// 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 context provides a test context for use in tcp tests. It also // provides helper methods to assert/check certain behaviours. package context import ( "bytes" "testing" "time" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/checker" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/link/channel" "gvisor.dev/gvisor/pkg/tcpip/link/sniffer" "gvisor.dev/gvisor/pkg/tcpip/network/ipv4" "gvisor.dev/gvisor/pkg/tcpip/network/ipv6" "gvisor.dev/gvisor/pkg/tcpip/seqnum" "gvisor.dev/gvisor/pkg/tcpip/stack" "gvisor.dev/gvisor/pkg/tcpip/transport/tcp" "gvisor.dev/gvisor/pkg/waiter" ) const ( // StackAddr is the IPv4 address assigned to the stack. StackAddr = "\x0a\x00\x00\x01" // StackPort is used as the listening port in tests for passive // connects. StackPort = 1234 // TestAddr is the source address for packets sent to the stack via the // link layer endpoint. TestAddr = "\x0a\x00\x00\x02" // TestPort is the TCP port used for packets sent to the stack // via the link layer endpoint. TestPort = 4096 // StackV6Addr is the IPv6 address assigned to the stack. StackV6Addr = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x01" // TestV6Addr is the source address for packets sent to the stack via // the link layer endpoint. TestV6Addr = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x02" // StackV4MappedAddr is StackAddr as a mapped v6 address. StackV4MappedAddr = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff" + StackAddr // TestV4MappedAddr is TestAddr as a mapped v6 address. TestV4MappedAddr = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff" + TestAddr // V4MappedWildcardAddr is the mapped v6 representation of 0.0.0.0. V4MappedWildcardAddr = "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff\x00\x00\x00\x00" // testInitialSequenceNumber is the initial sequence number sent in packets that // are sent in response to a SYN or in the initial SYN sent to the stack. testInitialSequenceNumber = 789 ) // Headers is used to represent the TCP header fields when building a // new packet. type Headers struct { // SrcPort holds the src port value to be used in the packet. SrcPort uint16 // DstPort holds the destination port value to be used in the packet. DstPort uint16 // SeqNum is the value of the sequence number field in the TCP header. SeqNum seqnum.Value // AckNum represents the acknowledgement number field in the TCP header. AckNum seqnum.Value // Flags are the TCP flags in the TCP header. Flags int // RcvWnd is the window to be advertised in the ReceiveWindow field of // the TCP header. RcvWnd seqnum.Size // TCPOpts holds the options to be sent in the option field of the TCP // header. TCPOpts []byte } // Context provides an initialized Network stack and a link layer endpoint // for use in TCP tests. type Context struct { t *testing.T linkEP *channel.Endpoint s *stack.Stack // IRS holds the initial sequence number in the SYN sent by endpoint in // case of an active connect or the sequence number sent by the endpoint // in the SYN-ACK sent in response to a SYN when listening in passive // mode. IRS seqnum.Value // Port holds the port bound by EP below in case of an active connect or // the listening port number in case of a passive connect. Port uint16 // EP is the test endpoint in the stack owned by this context. This endpoint // is used in various tests to either initiate an active connect or is used // as a passive listening endpoint to accept inbound connections. EP tcpip.Endpoint // Wq is the wait queue associated with EP and is used to block for events // on EP. WQ waiter.Queue // TimeStampEnabled is true if ep is connected with the timestamp option // enabled. TimeStampEnabled bool // WindowScale is the expected window scale in SYN packets sent by // the stack. WindowScale uint8 } // New allocates and initializes a test context containing a new // stack and a link-layer endpoint. func New(t *testing.T, mtu uint32) *Context { s := stack.New([]string{ipv4.ProtocolName, ipv6.ProtocolName}, []string{tcp.ProtocolName}, stack.Options{}) // Allow minimum send/receive buffer sizes to be 1 during tests. if err := s.SetTransportProtocolOption(tcp.ProtocolNumber, tcp.SendBufferSizeOption{1, tcp.DefaultSendBufferSize, 10 * tcp.DefaultSendBufferSize}); err != nil { t.Fatalf("SetTransportProtocolOption failed: %v", err) } if err := s.SetTransportProtocolOption(tcp.ProtocolNumber, tcp.ReceiveBufferSizeOption{1, tcp.DefaultReceiveBufferSize, 10 * tcp.DefaultReceiveBufferSize}); err != nil { t.Fatalf("SetTransportProtocolOption failed: %v", err) } // Some of the congestion control tests send up to 640 packets, we so // set the channel size to 1000. id, linkEP := channel.New(1000, mtu, "") if testing.Verbose() { id = sniffer.New(id) } if err := s.CreateNIC(1, id); err != nil { t.Fatalf("CreateNIC failed: %v", err) } if err := s.AddAddress(1, ipv4.ProtocolNumber, StackAddr); err != nil { t.Fatalf("AddAddress failed: %v", err) } if err := s.AddAddress(1, ipv6.ProtocolNumber, StackV6Addr); err != nil { t.Fatalf("AddAddress failed: %v", err) } s.SetRouteTable([]tcpip.Route{ { Destination: "\x00\x00\x00\x00", Mask: "\x00\x00\x00\x00", Gateway: "", NIC: 1, }, { Destination: "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00", Mask: "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00", Gateway: "", NIC: 1, }, }) return &Context{ t: t, s: s, linkEP: linkEP, WindowScale: uint8(tcp.FindWndScale(tcp.DefaultReceiveBufferSize)), } } // Cleanup closes the context endpoint if required. func (c *Context) Cleanup() { if c.EP != nil { c.EP.Close() } } // Stack returns a reference to the stack in the Context. func (c *Context) Stack() *stack.Stack { return c.s } // CheckNoPacketTimeout verifies that no packet is received during the time // specified by wait. func (c *Context) CheckNoPacketTimeout(errMsg string, wait time.Duration) { c.t.Helper() select { case <-c.linkEP.C: c.t.Fatal(errMsg) case <-time.After(wait): } } // CheckNoPacket verifies that no packet is received for 1 second. func (c *Context) CheckNoPacket(errMsg string) { c.CheckNoPacketTimeout(errMsg, 1*time.Second) } // GetPacket reads a packet from the link layer endpoint and verifies // that it is an IPv4 packet with the expected source and destination // addresses. It will fail with an error if no packet is received for // 2 seconds. func (c *Context) GetPacket() []byte { select { case p := <-c.linkEP.C: if p.Proto != ipv4.ProtocolNumber { c.t.Fatalf("Bad network protocol: got %v, wanted %v", p.Proto, ipv4.ProtocolNumber) } b := make([]byte, len(p.Header)+len(p.Payload)) copy(b, p.Header) copy(b[len(p.Header):], p.Payload) if p.GSO != nil && p.GSO.L3HdrLen != header.IPv4MinimumSize { c.t.Errorf("L3HdrLen %v (expected %v)", p.GSO.L3HdrLen, header.IPv4MinimumSize) } checker.IPv4(c.t, b, checker.SrcAddr(StackAddr), checker.DstAddr(TestAddr)) return b case <-time.After(2 * time.Second): c.t.Fatalf("Packet wasn't written out") } return nil } // GetPacketNonBlocking reads a packet from the link layer endpoint // and verifies that it is an IPv4 packet with the expected source // and destination address. If no packet is available it will return // nil immediately. func (c *Context) GetPacketNonBlocking() []byte { select { case p := <-c.linkEP.C: if p.Proto != ipv4.ProtocolNumber { c.t.Fatalf("Bad network protocol: got %v, wanted %v", p.Proto, ipv4.ProtocolNumber) } b := make([]byte, len(p.Header)+len(p.Payload)) copy(b, p.Header) copy(b[len(p.Header):], p.Payload) checker.IPv4(c.t, b, checker.SrcAddr(StackAddr), checker.DstAddr(TestAddr)) return b default: return nil } } // SendICMPPacket builds and sends an ICMPv4 packet via the link layer endpoint. func (c *Context) SendICMPPacket(typ header.ICMPv4Type, code uint8, p1, p2 []byte, maxTotalSize int) { // Allocate a buffer data and headers. buf := buffer.NewView(header.IPv4MinimumSize + header.ICMPv4PayloadOffset + len(p1) + len(p2)) if len(buf) > maxTotalSize { buf = buf[:maxTotalSize] } ip := header.IPv4(buf) ip.Encode(&header.IPv4Fields{ IHL: header.IPv4MinimumSize, TotalLength: uint16(len(buf)), TTL: 65, Protocol: uint8(header.ICMPv4ProtocolNumber), SrcAddr: TestAddr, DstAddr: StackAddr, }) ip.SetChecksum(^ip.CalculateChecksum()) icmp := header.ICMPv4(buf[header.IPv4MinimumSize:]) icmp.SetType(typ) icmp.SetCode(code) copy(icmp[header.ICMPv4PayloadOffset:], p1) copy(icmp[header.ICMPv4PayloadOffset+len(p1):], p2) // Inject packet. c.linkEP.Inject(ipv4.ProtocolNumber, buf.ToVectorisedView()) } // BuildSegment builds a TCP segment based on the given Headers and payload. func (c *Context) BuildSegment(payload []byte, h *Headers) buffer.VectorisedView { // Allocate a buffer for data and headers. buf := buffer.NewView(header.TCPMinimumSize + header.IPv4MinimumSize + len(h.TCPOpts) + len(payload)) copy(buf[len(buf)-len(payload):], payload) copy(buf[len(buf)-len(payload)-len(h.TCPOpts):], h.TCPOpts) // Initialize the IP header. ip := header.IPv4(buf) ip.Encode(&header.IPv4Fields{ IHL: header.IPv4MinimumSize, TotalLength: uint16(len(buf)), TTL: 65, Protocol: uint8(tcp.ProtocolNumber), SrcAddr: TestAddr, DstAddr: StackAddr, }) ip.SetChecksum(^ip.CalculateChecksum()) // Initialize the TCP header. t := header.TCP(buf[header.IPv4MinimumSize:]) t.Encode(&header.TCPFields{ SrcPort: h.SrcPort, DstPort: h.DstPort, SeqNum: uint32(h.SeqNum), AckNum: uint32(h.AckNum), DataOffset: uint8(header.TCPMinimumSize + len(h.TCPOpts)), Flags: uint8(h.Flags), WindowSize: uint16(h.RcvWnd), }) // Calculate the TCP pseudo-header checksum. xsum := header.PseudoHeaderChecksum(tcp.ProtocolNumber, TestAddr, StackAddr, uint16(len(t))) // Calculate the TCP checksum and set it. xsum = header.Checksum(payload, xsum) t.SetChecksum(^t.CalculateChecksum(xsum)) // Inject packet. return buf.ToVectorisedView() } // SendSegment sends a TCP segment that has already been built and written to a // buffer.VectorisedView. func (c *Context) SendSegment(s buffer.VectorisedView) { c.linkEP.Inject(ipv4.ProtocolNumber, s) } // SendPacket builds and sends a TCP segment(with the provided payload & TCP // headers) in an IPv4 packet via the link layer endpoint. func (c *Context) SendPacket(payload []byte, h *Headers) { c.linkEP.Inject(ipv4.ProtocolNumber, c.BuildSegment(payload, h)) } // SendAck sends an ACK packet. func (c *Context) SendAck(seq seqnum.Value, bytesReceived int) { c.SendAckWithSACK(seq, bytesReceived, nil) } // SendAckWithSACK sends an ACK packet which includes the sackBlocks specified. func (c *Context) SendAckWithSACK(seq seqnum.Value, bytesReceived int, sackBlocks []header.SACKBlock) { options := make([]byte, 40) offset := 0 if len(sackBlocks) > 0 { offset += header.EncodeNOP(options[offset:]) offset += header.EncodeNOP(options[offset:]) offset += header.EncodeSACKBlocks(sackBlocks, options[offset:]) } c.SendPacket(nil, &Headers{ SrcPort: TestPort, DstPort: c.Port, Flags: header.TCPFlagAck, SeqNum: seq, AckNum: c.IRS.Add(1 + seqnum.Size(bytesReceived)), RcvWnd: 30000, TCPOpts: options[:offset], }) } // ReceiveAndCheckPacket reads a packet from the link layer endpoint and // verifies that the packet packet payload of packet matches the slice // of data indicated by offset & size. func (c *Context) ReceiveAndCheckPacket(data []byte, offset, size int) { c.ReceiveAndCheckPacketWithOptions(data, offset, size, 0) } // ReceiveAndCheckPacketWithOptions reads a packet from the link layer endpoint // and verifies that the packet packet payload of packet matches the slice of // data indicated by offset & size and skips optlen bytes in addition to the IP // TCP headers when comparing the data. func (c *Context) ReceiveAndCheckPacketWithOptions(data []byte, offset, size, optlen int) { b := c.GetPacket() checker.IPv4(c.t, b, checker.PayloadLen(size+header.TCPMinimumSize+optlen), checker.TCP( checker.DstPort(TestPort), checker.SeqNum(uint32(c.IRS.Add(seqnum.Size(1+offset)))), checker.AckNum(uint32(seqnum.Value(testInitialSequenceNumber).Add(1))), checker.TCPFlagsMatch(header.TCPFlagAck, ^uint8(header.TCPFlagPsh)), ), ) pdata := data[offset:][:size] if p := b[header.IPv4MinimumSize+header.TCPMinimumSize+optlen:]; bytes.Compare(pdata, p) != 0 { c.t.Fatalf("Data is different: expected %v, got %v", pdata, p) } } // ReceiveNonBlockingAndCheckPacket reads a packet from the link layer endpoint // and verifies that the packet packet payload of packet matches the slice of // data indicated by offset & size. It returns true if a packet was received and // processed. func (c *Context) ReceiveNonBlockingAndCheckPacket(data []byte, offset, size int) bool { b := c.GetPacketNonBlocking() if b == nil { return false } checker.IPv4(c.t, b, checker.PayloadLen(size+header.TCPMinimumSize), checker.TCP( checker.DstPort(TestPort), checker.SeqNum(uint32(c.IRS.Add(seqnum.Size(1+offset)))), checker.AckNum(uint32(seqnum.Value(testInitialSequenceNumber).Add(1))), checker.TCPFlagsMatch(header.TCPFlagAck, ^uint8(header.TCPFlagPsh)), ), ) pdata := data[offset:][:size] if p := b[header.IPv4MinimumSize+header.TCPMinimumSize:]; bytes.Compare(pdata, p) != 0 { c.t.Fatalf("Data is different: expected %v, got %v", pdata, p) } return true } // CreateV6Endpoint creates and initializes c.ep as a IPv6 Endpoint. If v6Only // is true then it sets the IP_V6ONLY option on the socket to make it a IPv6 // only endpoint instead of a default dual stack socket. func (c *Context) CreateV6Endpoint(v6only bool) { var err *tcpip.Error c.EP, err = c.s.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &c.WQ) if err != nil { c.t.Fatalf("NewEndpoint failed: %v", err) } var v tcpip.V6OnlyOption if v6only { v = 1 } if err := c.EP.SetSockOpt(v); err != nil { c.t.Fatalf("SetSockOpt failed failed: %v", err) } } // GetV6Packet reads a single packet from the link layer endpoint of the context // and asserts that it is an IPv6 Packet with the expected src/dest addresses. func (c *Context) GetV6Packet() []byte { select { case p := <-c.linkEP.C: if p.Proto != ipv6.ProtocolNumber { c.t.Fatalf("Bad network protocol: got %v, wanted %v", p.Proto, ipv6.ProtocolNumber) } b := make([]byte, len(p.Header)+len(p.Payload)) copy(b, p.Header) copy(b[len(p.Header):], p.Payload) checker.IPv6(c.t, b, checker.SrcAddr(StackV6Addr), checker.DstAddr(TestV6Addr)) return b case <-time.After(2 * time.Second): c.t.Fatalf("Packet wasn't written out") } return nil } // SendV6Packet builds and sends an IPv6 Packet via the link layer endpoint of // the context. func (c *Context) SendV6Packet(payload []byte, h *Headers) { // Allocate a buffer for data and headers. buf := buffer.NewView(header.TCPMinimumSize + header.IPv6MinimumSize + len(payload)) copy(buf[len(buf)-len(payload):], payload) // Initialize the IP header. ip := header.IPv6(buf) ip.Encode(&header.IPv6Fields{ PayloadLength: uint16(header.TCPMinimumSize + len(payload)), NextHeader: uint8(tcp.ProtocolNumber), HopLimit: 65, SrcAddr: TestV6Addr, DstAddr: StackV6Addr, }) // Initialize the TCP header. t := header.TCP(buf[header.IPv6MinimumSize:]) t.Encode(&header.TCPFields{ SrcPort: h.SrcPort, DstPort: h.DstPort, SeqNum: uint32(h.SeqNum), AckNum: uint32(h.AckNum), DataOffset: header.TCPMinimumSize, Flags: uint8(h.Flags), WindowSize: uint16(h.RcvWnd), }) // Calculate the TCP pseudo-header checksum. xsum := header.PseudoHeaderChecksum(tcp.ProtocolNumber, TestV6Addr, StackV6Addr, uint16(len(t))) // Calculate the TCP checksum and set it. xsum = header.Checksum(payload, xsum) t.SetChecksum(^t.CalculateChecksum(xsum)) // Inject packet. c.linkEP.Inject(ipv6.ProtocolNumber, buf.ToVectorisedView()) } // CreateConnected creates a connected TCP endpoint. func (c *Context) CreateConnected(iss seqnum.Value, rcvWnd seqnum.Size, epRcvBuf *tcpip.ReceiveBufferSizeOption) { c.CreateConnectedWithRawOptions(iss, rcvWnd, epRcvBuf, nil) } // Connect performs the 3-way handshake for c.EP with the provided Initial // Sequence Number (iss) and receive window(rcvWnd) and any options if // specified. // // It also sets the receive buffer for the endpoint to the specified // value in epRcvBuf. // // PreCondition: c.EP must already be created. func (c *Context) Connect(iss seqnum.Value, rcvWnd seqnum.Size, options []byte) { // Start connection attempt. waitEntry, notifyCh := waiter.NewChannelEntry(nil) c.WQ.EventRegister(&waitEntry, waiter.EventOut) defer c.WQ.EventUnregister(&waitEntry) if err := c.EP.Connect(tcpip.FullAddress{Addr: TestAddr, Port: TestPort}); err != tcpip.ErrConnectStarted { c.t.Fatalf("Unexpected return value from Connect: %v", err) } // Receive SYN packet. b := c.GetPacket() checker.IPv4(c.t, b, checker.TCP( checker.DstPort(TestPort), checker.TCPFlags(header.TCPFlagSyn), ), ) if got, want := tcp.EndpointState(c.EP.State()), tcp.StateSynSent; got != want { c.t.Fatalf("Unexpected endpoint state: want %v, got %v", want, got) } tcpHdr := header.TCP(header.IPv4(b).Payload()) c.IRS = seqnum.Value(tcpHdr.SequenceNumber()) c.SendPacket(nil, &Headers{ SrcPort: tcpHdr.DestinationPort(), DstPort: tcpHdr.SourcePort(), Flags: header.TCPFlagSyn | header.TCPFlagAck, SeqNum: iss, AckNum: c.IRS.Add(1), RcvWnd: rcvWnd, TCPOpts: options, }) // Receive ACK packet. checker.IPv4(c.t, c.GetPacket(), checker.TCP( checker.DstPort(TestPort), checker.TCPFlags(header.TCPFlagAck), checker.SeqNum(uint32(c.IRS)+1), checker.AckNum(uint32(iss)+1), ), ) // Wait for connection to be established. select { case <-notifyCh: if err := c.EP.GetSockOpt(tcpip.ErrorOption{}); err != nil { c.t.Fatalf("Unexpected error when connecting: %v", err) } case <-time.After(1 * time.Second): c.t.Fatalf("Timed out waiting for connection") } if got, want := tcp.EndpointState(c.EP.State()), tcp.StateEstablished; got != want { c.t.Fatalf("Unexpected endpoint state: want %v, got %v", want, got) } c.Port = tcpHdr.SourcePort() } // CreateConnectedWithRawOptions creates a connected TCP endpoint and sends // the specified option bytes as the Option field in the initial SYN packet. // // It also sets the receive buffer for the endpoint to the specified // value in epRcvBuf. func (c *Context) CreateConnectedWithRawOptions(iss seqnum.Value, rcvWnd seqnum.Size, epRcvBuf *tcpip.ReceiveBufferSizeOption, options []byte) { // Create TCP endpoint. var err *tcpip.Error c.EP, err = c.s.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &c.WQ) if err != nil { c.t.Fatalf("NewEndpoint failed: %v", err) } if epRcvBuf != nil { if err := c.EP.SetSockOpt(*epRcvBuf); err != nil { c.t.Fatalf("SetSockOpt failed failed: %v", err) } } c.Connect(iss, rcvWnd, options) } // RawEndpoint is just a small wrapper around a TCP endpoint's state to make // sending data and ACK packets easy while being able to manipulate the sequence // numbers and timestamp values as needed. type RawEndpoint struct { C *Context SrcPort uint16 DstPort uint16 Flags int NextSeqNum seqnum.Value AckNum seqnum.Value WndSize seqnum.Size RecentTS uint32 // Stores the latest timestamp to echo back. TSVal uint32 // TSVal stores the last timestamp sent by this endpoint. // SackPermitted is true if SACKPermitted option was negotiated for this endpoint. SACKPermitted bool } // SendPacketWithTS embeds the provided tsVal in the Timestamp option // for the packet to be sent out. func (r *RawEndpoint) SendPacketWithTS(payload []byte, tsVal uint32) { r.TSVal = tsVal tsOpt := [12]byte{header.TCPOptionNOP, header.TCPOptionNOP} header.EncodeTSOption(r.TSVal, r.RecentTS, tsOpt[2:]) r.SendPacket(payload, tsOpt[:]) } // SendPacket is a small wrapper function to build and send packets. func (r *RawEndpoint) SendPacket(payload []byte, opts []byte) { packetHeaders := &Headers{ SrcPort: r.SrcPort, DstPort: r.DstPort, Flags: r.Flags, SeqNum: r.NextSeqNum, AckNum: r.AckNum, RcvWnd: r.WndSize, TCPOpts: opts, } r.C.SendPacket(payload, packetHeaders) r.NextSeqNum = r.NextSeqNum.Add(seqnum.Size(len(payload))) } // VerifyACKWithTS verifies that the tsEcr field in the ack matches the provided // tsVal. func (r *RawEndpoint) VerifyACKWithTS(tsVal uint32) { // Read ACK and verify that tsEcr of ACK packet is [1,2,3,4] ackPacket := r.C.GetPacket() checker.IPv4(r.C.t, ackPacket, checker.TCP( checker.DstPort(r.SrcPort), checker.TCPFlags(header.TCPFlagAck), checker.SeqNum(uint32(r.AckNum)), checker.AckNum(uint32(r.NextSeqNum)), checker.TCPTimestampChecker(true, 0, tsVal), ), ) // Store the parsed TSVal from the ack as recentTS. tcpSeg := header.TCP(header.IPv4(ackPacket).Payload()) opts := tcpSeg.ParsedOptions() r.RecentTS = opts.TSVal } // VerifyACKRcvWnd verifies that the window advertised by the incoming ACK // matches the provided rcvWnd. func (r *RawEndpoint) VerifyACKRcvWnd(rcvWnd uint16) { ackPacket := r.C.GetPacket() checker.IPv4(r.C.t, ackPacket, checker.TCP( checker.DstPort(r.SrcPort), checker.TCPFlags(header.TCPFlagAck), checker.SeqNum(uint32(r.AckNum)), checker.AckNum(uint32(r.NextSeqNum)), checker.Window(rcvWnd), ), ) } // VerifyACKNoSACK verifies that the ACK does not contain a SACK block. func (r *RawEndpoint) VerifyACKNoSACK() { r.VerifyACKHasSACK(nil) } // VerifyACKHasSACK verifies that the ACK contains the specified SACKBlocks. func (r *RawEndpoint) VerifyACKHasSACK(sackBlocks []header.SACKBlock) { // Read ACK and verify that the TCP options in the segment do // not contain a SACK block. ackPacket := r.C.GetPacket() checker.IPv4(r.C.t, ackPacket, checker.TCP( checker.DstPort(r.SrcPort), checker.TCPFlags(header.TCPFlagAck), checker.SeqNum(uint32(r.AckNum)), checker.AckNum(uint32(r.NextSeqNum)), checker.TCPSACKBlockChecker(sackBlocks), ), ) } // CreateConnectedWithOptions creates and connects c.ep with the specified TCP // options enabled and returns a RawEndpoint which represents the other end of // the connection. // // It also verifies where required(eg.Timestamp) that the ACK to the SYN-ACK // does not carry an option that was not requested. func (c *Context) CreateConnectedWithOptions(wantOptions header.TCPSynOptions) *RawEndpoint { var err *tcpip.Error c.EP, err = c.s.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &c.WQ) if err != nil { c.t.Fatalf("c.s.NewEndpoint(tcp, ipv4...) = %v", err) } if got, want := tcp.EndpointState(c.EP.State()), tcp.StateInitial; got != want { c.t.Fatalf("Unexpected endpoint state: want %v, got %v", want, got) } // Start connection attempt. waitEntry, notifyCh := waiter.NewChannelEntry(nil) c.WQ.EventRegister(&waitEntry, waiter.EventOut) defer c.WQ.EventUnregister(&waitEntry) testFullAddr := tcpip.FullAddress{Addr: TestAddr, Port: TestPort} err = c.EP.Connect(testFullAddr) if err != tcpip.ErrConnectStarted { c.t.Fatalf("c.ep.Connect(%v) = %v", testFullAddr, err) } // Receive SYN packet. b := c.GetPacket() // Validate that the syn has the timestamp option and a valid // TS value. mss := uint16(c.linkEP.MTU() - header.IPv4MinimumSize - header.TCPMinimumSize) checker.IPv4(c.t, b, checker.TCP( checker.DstPort(TestPort), checker.TCPFlags(header.TCPFlagSyn), checker.TCPSynOptions(header.TCPSynOptions{ MSS: mss, TS: true, WS: int(c.WindowScale), SACKPermitted: c.SACKEnabled(), }), ), ) if got, want := tcp.EndpointState(c.EP.State()), tcp.StateSynSent; got != want { c.t.Fatalf("Unexpected endpoint state: want %v, got %v", want, got) } tcpSeg := header.TCP(header.IPv4(b).Payload()) synOptions := header.ParseSynOptions(tcpSeg.Options(), false) // Build options w/ tsVal to be sent in the SYN-ACK. synAckOptions := make([]byte, header.TCPOptionsMaximumSize) offset := 0 if wantOptions.WS != -1 { offset += header.EncodeWSOption(wantOptions.WS, synAckOptions[offset:]) } if wantOptions.TS { offset += header.EncodeTSOption(wantOptions.TSVal, synOptions.TSVal, synAckOptions[offset:]) } if wantOptions.SACKPermitted { offset += header.EncodeSACKPermittedOption(synAckOptions[offset:]) } offset += header.AddTCPOptionPadding(synAckOptions, offset) // Build SYN-ACK. c.IRS = seqnum.Value(tcpSeg.SequenceNumber()) iss := seqnum.Value(testInitialSequenceNumber) c.SendPacket(nil, &Headers{ SrcPort: tcpSeg.DestinationPort(), DstPort: tcpSeg.SourcePort(), Flags: header.TCPFlagSyn | header.TCPFlagAck, SeqNum: iss, AckNum: c.IRS.Add(1), RcvWnd: 30000, TCPOpts: synAckOptions[:offset], }) // Read ACK. ackPacket := c.GetPacket() // Verify TCP header fields. tcpCheckers := []checker.TransportChecker{ checker.DstPort(TestPort), checker.TCPFlags(header.TCPFlagAck), checker.SeqNum(uint32(c.IRS) + 1), checker.AckNum(uint32(iss) + 1), } // Verify that tsEcr of ACK packet is wantOptions.TSVal if the // timestamp option was enabled, if not then we verify that // there is no timestamp in the ACK packet. if wantOptions.TS { tcpCheckers = append(tcpCheckers, checker.TCPTimestampChecker(true, 0, wantOptions.TSVal)) } else { tcpCheckers = append(tcpCheckers, checker.TCPTimestampChecker(false, 0, 0)) } checker.IPv4(c.t, ackPacket, checker.TCP(tcpCheckers...)) ackSeg := header.TCP(header.IPv4(ackPacket).Payload()) ackOptions := ackSeg.ParsedOptions() // Wait for connection to be established. select { case <-notifyCh: err = c.EP.GetSockOpt(tcpip.ErrorOption{}) if err != nil { c.t.Fatalf("Unexpected error when connecting: %v", err) } case <-time.After(1 * time.Second): c.t.Fatalf("Timed out waiting for connection") } if got, want := tcp.EndpointState(c.EP.State()), tcp.StateEstablished; got != want { c.t.Fatalf("Unexpected endpoint state: want %v, got %v", want, got) } // Store the source port in use by the endpoint. c.Port = tcpSeg.SourcePort() // Mark in context that timestamp option is enabled for this endpoint. c.TimeStampEnabled = true return &RawEndpoint{ C: c, SrcPort: tcpSeg.DestinationPort(), DstPort: tcpSeg.SourcePort(), Flags: header.TCPFlagAck | header.TCPFlagPsh, NextSeqNum: iss + 1, AckNum: c.IRS.Add(1), WndSize: 30000, RecentTS: ackOptions.TSVal, TSVal: wantOptions.TSVal, SACKPermitted: wantOptions.SACKPermitted, } } // AcceptWithOptions initializes a listening endpoint and connects to it with the // provided options enabled. It also verifies that the SYN-ACK has the expected // values for the provided options. // // The function returns a RawEndpoint representing the other end of the accepted // endpoint. func (c *Context) AcceptWithOptions(wndScale int, synOptions header.TCPSynOptions) *RawEndpoint { // Create EP and start listening. wq := &waiter.Queue{} ep, err := c.s.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, wq) if err != nil { c.t.Fatalf("NewEndpoint failed: %v", err) } defer ep.Close() if err := ep.Bind(tcpip.FullAddress{Port: StackPort}); err != nil { c.t.Fatalf("Bind failed: %v", err) } if got, want := tcp.EndpointState(ep.State()), tcp.StateBound; got != want { c.t.Errorf("Unexpected endpoint state: want %v, got %v", want, got) } if err := ep.Listen(10); err != nil { c.t.Fatalf("Listen failed: %v", err) } if got, want := tcp.EndpointState(ep.State()), tcp.StateListen; got != want { c.t.Errorf("Unexpected endpoint state: want %v, got %v", want, got) } rep := c.PassiveConnectWithOptions(100, wndScale, synOptions) // Try to accept the connection. we, ch := waiter.NewChannelEntry(nil) wq.EventRegister(&we, waiter.EventIn) defer wq.EventUnregister(&we) c.EP, _, err = ep.Accept() if err == tcpip.ErrWouldBlock { // Wait for connection to be established. select { case <-ch: c.EP, _, err = ep.Accept() if err != nil { c.t.Fatalf("Accept failed: %v", err) } case <-time.After(1 * time.Second): c.t.Fatalf("Timed out waiting for accept") } } if got, want := tcp.EndpointState(c.EP.State()), tcp.StateEstablished; got != want { c.t.Errorf("Unexpected endpoint state: want %v, got %v", want, got) } return rep } // PassiveConnect just disables WindowScaling and delegates the call to // PassiveConnectWithOptions. func (c *Context) PassiveConnect(maxPayload, wndScale int, synOptions header.TCPSynOptions) { synOptions.WS = -1 c.PassiveConnectWithOptions(maxPayload, wndScale, synOptions) } // PassiveConnectWithOptions initiates a new connection (with the specified TCP // options enabled) to the port on which the Context.ep is listening for new // connections. It also validates that the SYN-ACK has the expected values for // the enabled options. // // NOTE: MSS is not a negotiated option and it can be asymmetric // in each direction. This function uses the maxPayload to set the MSS to be // sent to the peer on a connect and validates that the MSS in the SYN-ACK // response is equal to the MTU - (tcphdr len + iphdr len). // // wndScale is the expected window scale in the SYN-ACK and synOptions.WS is the // value of the window scaling option to be sent in the SYN. If synOptions.WS > // 0 then we send the WindowScale option. func (c *Context) PassiveConnectWithOptions(maxPayload, wndScale int, synOptions header.TCPSynOptions) *RawEndpoint { opts := make([]byte, header.TCPOptionsMaximumSize) offset := 0 offset += header.EncodeMSSOption(uint32(maxPayload), opts) if synOptions.WS >= 0 { offset += header.EncodeWSOption(3, opts[offset:]) } if synOptions.TS { offset += header.EncodeTSOption(synOptions.TSVal, synOptions.TSEcr, opts[offset:]) } if synOptions.SACKPermitted { offset += header.EncodeSACKPermittedOption(opts[offset:]) } paddingToAdd := 4 - offset%4 // Now add any padding bytes that might be required to quad align the // options. for i := offset; i < offset+paddingToAdd; i++ { opts[i] = header.TCPOptionNOP } offset += paddingToAdd // Send a SYN request. iss := seqnum.Value(testInitialSequenceNumber) c.SendPacket(nil, &Headers{ SrcPort: TestPort, DstPort: StackPort, Flags: header.TCPFlagSyn, SeqNum: iss, RcvWnd: 30000, TCPOpts: opts[:offset], }) // Receive the SYN-ACK reply. Make sure MSS and other expected options // are present. b := c.GetPacket() tcp := header.TCP(header.IPv4(b).Payload()) c.IRS = seqnum.Value(tcp.SequenceNumber()) tcpCheckers := []checker.TransportChecker{ checker.SrcPort(StackPort), checker.DstPort(TestPort), checker.TCPFlags(header.TCPFlagAck | header.TCPFlagSyn), checker.AckNum(uint32(iss) + 1), checker.TCPSynOptions(header.TCPSynOptions{MSS: synOptions.MSS, WS: wndScale, SACKPermitted: synOptions.SACKPermitted && c.SACKEnabled()}), } // If TS option was enabled in the original SYN then add a checker to // validate the Timestamp option in the SYN-ACK. if synOptions.TS { tcpCheckers = append(tcpCheckers, checker.TCPTimestampChecker(synOptions.TS, 0, synOptions.TSVal)) } else { tcpCheckers = append(tcpCheckers, checker.TCPTimestampChecker(false, 0, 0)) } checker.IPv4(c.t, b, checker.TCP(tcpCheckers...)) rcvWnd := seqnum.Size(30000) ackHeaders := &Headers{ SrcPort: TestPort, DstPort: StackPort, Flags: header.TCPFlagAck, SeqNum: iss + 1, AckNum: c.IRS + 1, RcvWnd: rcvWnd, } // If WS was expected to be in effect then scale the advertised window // correspondingly. if synOptions.WS > 0 { ackHeaders.RcvWnd = rcvWnd >> byte(synOptions.WS) } parsedOpts := tcp.ParsedOptions() if synOptions.TS { // Echo the tsVal back to the peer in the tsEcr field of the // timestamp option. // Increment TSVal by 1 from the value sent in the SYN and echo // the TSVal in the SYN-ACK in the TSEcr field. opts := [12]byte{header.TCPOptionNOP, header.TCPOptionNOP} header.EncodeTSOption(synOptions.TSVal+1, parsedOpts.TSVal, opts[2:]) ackHeaders.TCPOpts = opts[:] } // Send ACK. c.SendPacket(nil, ackHeaders) c.Port = StackPort return &RawEndpoint{ C: c, SrcPort: TestPort, DstPort: StackPort, Flags: header.TCPFlagPsh | header.TCPFlagAck, NextSeqNum: iss + 1, AckNum: c.IRS + 1, WndSize: rcvWnd, SACKPermitted: synOptions.SACKPermitted && c.SACKEnabled(), RecentTS: parsedOpts.TSVal, TSVal: synOptions.TSVal + 1, } } // SACKEnabled returns true if the TCP Protocol option SACKEnabled is set to true // for the Stack in the context. func (c *Context) SACKEnabled() bool { var v tcp.SACKEnabled if err := c.Stack().TransportProtocolOption(tcp.ProtocolNumber, &v); err != nil { // Stack doesn't support SACK. So just return. return false } return bool(v) } // SetGSOEnabled enables or disables generic segmentation offload. func (c *Context) SetGSOEnabled(enable bool) { c.linkEP.GSO = enable } // MSSWithoutOptions returns the value for the MSS used by the stack when no // options are in use. func (c *Context) MSSWithoutOptions() uint16 { return uint16(c.linkEP.MTU() - header.IPv4MinimumSize - header.TCPMinimumSize) }