts,
myUdpAddr1, myUdpAddr2, myUdpAddr3, myUdpAddr4, myUdpAddr5, myUdpAddr5, myUdpAddr6, myUdpAddr7, myUdpAddr8, myUdpAddr9,
)
// Make sure we won't add ips in our vpn network
bad1 := &udp.Addr{IP: net.ParseIP("10.128.0.99"), Port: 4242}
bad2 := &udp.Addr{IP: net.ParseIP("10.128.0.100"), Port: 4242}
good := &udp.Addr{IP: net.ParseIP("1.128.0.99"), Port: 4242}
newLHHostUpdate(myUdpAddr0, myVpnIp, []*udp.Addr{bad1, bad2, good}, lhh)
r = newLHHostRequest(myUdpAddr0, myVpnIp, myVpnIp, lhh)
assertIp4InArray(t, r.msg.Details.Ip4AndPorts, good)
}
func TestLighthouse_reload(t *testing.T) {
l := test.NewLogger()
c := config.NewC(l)
c.Settings["lighthouse"] = map[interface{}]interface{}{"am_lighthouse": true}
c.Settings["listen"] = map[interface{}]interface{}{"port": 4242}
lh, err := NewLightHouseFromConfig(l, c, &net.IPNet{IP: net.IP{10, 128, 0, 1}, Mask: net.IPMask{255, 255, 255, 0}}, nil, nil)
assert.NoError(t, err)
c.Settings["static_host_map"] = map[interface{}]interface{}{"10.128.0.2": []interface{}{"1.1.1.1:4242"}}
lh.reload(c, false)
}
func newLHHostRequest(fromAddr *udp.Addr, myVpnIp, queryVpnIp iputil.VpnIp, lhh *LightHouseHandler) testLhReply {
req := &NebulaMeta{
Type: NebulaMeta_HostQuery,
Details: &NebulaMetaDetails{
VpnIp: uint32(queryVpnIp),
},
}
b, err := req.Marshal()
if err != nil {
panic(err)
}
filter := NebulaMeta_HostQueryReply
w := &testEncWriter{
metaFilter: &filter,
}
lhh.HandleRequest(fromAddr, myVpnIp, b, w)
return w.lastReply
}
func newLHHostUpdate(fromAddr *udp.Addr, vpnIp iputil.VpnIp, addrs []*udp.Addr, lhh *LightHouseHandler) {
req := &NebulaMeta{
Type: NebulaMeta_HostUpdateNotification,
Details: &NebulaMetaDetails{
VpnIp: uint32(vpnIp),
Ip4AndPorts: make([]*Ip4AndPort, len(addrs)),
},
}
for k, v := range addrs {
req.Details.Ip4AndPorts[k] = &Ip4AndPort{Ip: uint32(iputil.Ip2VpnIp(v.IP)), Port: uint32(v.Port)}
}
b, err := req.Marshal()
if err != nil {
panic(err)
}
w := &testEncWriter{}
lhh.HandleRequest(fromAddr, vpnIp, b, w)
}
//TODO: this is a RemoteList test
//func Test_lhRemoteAllowList(t *testing.T) {
// l := NewLogger()
// c := NewConfig(l)
// c.Settings["remoteallowlist"] = map[interface{}]interface{}{
// "10.20.0.0/12": false,
// }
// allowList, err := c.GetAllowList("remoteallowlist", false)
// assert.Nil(t, err)
//
// lh1 := "10.128.0.2"
// lh1IP := net.ParseIP(lh1)
//
// udpServer, _ := NewListener(l, "0.0.0.0", 0, true)
//
// lh := NewLightHouse(l, true, &net.IPNet{IP: net.IP{0, 0, 0, 1}, Mask: net.IPMask{255, 255, 255, 0}}, []uint32{ip2int(lh1IP)}, 10, 10003, udpServer, false, 1, false)
// lh.SetRemoteAllowList(allowList)
//
// // A disallowed ip should not enter the cache but we should end up with an empty entry in the addrMap
// remote1IP := net.ParseIP("10.20.0.3")
// remotes := lh.unlockedGetRemoteList(ip2int(remote1IP))
// remotes.unlockedPrependV4(ip2int(remote1IP), NewIp4AndPort(remote1IP, 4242))
// assert.NotNil(t, lh.addrMap[ip2int(remote1IP)])
// assert.Empty(t, lh.addrMap[ip2int(remote1IP)].CopyAddrs([]*net.IPNet{}))
//
// // Make sure a good ip enters the cache and addrMap
// remote2IP := net.ParseIP("10.128.0.3")
// remote2UDPAddr := NewUDPAddr(remote2IP, uint16(4242))
// lh.addRemoteV4(ip2int(remote2IP), ip2int(remote2IP), NewIp4AndPort(remote2UDPAddr.IP, uint32(remote2UDPAddr.Port)), false, false)
// assertUdpAddrInArray(t, lh.addrMap[ip2int(remote2IP)].CopyAddrs([]*net.IPNet{}), remote2UDPAddr)
//
// // Another good ip gets into the cache, ordering is inverted
// remote3IP := net.ParseIP("10.128.0.4")
// remote3UDPAddr := NewUDPAddr(remote3IP, uint16(4243))
// lh.addRemoteV4(ip2int(remote2IP), ip2int(remote2IP), NewIp4AndPort(remote3UDPAddr.IP, uint32(remote3UDPAddr.Port)), false, false)
// assertUdpAddrInArray(t, lh.addrMap[ip2int(remote2IP)].CopyAddrs([]*net.IPNet{}), remote2UDPAddr, remote3UDPAddr)
//
// // If we exceed the length limit we should only have the most recent addresses
// addedAddrs := []*udpAddr{}
// for i := 0; i < 11; i++ {
// remoteUDPAddr := NewUDPAddr(net.IP{10, 128, 0, 4}, uint16(4243+i))
// lh.addRemoteV4(ip2int(remote2IP), ip2int(remote2IP), NewIp4AndPort(remoteUDPAddr.IP, uint32(remoteUDPAddr.Port)), false, false)
// // The first entry here is a duplicate, don't add it to the assert list
// if i != 0 {
// addedAddrs = append(addedAddrs, remoteUDPAddr)
// }
// }
//
// // We should only have the last 10 of what we tried to add
// assert.True(t, len(addedAddrs) >= 10, "We should have tried to add at least 10 addresses")
// assertUdpAddrInArray(
// t,
// lh.addrMap[ip2int(remote2IP)].CopyAddrs([]*net.IPNet{}),
// addedAddrs[0],
// addedAddrs[1],
// addedAddrs[2],
// addedAddrs[3],
// addedAddrs[4],
// addedAddrs[5],
// addedAddrs[6],
// addedAddrs[7],
// addedAddrs[8],
// addedAddrs[9],
// )
//}
func Test_ipMaskContains(t *testing.T) {
assert.True(t, ipMaskContains(iputil.Ip2VpnIp(net.ParseIP("10.0.0.1")), 32-24, iputil.Ip2VpnIp(net.ParseIP("10.0.0.255"))))
assert.False(t, ipMaskContains(iputil.Ip2VpnIp(net.ParseIP("10.0.0.1")), 32-24, iputil.Ip2VpnIp(net.ParseIP("10.0.1.1"))))
assert.True(t, ipMaskContains(iputil.Ip2VpnIp(net.ParseIP("10.0.0.1")), 32, iputil.Ip2VpnIp(net.ParseIP("10.0.1.1"))))
}
type testLhReply struct {
nebType header.MessageType
nebSubType header.MessageSubType
vpnIp iputil.VpnIp
msg *NebulaMeta
}
type testEncWriter struct {
lastReply testLhReply
metaFilter *NebulaMeta_MessageType
}
func (tw *testEncWriter) SendVia(via *HostInfo, relay *Relay, ad, nb, out []byte, nocopy bool) {
}
func (tw *testEncWriter) Handshake(vpnIp iputil.VpnIp) {
}
func (tw *testEncWriter) SendMessageToVpnIp(t header.MessageType, st header.MessageSubType, vpnIp iputil.VpnIp, p, _, _ []byte) {
msg := &NebulaMeta{}
err := msg.Unmarshal(p)
if tw.metaFilter == nil || msg.Type == *tw.metaFilter {
tw.lastReply = testLhReply{
nebType: t,
nebSubType: st,
vpnIp: vpnIp,
msg: msg,
}
}
if err != nil {
panic(err)
}
}
// assertIp4InArray asserts every address in want is at the same position in have and that the lengths match
func assertIp4InArray(t *testing.T, have []*Ip4AndPort, want ...*udp.Addr) {
if !assert.Len(t, have, len(want)) {
return
}
for k, w := range want {
if !(have[k].Ip == uint32(iputil.Ip2VpnIp(w.IP)) && have[k].Port == uint32(w.Port)) {
assert.Fail(t, fmt.Sprintf("Response did not contain: %v:%v at %v; %v", w.IP, w.Port, k, translateV4toUdpAddr(have)))
}
}
}
// assertUdpAddrInArray asserts every address in want is at the same position in have and that the lengths match
func assertUdpAddrInArray(t *testing.T, have []*udp.Addr, want ...*udp.Addr) {
if !assert.Len(t, have, len(want)) {
return
}
for k, w := range want {
if !(have[k].IP.Equal(w.IP) && have[k].Port == w.Port) {
assert.Fail(t, fmt.Sprintf("Response did not contain: %v at %v; %v", w, k, have))
}
}
}
func translateV4toUdpAddr(ips []*Ip4AndPort) []*udp.Addr {
addrs := make([]*udp.Addr, len(ips))
for k, v := range ips {
addrs[k] = NewUDPAddrFromLH4(v)
}
return addrs
}