// Copyright 2020 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package stack import ( "encoding/binary" "math" "testing" "time" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" ) const ( fwdTestNetNumber tcpip.NetworkProtocolNumber = math.MaxUint32 fwdTestNetHeaderLen = 12 fwdTestNetDefaultPrefixLen = 8 // fwdTestNetDefaultMTU is the MTU, in bytes, used throughout the tests, // except where another value is explicitly used. It is chosen to match // the MTU of loopback interfaces on linux systems. fwdTestNetDefaultMTU = 65536 dstAddrOffset = 0 srcAddrOffset = 1 protocolNumberOffset = 2 ) var _ LinkAddressResolver = (*fwdTestNetworkEndpoint)(nil) var _ NetworkEndpoint = (*fwdTestNetworkEndpoint)(nil) // fwdTestNetworkEndpoint is a network-layer protocol endpoint. // Headers of this protocol are fwdTestNetHeaderLen bytes, but we currently only // use the first three: destination address, source address, and transport // protocol. They're all one byte fields to simplify parsing. type fwdTestNetworkEndpoint struct { AddressableEndpointState nic NetworkInterface proto *fwdTestNetworkProtocol dispatcher TransportDispatcher mu struct { sync.RWMutex forwarding bool } } func (*fwdTestNetworkEndpoint) Enable() tcpip.Error { return nil } func (*fwdTestNetworkEndpoint) Enabled() bool { return true } func (*fwdTestNetworkEndpoint) Disable() {} func (f *fwdTestNetworkEndpoint) MTU() uint32 { return f.nic.MTU() - uint32(f.MaxHeaderLength()) } func (*fwdTestNetworkEndpoint) DefaultTTL() uint8 { return 123 } func (f *fwdTestNetworkEndpoint) HandlePacket(pkt *PacketBuffer) { if _, _, ok := f.proto.Parse(pkt); !ok { return } netHdr := pkt.NetworkHeader().View() _, dst := f.proto.ParseAddresses(netHdr) addressEndpoint := f.AcquireAssignedAddress(dst, f.nic.Promiscuous(), CanBePrimaryEndpoint) if addressEndpoint != nil { addressEndpoint.DecRef() // Dispatch the packet to the transport protocol. f.dispatcher.DeliverTransportPacket(tcpip.TransportProtocolNumber(netHdr[protocolNumberOffset]), pkt) return } r, err := f.proto.stack.FindRoute(0, "", dst, fwdTestNetNumber, false /* multicastLoop */) if err != nil { return } defer r.Release() vv := buffer.NewVectorisedView(pkt.Size(), pkt.Views()) pkt = NewPacketBuffer(PacketBufferOptions{ ReserveHeaderBytes: int(r.MaxHeaderLength()), Data: vv.ToView().ToVectorisedView(), }) // TODO(gvisor.dev/issue/1085) Decrease the TTL field in forwarded packets. _ = r.WriteHeaderIncludedPacket(pkt) } func (f *fwdTestNetworkEndpoint) MaxHeaderLength() uint16 { return f.nic.MaxHeaderLength() + fwdTestNetHeaderLen } func (*fwdTestNetworkEndpoint) PseudoHeaderChecksum(protocol tcpip.TransportProtocolNumber, dstAddr tcpip.Address) uint16 { return 0 } func (f *fwdTestNetworkEndpoint) NetworkProtocolNumber() tcpip.NetworkProtocolNumber { return f.proto.Number() } func (f *fwdTestNetworkEndpoint) WritePacket(r *Route, params NetworkHeaderParams, pkt *PacketBuffer) tcpip.Error { // Add the protocol's header to the packet and send it to the link // endpoint. b := pkt.NetworkHeader().Push(fwdTestNetHeaderLen) b[dstAddrOffset] = r.RemoteAddress()[0] b[srcAddrOffset] = r.LocalAddress()[0] b[protocolNumberOffset] = byte(params.Protocol) return f.nic.WritePacket(r, fwdTestNetNumber, pkt) } // WritePackets implements LinkEndpoint.WritePackets. func (*fwdTestNetworkEndpoint) WritePackets(r *Route, pkts PacketBufferList, params NetworkHeaderParams) (int, tcpip.Error) { panic("not implemented") } func (f *fwdTestNetworkEndpoint) WriteHeaderIncludedPacket(r *Route, pkt *PacketBuffer) tcpip.Error { // The network header should not already be populated. if _, ok := pkt.NetworkHeader().Consume(fwdTestNetHeaderLen); !ok { return &tcpip.ErrMalformedHeader{} } return f.nic.WritePacket(r, fwdTestNetNumber, pkt) } func (f *fwdTestNetworkEndpoint) Close() { f.AddressableEndpointState.Cleanup() } // Stats implements stack.NetworkEndpoint. func (*fwdTestNetworkEndpoint) Stats() NetworkEndpointStats { return &fwdTestNetworkEndpointStats{} } var _ NetworkEndpointStats = (*fwdTestNetworkEndpointStats)(nil) type fwdTestNetworkEndpointStats struct{} // IsNetworkEndpointStats implements stack.NetworkEndpointStats. func (*fwdTestNetworkEndpointStats) IsNetworkEndpointStats() {} var _ NetworkProtocol = (*fwdTestNetworkProtocol)(nil) // fwdTestNetworkProtocol is a network-layer protocol that implements Address // resolution. type fwdTestNetworkProtocol struct { stack *Stack neigh *neighborCache addrResolveDelay time.Duration onLinkAddressResolved func(*neighborCache, tcpip.Address, tcpip.LinkAddress) onResolveStaticAddress func(tcpip.Address) (tcpip.LinkAddress, bool) } func (*fwdTestNetworkProtocol) Number() tcpip.NetworkProtocolNumber { return fwdTestNetNumber } func (*fwdTestNetworkProtocol) MinimumPacketSize() int { return fwdTestNetHeaderLen } func (*fwdTestNetworkProtocol) DefaultPrefixLen() int { return fwdTestNetDefaultPrefixLen } func (*fwdTestNetworkProtocol) ParseAddresses(v buffer.View) (src, dst tcpip.Address) { return tcpip.Address(v[srcAddrOffset : srcAddrOffset+1]), tcpip.Address(v[dstAddrOffset : dstAddrOffset+1]) } func (*fwdTestNetworkProtocol) Parse(pkt *PacketBuffer) (tcpip.TransportProtocolNumber, bool, bool) { netHeader, ok := pkt.NetworkHeader().Consume(fwdTestNetHeaderLen) if !ok { return 0, false, false } return tcpip.TransportProtocolNumber(netHeader[protocolNumberOffset]), true, true } func (f *fwdTestNetworkProtocol) NewEndpoint(nic NetworkInterface, dispatcher TransportDispatcher) NetworkEndpoint { e := &fwdTestNetworkEndpoint{ nic: nic, proto: f, dispatcher: dispatcher, } e.AddressableEndpointState.Init(e) return e } func (*fwdTestNetworkProtocol) SetOption(tcpip.SettableNetworkProtocolOption) tcpip.Error { return &tcpip.ErrUnknownProtocolOption{} } func (*fwdTestNetworkProtocol) Option(tcpip.GettableNetworkProtocolOption) tcpip.Error { return &tcpip.ErrUnknownProtocolOption{} } func (*fwdTestNetworkProtocol) Close() {} func (*fwdTestNetworkProtocol) Wait() {} func (f *fwdTestNetworkEndpoint) LinkAddressRequest(addr, _ tcpip.Address, remoteLinkAddr tcpip.LinkAddress) tcpip.Error { if fn := f.proto.onLinkAddressResolved; fn != nil { time.AfterFunc(f.proto.addrResolveDelay, func() { fn(f.proto.neigh, addr, remoteLinkAddr) }) } return nil } func (f *fwdTestNetworkEndpoint) ResolveStaticAddress(addr tcpip.Address) (tcpip.LinkAddress, bool) { if fn := f.proto.onResolveStaticAddress; fn != nil { return fn(addr) } return "", false } func (*fwdTestNetworkEndpoint) LinkAddressProtocol() tcpip.NetworkProtocolNumber { return fwdTestNetNumber } // Forwarding implements stack.ForwardingNetworkEndpoint. func (f *fwdTestNetworkEndpoint) Forwarding() bool { f.mu.RLock() defer f.mu.RUnlock() return f.mu.forwarding } // SetForwarding implements stack.ForwardingNetworkEndpoint. func (f *fwdTestNetworkEndpoint) SetForwarding(v bool) { f.mu.Lock() defer f.mu.Unlock() f.mu.forwarding = v } // fwdTestPacketInfo holds all the information about an outbound packet. type fwdTestPacketInfo struct { RemoteLinkAddress tcpip.LinkAddress LocalLinkAddress tcpip.LinkAddress Pkt *PacketBuffer } var _ LinkEndpoint = (*fwdTestLinkEndpoint)(nil) type fwdTestLinkEndpoint struct { dispatcher NetworkDispatcher mtu uint32 linkAddr tcpip.LinkAddress // C is where outbound packets are queued. C chan fwdTestPacketInfo } // InjectInbound injects an inbound packet. func (e *fwdTestLinkEndpoint) InjectInbound(protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) { e.InjectLinkAddr(protocol, "", pkt) } // InjectLinkAddr injects an inbound packet with a remote link address. func (e *fwdTestLinkEndpoint) InjectLinkAddr(protocol tcpip.NetworkProtocolNumber, remote tcpip.LinkAddress, pkt *PacketBuffer) { e.dispatcher.DeliverNetworkPacket(remote, "" /* local */, protocol, pkt) } // Attach saves the stack network-layer dispatcher for use later when packets // are injected. func (e *fwdTestLinkEndpoint) Attach(dispatcher NetworkDispatcher) { e.dispatcher = dispatcher } // IsAttached implements stack.LinkEndpoint.IsAttached. func (e *fwdTestLinkEndpoint) IsAttached() bool { return e.dispatcher != nil } // MTU implements stack.LinkEndpoint.MTU. It returns the value initialized // during construction. func (e *fwdTestLinkEndpoint) MTU() uint32 { return e.mtu } // Capabilities implements stack.LinkEndpoint.Capabilities. func (e fwdTestLinkEndpoint) Capabilities() LinkEndpointCapabilities { caps := LinkEndpointCapabilities(0) return caps | CapabilityResolutionRequired } // MaxHeaderLength returns the maximum size of the link layer header. Given it // doesn't have a header, it just returns 0. func (*fwdTestLinkEndpoint) MaxHeaderLength() uint16 { return 0 } // LinkAddress returns the link address of this endpoint. func (e *fwdTestLinkEndpoint) LinkAddress() tcpip.LinkAddress { return e.linkAddr } func (e fwdTestLinkEndpoint) WritePacket(r RouteInfo, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) tcpip.Error { p := fwdTestPacketInfo{ RemoteLinkAddress: r.RemoteLinkAddress, LocalLinkAddress: r.LocalLinkAddress, Pkt: pkt, } select { case e.C <- p: default: } return nil } // WritePackets stores outbound packets into the channel. func (e *fwdTestLinkEndpoint) WritePackets(r RouteInfo, pkts PacketBufferList, protocol tcpip.NetworkProtocolNumber) (int, tcpip.Error) { n := 0 for pkt := pkts.Front(); pkt != nil; pkt = pkt.Next() { e.WritePacket(r, protocol, pkt) n++ } return n, nil } // Wait implements stack.LinkEndpoint.Wait. func (*fwdTestLinkEndpoint) Wait() {} // ARPHardwareType implements stack.LinkEndpoint.ARPHardwareType. func (*fwdTestLinkEndpoint) ARPHardwareType() header.ARPHardwareType { panic("not implemented") } // AddHeader implements stack.LinkEndpoint.AddHeader. func (e *fwdTestLinkEndpoint) AddHeader(local, remote tcpip.LinkAddress, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) { panic("not implemented") } func fwdTestNetFactory(t *testing.T, proto *fwdTestNetworkProtocol) (ep1, ep2 *fwdTestLinkEndpoint) { // Create a stack with the network protocol and two NICs. s := New(Options{ NetworkProtocols: []NetworkProtocolFactory{func(s *Stack) NetworkProtocol { proto.stack = s return proto }}, }) protoNum := proto.Number() if err := s.SetForwardingDefaultAndAllNICs(protoNum, true); err != nil { t.Fatalf("SetForwardingDefaultAndAllNICs(%d, true): %s", protoNum, err) } // NIC 1 has the link address "a", and added the network address 1. ep1 = &fwdTestLinkEndpoint{ C: make(chan fwdTestPacketInfo, 300), mtu: fwdTestNetDefaultMTU, linkAddr: "a", } if err := s.CreateNIC(1, ep1); err != nil { t.Fatal("CreateNIC #1 failed:", err) } if err := s.AddAddress(1, fwdTestNetNumber, "\x01"); err != nil { t.Fatal("AddAddress #1 failed:", err) } // NIC 2 has the link address "b", and added the network address 2. ep2 = &fwdTestLinkEndpoint{ C: make(chan fwdTestPacketInfo, 300), mtu: fwdTestNetDefaultMTU, linkAddr: "b", } if err := s.CreateNIC(2, ep2); err != nil { t.Fatal("CreateNIC #2 failed:", err) } if err := s.AddAddress(2, fwdTestNetNumber, "\x02"); err != nil { t.Fatal("AddAddress #2 failed:", err) } nic, ok := s.nics[2] if !ok { t.Fatal("NIC 2 does not exist") } if l, ok := nic.linkAddrResolvers[fwdTestNetNumber]; ok { proto.neigh = &l.neigh } // Route all packets to NIC 2. { subnet, err := tcpip.NewSubnet("\x00", "\x00") if err != nil { t.Fatal(err) } s.SetRouteTable([]tcpip.Route{{Destination: subnet, NIC: 2}}) } return ep1, ep2 } func TestForwardingWithStaticResolver(t *testing.T) { // Create a network protocol with a static resolver. proto := &fwdTestNetworkProtocol{ onResolveStaticAddress: // The network address 3 is resolved to the link address "c". func(addr tcpip.Address) (tcpip.LinkAddress, bool) { if addr == "\x03" { return "c", true } return "", false }, } ep1, ep2 := fwdTestNetFactory(t, proto) // Inject an inbound packet to address 3 on NIC 1, and see if it is // forwarded to NIC 2. buf := buffer.NewView(30) buf[dstAddrOffset] = 3 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) var p fwdTestPacketInfo select { case p = <-ep2.C: default: t.Fatal("packet not forwarded") } // Test that the static address resolution happened correctly. if p.RemoteLinkAddress != "c" { t.Fatalf("got p.RemoteLinkAddress = %s, want = c", p.RemoteLinkAddress) } if p.LocalLinkAddress != "b" { t.Fatalf("got p.LocalLinkAddress = %s, want = b", p.LocalLinkAddress) } } func TestForwardingWithFakeResolver(t *testing.T) { proto := fwdTestNetworkProtocol{ addrResolveDelay: 500 * time.Millisecond, onLinkAddressResolved: func(neigh *neighborCache, addr tcpip.Address, linkAddr tcpip.LinkAddress) { t.Helper() if len(linkAddr) != 0 { t.Fatalf("got linkAddr=%q, want unspecified", linkAddr) } // Any address will be resolved to the link address "c". neigh.handleConfirmation(addr, "c", ReachabilityConfirmationFlags{ Solicited: true, Override: false, IsRouter: false, }) }, } ep1, ep2 := fwdTestNetFactory(t, &proto) // Inject an inbound packet to address 3 on NIC 1, and see if it is // forwarded to NIC 2. buf := buffer.NewView(30) buf[dstAddrOffset] = 3 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) var p fwdTestPacketInfo select { case p = <-ep2.C: case <-time.After(time.Second): t.Fatal("packet not forwarded") } // Test that the address resolution happened correctly. if p.RemoteLinkAddress != "c" { t.Fatalf("got p.RemoteLinkAddress = %s, want = c", p.RemoteLinkAddress) } if p.LocalLinkAddress != "b" { t.Fatalf("got p.LocalLinkAddress = %s, want = b", p.LocalLinkAddress) } } func TestForwardingWithNoResolver(t *testing.T) { // Create a network protocol without a resolver. proto := &fwdTestNetworkProtocol{} // Whether or not we use the neighbor cache here does not matter since // neither linkAddrCache nor neighborCache will be used. ep1, ep2 := fwdTestNetFactory(t, proto) // inject an inbound packet to address 3 on NIC 1, and see if it is // forwarded to NIC 2. buf := buffer.NewView(30) buf[dstAddrOffset] = 3 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) select { case <-ep2.C: t.Fatal("Packet should not be forwarded") case <-time.After(time.Second): } } func TestForwardingResolutionFailsForQueuedPackets(t *testing.T) { proto := &fwdTestNetworkProtocol{ addrResolveDelay: 50 * time.Millisecond, onLinkAddressResolved: func(*neighborCache, tcpip.Address, tcpip.LinkAddress) { // Don't resolve the link address. }, } ep1, ep2 := fwdTestNetFactory(t, proto) const numPackets int = 5 // These packets will all be enqueued in the packet queue to wait for link // address resolution. for i := 0; i < numPackets; i++ { buf := buffer.NewView(30) buf[dstAddrOffset] = 3 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) } // All packets should fail resolution. // TODO(gvisor.dev/issue/5141): Use a fake clock. for i := 0; i < numPackets; i++ { select { case got := <-ep2.C: t.Fatalf("got %#v; packets should have failed resolution and not been forwarded", got) case <-time.After(100 * time.Millisecond): } } } func TestForwardingWithFakeResolverPartialTimeout(t *testing.T) { proto := fwdTestNetworkProtocol{ addrResolveDelay: 500 * time.Millisecond, onLinkAddressResolved: func(neigh *neighborCache, addr tcpip.Address, linkAddr tcpip.LinkAddress) { t.Helper() if len(linkAddr) != 0 { t.Fatalf("got linkAddr=%q, want unspecified", linkAddr) } // Only packets to address 3 will be resolved to the // link address "c". if addr == "\x03" { neigh.handleConfirmation(addr, "c", ReachabilityConfirmationFlags{ Solicited: true, Override: false, IsRouter: false, }) } }, } ep1, ep2 := fwdTestNetFactory(t, &proto) // Inject an inbound packet to address 4 on NIC 1. This packet should // not be forwarded. buf := buffer.NewView(30) buf[dstAddrOffset] = 4 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) // Inject an inbound packet to address 3 on NIC 1, and see if it is // forwarded to NIC 2. buf = buffer.NewView(30) buf[dstAddrOffset] = 3 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) var p fwdTestPacketInfo select { case p = <-ep2.C: case <-time.After(time.Second): t.Fatal("packet not forwarded") } if nh := PayloadSince(p.Pkt.NetworkHeader()); nh[dstAddrOffset] != 3 { t.Fatalf("got p.Pkt.NetworkHeader[dstAddrOffset] = %d, want = 3", nh[dstAddrOffset]) } // Test that the address resolution happened correctly. if p.RemoteLinkAddress != "c" { t.Fatalf("got p.RemoteLinkAddress = %s, want = c", p.RemoteLinkAddress) } if p.LocalLinkAddress != "b" { t.Fatalf("got p.LocalLinkAddress = %s, want = b", p.LocalLinkAddress) } } func TestForwardingWithFakeResolverTwoPackets(t *testing.T) { proto := fwdTestNetworkProtocol{ addrResolveDelay: 500 * time.Millisecond, onLinkAddressResolved: func(neigh *neighborCache, addr tcpip.Address, linkAddr tcpip.LinkAddress) { t.Helper() if len(linkAddr) != 0 { t.Fatalf("got linkAddr=%q, want unspecified", linkAddr) } // Any packets will be resolved to the link address "c". neigh.handleConfirmation(addr, "c", ReachabilityConfirmationFlags{ Solicited: true, Override: false, IsRouter: false, }) }, } ep1, ep2 := fwdTestNetFactory(t, &proto) // Inject two inbound packets to address 3 on NIC 1. for i := 0; i < 2; i++ { buf := buffer.NewView(30) buf[dstAddrOffset] = 3 ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) } for i := 0; i < 2; i++ { var p fwdTestPacketInfo select { case p = <-ep2.C: case <-time.After(time.Second): t.Fatal("packet not forwarded") } if nh := PayloadSince(p.Pkt.NetworkHeader()); nh[dstAddrOffset] != 3 { t.Fatalf("got p.Pkt.NetworkHeader[dstAddrOffset] = %d, want = 3", nh[dstAddrOffset]) } // Test that the address resolution happened correctly. if p.RemoteLinkAddress != "c" { t.Fatalf("got p.RemoteLinkAddress = %s, want = c", p.RemoteLinkAddress) } if p.LocalLinkAddress != "b" { t.Fatalf("got p.LocalLinkAddress = %s, want = b", p.LocalLinkAddress) } } } func TestForwardingWithFakeResolverManyPackets(t *testing.T) { proto := fwdTestNetworkProtocol{ addrResolveDelay: 500 * time.Millisecond, onLinkAddressResolved: func(neigh *neighborCache, addr tcpip.Address, linkAddr tcpip.LinkAddress) { t.Helper() if len(linkAddr) != 0 { t.Fatalf("got linkAddr=%q, want unspecified", linkAddr) } // Any packets will be resolved to the link address "c". neigh.handleConfirmation(addr, "c", ReachabilityConfirmationFlags{ Solicited: true, Override: false, IsRouter: false, }) }, } ep1, ep2 := fwdTestNetFactory(t, &proto) for i := 0; i < maxPendingPacketsPerResolution+5; i++ { // Inject inbound 'maxPendingPacketsPerResolution + 5' packets on NIC 1. buf := buffer.NewView(30) buf[dstAddrOffset] = 3 // Set the packet sequence number. binary.BigEndian.PutUint16(buf[fwdTestNetHeaderLen:], uint16(i)) ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) } for i := 0; i < maxPendingPacketsPerResolution; i++ { var p fwdTestPacketInfo select { case p = <-ep2.C: case <-time.After(time.Second): t.Fatal("packet not forwarded") } b := PayloadSince(p.Pkt.NetworkHeader()) if b[dstAddrOffset] != 3 { t.Fatalf("got b[dstAddrOffset] = %d, want = 3", b[dstAddrOffset]) } if len(b) < fwdTestNetHeaderLen+2 { t.Fatalf("packet is too short to hold a sequence number: len(b) = %d", b) } seqNumBuf := b[fwdTestNetHeaderLen:] // The first 5 packets should not be forwarded so the sequence number should // start with 5. want := uint16(i + 5) if n := binary.BigEndian.Uint16(seqNumBuf); n != want { t.Fatalf("got the packet #%d, want = #%d", n, want) } // Test that the address resolution happened correctly. if p.RemoteLinkAddress != "c" { t.Fatalf("got p.RemoteLinkAddress = %s, want = c", p.RemoteLinkAddress) } if p.LocalLinkAddress != "b" { t.Fatalf("got p.LocalLinkAddress = %s, want = b", p.LocalLinkAddress) } } } func TestForwardingWithFakeResolverManyResolutions(t *testing.T) { proto := fwdTestNetworkProtocol{ addrResolveDelay: 500 * time.Millisecond, onLinkAddressResolved: func(neigh *neighborCache, addr tcpip.Address, linkAddr tcpip.LinkAddress) { t.Helper() if len(linkAddr) != 0 { t.Fatalf("got linkAddr=%q, want unspecified", linkAddr) } // Any packets will be resolved to the link address "c". neigh.handleConfirmation(addr, "c", ReachabilityConfirmationFlags{ Solicited: true, Override: false, IsRouter: false, }) }, } ep1, ep2 := fwdTestNetFactory(t, &proto) for i := 0; i < maxPendingResolutions+5; i++ { // Inject inbound 'maxPendingResolutions + 5' packets on NIC 1. // Each packet has a different destination address (3 to // maxPendingResolutions + 7). buf := buffer.NewView(30) buf[dstAddrOffset] = byte(3 + i) ep1.InjectInbound(fwdTestNetNumber, NewPacketBuffer(PacketBufferOptions{ Data: buf.ToVectorisedView(), })) } for i := 0; i < maxPendingResolutions; i++ { var p fwdTestPacketInfo select { case p = <-ep2.C: case <-time.After(time.Second): t.Fatal("packet not forwarded") } // The first 5 packets (address 3 to 7) should not be forwarded // because their address resolutions are interrupted. if nh := PayloadSince(p.Pkt.NetworkHeader()); nh[dstAddrOffset] < 8 { t.Fatalf("got p.Pkt.NetworkHeader[dstAddrOffset] = %d, want p.Pkt.NetworkHeader[dstAddrOffset] >= 8", nh[dstAddrOffset]) } // Test that the address resolution happened correctly. if p.RemoteLinkAddress != "c" { t.Fatalf("got p.RemoteLinkAddress = %s, want = c", p.RemoteLinkAddress) } if p.LocalLinkAddress != "b" { t.Fatalf("got p.LocalLinkAddress = %s, want = b", p.LocalLinkAddress) } } }