// Copyright 2018 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 checker provides helper functions to check networking packets for // validity. package checker import ( "encoding/binary" "reflect" "testing" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/seqnum" ) // NetworkChecker is a function to check a property of a network packet. type NetworkChecker func(*testing.T, []header.Network) // TransportChecker is a function to check a property of a transport packet. type TransportChecker func(*testing.T, header.Transport) // ControlMessagesChecker is a function to check a property of ancillary data. type ControlMessagesChecker func(*testing.T, tcpip.ControlMessages) // IPv4 checks the validity and properties of the given IPv4 packet. It is // expected to be used in conjunction with other network checkers for specific // properties. For example, to check the source and destination address, one // would call: // // checker.IPv4(t, b, checker.SrcAddr(x), checker.DstAddr(y)) func IPv4(t *testing.T, b []byte, checkers ...NetworkChecker) { t.Helper() ipv4 := header.IPv4(b) if !ipv4.IsValid(len(b)) { t.Error("Not a valid IPv4 packet") } xsum := ipv4.CalculateChecksum() if xsum != 0 && xsum != 0xffff { t.Errorf("Bad checksum: 0x%x, checksum in packet: 0x%x", xsum, ipv4.Checksum()) } for _, f := range checkers { f(t, []header.Network{ipv4}) } if t.Failed() { t.FailNow() } } // IPv6 checks the validity and properties of the given IPv6 packet. The usage // is similar to IPv4. func IPv6(t *testing.T, b []byte, checkers ...NetworkChecker) { t.Helper() ipv6 := header.IPv6(b) if !ipv6.IsValid(len(b)) { t.Error("Not a valid IPv6 packet") } for _, f := range checkers { f(t, []header.Network{ipv6}) } if t.Failed() { t.FailNow() } } // SrcAddr creates a checker that checks the source address. func SrcAddr(addr tcpip.Address) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() if a := h[0].SourceAddress(); a != addr { t.Errorf("Bad source address, got %v, want %v", a, addr) } } } // DstAddr creates a checker that checks the destination address. func DstAddr(addr tcpip.Address) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() if a := h[0].DestinationAddress(); a != addr { t.Errorf("Bad destination address, got %v, want %v", a, addr) } } } // TTL creates a checker that checks the TTL (ipv4) or HopLimit (ipv6). func TTL(ttl uint8) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() var v uint8 switch ip := h[0].(type) { case header.IPv4: v = ip.TTL() case header.IPv6: v = ip.HopLimit() } if v != ttl { t.Fatalf("Bad TTL, got %v, want %v", v, ttl) } } } // PayloadLen creates a checker that checks the payload length. func PayloadLen(plen int) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() if l := len(h[0].Payload()); l != plen { t.Errorf("Bad payload length, got %v, want %v", l, plen) } } } // FragmentOffset creates a checker that checks the FragmentOffset field. func FragmentOffset(offset uint16) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() // We only do this of IPv4 for now. switch ip := h[0].(type) { case header.IPv4: if v := ip.FragmentOffset(); v != offset { t.Errorf("Bad fragment offset, got %v, want %v", v, offset) } } } } // FragmentFlags creates a checker that checks the fragment flags field. func FragmentFlags(flags uint8) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() // We only do this of IPv4 for now. switch ip := h[0].(type) { case header.IPv4: if v := ip.Flags(); v != flags { t.Errorf("Bad fragment offset, got %v, want %v", v, flags) } } } } // ReceiveTClass creates a checker that checks the TCLASS field in // ControlMessages. func ReceiveTClass(want uint32) ControlMessagesChecker { return func(t *testing.T, cm tcpip.ControlMessages) { t.Helper() if !cm.HasTClass { t.Fatalf("got cm.HasTClass = %t, want cm.TClass = %d", cm.HasTClass, want) } if got := cm.TClass; got != want { t.Fatalf("got cm.TClass = %d, want %d", got, want) } } } // ReceiveTOS creates a checker that checks the TOS field in ControlMessages. func ReceiveTOS(want uint8) ControlMessagesChecker { return func(t *testing.T, cm tcpip.ControlMessages) { t.Helper() if !cm.HasTOS { t.Fatalf("got cm.HasTOS = %t, want cm.TOS = %d", cm.HasTOS, want) } if got := cm.TOS; got != want { t.Fatalf("got cm.TOS = %d, want %d", got, want) } } } // TOS creates a checker that checks the TOS field. func TOS(tos uint8, label uint32) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() if v, l := h[0].TOS(); v != tos || l != label { t.Errorf("Bad TOS, got (%v, %v), want (%v,%v)", v, l, tos, label) } } } // Raw creates a checker that checks the bytes of payload. // The checker always checks the payload of the last network header. // For instance, in case of IPv6 fragments, the payload that will be checked // is the one containing the actual data that the packet is carrying, without // the bytes added by the IPv6 fragmentation. func Raw(want []byte) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() if got := h[len(h)-1].Payload(); !reflect.DeepEqual(got, want) { t.Errorf("Wrong payload, got %v, want %v", got, want) } } } // IPv6Fragment creates a checker that validates an IPv6 fragment. func IPv6Fragment(checkers ...NetworkChecker) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() if p := h[0].TransportProtocol(); p != header.IPv6FragmentHeader { t.Errorf("Bad protocol, got %v, want %v", p, header.UDPProtocolNumber) } ipv6Frag := header.IPv6Fragment(h[0].Payload()) if !ipv6Frag.IsValid() { t.Error("Not a valid IPv6 fragment") } for _, f := range checkers { f(t, []header.Network{h[0], ipv6Frag}) } if t.Failed() { t.FailNow() } } } // TCP creates a checker that checks that the transport protocol is TCP and // potentially additional transport header fields. func TCP(checkers ...TransportChecker) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() first := h[0] last := h[len(h)-1] if p := last.TransportProtocol(); p != header.TCPProtocolNumber { t.Errorf("Bad protocol, got %v, want %v", p, header.TCPProtocolNumber) } // Verify the checksum. tcp := header.TCP(last.Payload()) l := uint16(len(tcp)) xsum := header.Checksum([]byte(first.SourceAddress()), 0) xsum = header.Checksum([]byte(first.DestinationAddress()), xsum) xsum = header.Checksum([]byte{0, byte(last.TransportProtocol())}, xsum) xsum = header.Checksum([]byte{byte(l >> 8), byte(l)}, xsum) xsum = header.Checksum(tcp, xsum) if xsum != 0 && xsum != 0xffff { t.Errorf("Bad checksum: 0x%x, checksum in segment: 0x%x", xsum, tcp.Checksum()) } // Run the transport checkers. for _, f := range checkers { f(t, tcp) } if t.Failed() { t.FailNow() } } } // UDP creates a checker that checks that the transport protocol is UDP and // potentially additional transport header fields. func UDP(checkers ...TransportChecker) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() last := h[len(h)-1] if p := last.TransportProtocol(); p != header.UDPProtocolNumber { t.Errorf("Bad protocol, got %v, want %v", p, header.UDPProtocolNumber) } udp := header.UDP(last.Payload()) for _, f := range checkers { f(t, udp) } if t.Failed() { t.FailNow() } } } // SrcPort creates a checker that checks the source port. func SrcPort(port uint16) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() if p := h.SourcePort(); p != port { t.Errorf("Bad source port, got %v, want %v", p, port) } } } // DstPort creates a checker that checks the destination port. func DstPort(port uint16) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() if p := h.DestinationPort(); p != port { t.Errorf("Bad destination port, got %v, want %v", p, port) } } } // SeqNum creates a checker that checks the sequence number. func SeqNum(seq uint32) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } if s := tcp.SequenceNumber(); s != seq { t.Errorf("Bad sequence number, got %v, want %v", s, seq) } } } // AckNum creates a checker that checks the ack number. func AckNum(seq uint32) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } if s := tcp.AckNumber(); s != seq { t.Errorf("Bad ack number, got %v, want %v", s, seq) } } } // Window creates a checker that checks the tcp window. func Window(window uint16) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } if w := tcp.WindowSize(); w != window { t.Errorf("Bad window, got 0x%x, want 0x%x", w, window) } } } // TCPFlags creates a checker that checks the tcp flags. func TCPFlags(flags uint8) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } if f := tcp.Flags(); f != flags { t.Errorf("Bad flags, got 0x%x, want 0x%x", f, flags) } } } // TCPFlagsMatch creates a checker that checks that the tcp flags, masked by the // given mask, match the supplied flags. func TCPFlagsMatch(flags, mask uint8) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } if f := tcp.Flags(); (f & mask) != (flags & mask) { t.Errorf("Bad masked flags, got 0x%x, want 0x%x, mask 0x%x", f, flags, mask) } } } // TCPSynOptions creates a checker that checks the presence of TCP options in // SYN segments. // // If wndscale is negative, the window scale option must not be present. func TCPSynOptions(wantOpts header.TCPSynOptions) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } opts := tcp.Options() limit := len(opts) foundMSS := false foundWS := false foundTS := false foundSACKPermitted := false tsVal := uint32(0) tsEcr := uint32(0) for i := 0; i < limit; { switch opts[i] { case header.TCPOptionEOL: i = limit case header.TCPOptionNOP: i++ case header.TCPOptionMSS: v := uint16(opts[i+2])<<8 | uint16(opts[i+3]) if wantOpts.MSS != v { t.Errorf("Bad MSS: got %v, want %v", v, wantOpts.MSS) } foundMSS = true i += 4 case header.TCPOptionWS: if wantOpts.WS < 0 { t.Error("WS present when it shouldn't be") } v := int(opts[i+2]) if v != wantOpts.WS { t.Errorf("Bad WS: got %v, want %v", v, wantOpts.WS) } foundWS = true i += 3 case header.TCPOptionTS: if i+9 >= limit { t.Errorf("TS Option truncated , option is only: %d bytes, want 10", limit-i) } if opts[i+1] != 10 { t.Errorf("Bad length %d for TS option, limit: %d", opts[i+1], limit) } tsVal = binary.BigEndian.Uint32(opts[i+2:]) tsEcr = uint32(0) if tcp.Flags()&header.TCPFlagAck != 0 { // If the syn is an SYN-ACK then read // the tsEcr value as well. tsEcr = binary.BigEndian.Uint32(opts[i+6:]) } foundTS = true i += 10 case header.TCPOptionSACKPermitted: if i+1 >= limit { t.Errorf("SACKPermitted option truncated, option is only : %d bytes, want 2", limit-i) } if opts[i+1] != 2 { t.Errorf("Bad length %d for SACKPermitted option, limit: %d", opts[i+1], limit) } foundSACKPermitted = true i += 2 default: i += int(opts[i+1]) } } if !foundMSS { t.Errorf("MSS option not found. Options: %x", opts) } if !foundWS && wantOpts.WS >= 0 { t.Errorf("WS option not found. Options: %x", opts) } if wantOpts.TS && !foundTS { t.Errorf("TS option not found. Options: %x", opts) } if foundTS && tsVal == 0 { t.Error("TS option specified but the timestamp value is zero") } if foundTS && tsEcr == 0 && wantOpts.TSEcr != 0 { t.Errorf("TS option specified but TSEcr is incorrect: got %d, want: %d", tsEcr, wantOpts.TSEcr) } if wantOpts.SACKPermitted && !foundSACKPermitted { t.Errorf("SACKPermitted option not found. Options: %x", opts) } } } // TCPTimestampChecker creates a checker that validates that a TCP segment has a // TCP Timestamp option if wantTS is true, it also compares the wantTSVal and // wantTSEcr values with those in the TCP segment (if present). // // If wantTSVal or wantTSEcr is zero then the corresponding comparison is // skipped. func TCPTimestampChecker(wantTS bool, wantTSVal uint32, wantTSEcr uint32) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } opts := []byte(tcp.Options()) limit := len(opts) foundTS := false tsVal := uint32(0) tsEcr := uint32(0) for i := 0; i < limit; { switch opts[i] { case header.TCPOptionEOL: i = limit case header.TCPOptionNOP: i++ case header.TCPOptionTS: if i+9 >= limit { t.Errorf("TS option found, but option is truncated, option length: %d, want 10 bytes", limit-i) } if opts[i+1] != 10 { t.Errorf("TS option found, but bad length specified: %d, want: 10", opts[i+1]) } tsVal = binary.BigEndian.Uint32(opts[i+2:]) tsEcr = binary.BigEndian.Uint32(opts[i+6:]) foundTS = true i += 10 default: // We don't recognize this option, just skip over it. if i+2 > limit { return } l := int(opts[i+1]) if i < 2 || i+l > limit { return } i += l } } if wantTS != foundTS { t.Errorf("TS Option mismatch: got TS= %v, want TS= %v", foundTS, wantTS) } if wantTS && wantTSVal != 0 && wantTSVal != tsVal { t.Errorf("Timestamp value is incorrect: got: %d, want: %d", tsVal, wantTSVal) } if wantTS && wantTSEcr != 0 && tsEcr != wantTSEcr { t.Errorf("Timestamp Echo Reply is incorrect: got: %d, want: %d", tsEcr, wantTSEcr) } } } // TCPNoSACKBlockChecker creates a checker that verifies that the segment does not // contain any SACK blocks in the TCP options. func TCPNoSACKBlockChecker() TransportChecker { return TCPSACKBlockChecker(nil) } // TCPSACKBlockChecker creates a checker that verifies that the segment does // contain the specified SACK blocks in the TCP options. func TCPSACKBlockChecker(sackBlocks []header.SACKBlock) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() tcp, ok := h.(header.TCP) if !ok { return } var gotSACKBlocks []header.SACKBlock opts := []byte(tcp.Options()) limit := len(opts) for i := 0; i < limit; { switch opts[i] { case header.TCPOptionEOL: i = limit case header.TCPOptionNOP: i++ case header.TCPOptionSACK: if i+2 > limit { // Malformed SACK block. t.Errorf("malformed SACK option in options: %v", opts) } sackOptionLen := int(opts[i+1]) if i+sackOptionLen > limit || (sackOptionLen-2)%8 != 0 { // Malformed SACK block. t.Errorf("malformed SACK option length in options: %v", opts) } numBlocks := sackOptionLen / 8 for j := 0; j < numBlocks; j++ { start := binary.BigEndian.Uint32(opts[i+2+j*8:]) end := binary.BigEndian.Uint32(opts[i+2+j*8+4:]) gotSACKBlocks = append(gotSACKBlocks, header.SACKBlock{ Start: seqnum.Value(start), End: seqnum.Value(end), }) } i += sackOptionLen default: // We don't recognize this option, just skip over it. if i+2 > limit { break } l := int(opts[i+1]) if l < 2 || i+l > limit { break } i += l } } if !reflect.DeepEqual(gotSACKBlocks, sackBlocks) { t.Errorf("SACKBlocks are not equal, got: %v, want: %v", gotSACKBlocks, sackBlocks) } } } // Payload creates a checker that checks the payload. func Payload(want []byte) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() if got := h.Payload(); !reflect.DeepEqual(got, want) { t.Errorf("Wrong payload, got %v, want %v", got, want) } } } // ICMPv4 creates a checker that checks that the transport protocol is ICMPv4 and // potentially additional ICMPv4 header fields. func ICMPv4(checkers ...TransportChecker) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() last := h[len(h)-1] if p := last.TransportProtocol(); p != header.ICMPv4ProtocolNumber { t.Fatalf("Bad protocol, got %d, want %d", p, header.ICMPv4ProtocolNumber) } icmp := header.ICMPv4(last.Payload()) for _, f := range checkers { f(t, icmp) } if t.Failed() { t.FailNow() } } } // ICMPv4Type creates a checker that checks the ICMPv4 Type field. func ICMPv4Type(want header.ICMPv4Type) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmpv4, ok := h.(header.ICMPv4) if !ok { t.Fatalf("unexpected transport header passed to checker got: %+v, want: header.ICMPv4", h) } if got := icmpv4.Type(); got != want { t.Fatalf("unexpected icmp type got: %d, want: %d", got, want) } } } // ICMPv4Code creates a checker that checks the ICMPv4 Code field. func ICMPv4Code(want byte) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmpv4, ok := h.(header.ICMPv4) if !ok { t.Fatalf("unexpected transport header passed to checker got: %+v, want: header.ICMPv4", h) } if got := icmpv4.Code(); got != want { t.Fatalf("unexpected ICMP code got: %d, want: %d", got, want) } } } // ICMPv6 creates a checker that checks that the transport protocol is ICMPv6 and // potentially additional ICMPv6 header fields. // // ICMPv6 will validate the checksum field before calling checkers. func ICMPv6(checkers ...TransportChecker) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() last := h[len(h)-1] if p := last.TransportProtocol(); p != header.ICMPv6ProtocolNumber { t.Fatalf("Bad protocol, got %d, want %d", p, header.ICMPv6ProtocolNumber) } icmp := header.ICMPv6(last.Payload()) if got, want := icmp.Checksum(), header.ICMPv6Checksum(icmp, last.SourceAddress(), last.DestinationAddress(), buffer.VectorisedView{}); got != want { t.Fatalf("Bad ICMPv6 checksum; got %d, want %d", got, want) } for _, f := range checkers { f(t, icmp) } if t.Failed() { t.FailNow() } } } // ICMPv6Type creates a checker that checks the ICMPv6 Type field. func ICMPv6Type(want header.ICMPv6Type) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmpv6, ok := h.(header.ICMPv6) if !ok { t.Fatalf("unexpected transport header passed to checker got: %+v, want: header.ICMPv6", h) } if got := icmpv6.Type(); got != want { t.Fatalf("unexpected icmp type got: %d, want: %d", got, want) } } } // ICMPv6Code creates a checker that checks the ICMPv6 Code field. func ICMPv6Code(want byte) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmpv6, ok := h.(header.ICMPv6) if !ok { t.Fatalf("unexpected transport header passed to checker got: %+v, want: header.ICMPv6", h) } if got := icmpv6.Code(); got != want { t.Fatalf("unexpected ICMP code got: %d, want: %d", got, want) } } } // NDP creates a checker that checks that the packet contains a valid NDP // message for type of ty, with potentially additional checks specified by // checkers. // // Checkers may assume that a valid ICMPv6 is passed to it containing a valid // NDP message as far as the size of the message (minSize) is concerned. The // values within the message are up to checkers to validate. func NDP(msgType header.ICMPv6Type, minSize int, checkers ...TransportChecker) NetworkChecker { return func(t *testing.T, h []header.Network) { t.Helper() // Check normal ICMPv6 first. ICMPv6( ICMPv6Type(msgType), ICMPv6Code(0))(t, h) last := h[len(h)-1] icmp := header.ICMPv6(last.Payload()) if got := len(icmp.NDPPayload()); got < minSize { t.Fatalf("ICMPv6 NDP (type = %d) payload size of %d is less than the minimum size of %d", msgType, got, minSize) } for _, f := range checkers { f(t, icmp) } if t.Failed() { t.FailNow() } } } // NDPNS creates a checker that checks that the packet contains a valid NDP // Neighbor Solicitation message (as per the raw wire format), with potentially // additional checks specified by checkers. // // Checkers may assume that a valid ICMPv6 is passed to it containing a valid // NDPNS message as far as the size of the message is concerned. The values // within the message are up to checkers to validate. func NDPNS(checkers ...TransportChecker) NetworkChecker { return NDP(header.ICMPv6NeighborSolicit, header.NDPNSMinimumSize, checkers...) } // NDPNSTargetAddress creates a checker that checks the Target Address field of // a header.NDPNeighborSolicit. // // The returned TransportChecker assumes that a valid ICMPv6 is passed to it // containing a valid NDPNS message as far as the size is concerned. func NDPNSTargetAddress(want tcpip.Address) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmp := h.(header.ICMPv6) ns := header.NDPNeighborSolicit(icmp.NDPPayload()) if got := ns.TargetAddress(); got != want { t.Errorf("got %T.TargetAddress() = %s, want = %s", ns, got, want) } } } // NDPNA creates a checker that checks that the packet contains a valid NDP // Neighbor Advertisement message (as per the raw wire format), with potentially // additional checks specified by checkers. // // Checkers may assume that a valid ICMPv6 is passed to it containing a valid // NDPNA message as far as the size of the message is concerned. The values // within the message are up to checkers to validate. func NDPNA(checkers ...TransportChecker) NetworkChecker { return NDP(header.ICMPv6NeighborAdvert, header.NDPNAMinimumSize, checkers...) } // NDPNATargetAddress creates a checker that checks the Target Address field of // a header.NDPNeighborAdvert. // // The returned TransportChecker assumes that a valid ICMPv6 is passed to it // containing a valid NDPNA message as far as the size is concerned. func NDPNATargetAddress(want tcpip.Address) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmp := h.(header.ICMPv6) na := header.NDPNeighborAdvert(icmp.NDPPayload()) if got := na.TargetAddress(); got != want { t.Errorf("got %T.TargetAddress() = %s, want = %s", na, got, want) } } } // NDPNASolicitedFlag creates a checker that checks the Solicited field of // a header.NDPNeighborAdvert. // // The returned TransportChecker assumes that a valid ICMPv6 is passed to it // containing a valid NDPNA message as far as the size is concerned. func NDPNASolicitedFlag(want bool) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmp := h.(header.ICMPv6) na := header.NDPNeighborAdvert(icmp.NDPPayload()) if got := na.SolicitedFlag(); got != want { t.Errorf("got %T.SolicitedFlag = %t, want = %t", na, got, want) } } } // ndpOptions checks that optsBuf only contains opts. func ndpOptions(t *testing.T, optsBuf header.NDPOptions, opts []header.NDPOption) { t.Helper() it, err := optsBuf.Iter(true) if err != nil { t.Errorf("optsBuf.Iter(true): %s", err) return } i := 0 for { opt, done, err := it.Next() if err != nil { // This should never happen as Iter(true) above did not return an error. t.Fatalf("unexpected error when iterating over NDP options: %s", err) } if done { break } if i >= len(opts) { t.Errorf("got unexpected option: %s", opt) continue } switch wantOpt := opts[i].(type) { case header.NDPSourceLinkLayerAddressOption: gotOpt, ok := opt.(header.NDPSourceLinkLayerAddressOption) if !ok { t.Errorf("got type = %T at index = %d; want = %T", opt, i, wantOpt) } else if got, want := gotOpt.EthernetAddress(), wantOpt.EthernetAddress(); got != want { t.Errorf("got EthernetAddress() = %s at index %d, want = %s", got, i, want) } case header.NDPTargetLinkLayerAddressOption: gotOpt, ok := opt.(header.NDPTargetLinkLayerAddressOption) if !ok { t.Errorf("got type = %T at index = %d; want = %T", opt, i, wantOpt) } else if got, want := gotOpt.EthernetAddress(), wantOpt.EthernetAddress(); got != want { t.Errorf("got EthernetAddress() = %s at index %d, want = %s", got, i, want) } default: t.Fatalf("checker not implemented for expected NDP option: %T", wantOpt) } i++ } if missing := opts[i:]; len(missing) > 0 { t.Errorf("missing options: %s", missing) } } // NDPNAOptions creates a checker that checks that the packet contains the // provided NDP options within an NDP Neighbor Solicitation message. // // The returned TransportChecker assumes that a valid ICMPv6 is passed to it // containing a valid NDPNA message as far as the size is concerned. func NDPNAOptions(opts []header.NDPOption) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmp := h.(header.ICMPv6) na := header.NDPNeighborAdvert(icmp.NDPPayload()) ndpOptions(t, na.Options(), opts) } } // NDPNSOptions creates a checker that checks that the packet contains the // provided NDP options within an NDP Neighbor Solicitation message. // // The returned TransportChecker assumes that a valid ICMPv6 is passed to it // containing a valid NDPNS message as far as the size is concerned. func NDPNSOptions(opts []header.NDPOption) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmp := h.(header.ICMPv6) ns := header.NDPNeighborSolicit(icmp.NDPPayload()) ndpOptions(t, ns.Options(), opts) } } // NDPRS creates a checker that checks that the packet contains a valid NDP // Router Solicitation message (as per the raw wire format). // // Checkers may assume that a valid ICMPv6 is passed to it containing a valid // NDPRS as far as the size of the message is concerned. The values within the // message are up to checkers to validate. func NDPRS(checkers ...TransportChecker) NetworkChecker { return NDP(header.ICMPv6RouterSolicit, header.NDPRSMinimumSize, checkers...) } // NDPRSOptions creates a checker that checks that the packet contains the // provided NDP options within an NDP Router Solicitation message. // // The returned TransportChecker assumes that a valid ICMPv6 is passed to it // containing a valid NDPRS message as far as the size is concerned. func NDPRSOptions(opts []header.NDPOption) TransportChecker { return func(t *testing.T, h header.Transport) { t.Helper() icmp := h.(header.ICMPv6) rs := header.NDPRouterSolicit(icmp.NDPPayload()) ndpOptions(t, rs.Options(), opts) } }