// 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. // +build linux // Package fdbased provides the implemention of data-link layer endpoints // backed by boundary-preserving file descriptors (e.g., TUN devices, // seqpacket/datagram sockets). // // FD based endpoints can be used in the networking stack by calling New() to // create a new endpoint, and then passing it as an argument to // Stack.CreateNIC(). // // FD based endpoints can use more than one file descriptor to read incoming // packets. If there are more than one FDs specified and the underlying FD is an // AF_PACKET then the endpoint will enable FANOUT mode on the socket so that the // host kernel will consistently hash the packets to the sockets. This ensures // that packets for the same TCP streams are not reordered. // // Similarly if more than one FD's are specified where the underlying FD is not // AF_PACKET then it's the caller's responsibility to ensure that all inbound // packets on the descriptors are consistently 5 tuple hashed to one of the // descriptors to prevent TCP reordering. // // Since netstack today does not compute 5 tuple hashes for outgoing packets we // only use the first FD to write outbound packets. Once 5 tuple hashes for // all outbound packets are available we will make use of all underlying FD's to // write outbound packets. package fdbased import ( "fmt" "sync/atomic" "golang.org/x/sys/unix" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/link/rawfile" "gvisor.dev/gvisor/pkg/tcpip/stack" ) // linkDispatcher reads packets from the link FD and dispatches them to the // NetworkDispatcher. type linkDispatcher interface { dispatch() (bool, tcpip.Error) } // PacketDispatchMode are the various supported methods of receiving and // dispatching packets from the underlying FD. type PacketDispatchMode int const ( // Readv is the default dispatch mode and is the least performant of the // dispatch options but the one that is supported by all underlying FD // types. Readv PacketDispatchMode = iota // RecvMMsg enables use of recvmmsg() syscall instead of readv() to // read inbound packets. This reduces # of syscalls needed to process // packets. // // NOTE: recvmmsg() is only supported for sockets, so if the underlying // FD is not a socket then the code will still fall back to the readv() // path. RecvMMsg // PacketMMap enables use of PACKET_RX_RING to receive packets from the // NIC. PacketMMap requires that the underlying FD be an AF_PACKET. The // primary use-case for this is runsc which uses an AF_PACKET FD to // receive packets from the veth device. PacketMMap ) func (p PacketDispatchMode) String() string { switch p { case Readv: return "Readv" case RecvMMsg: return "RecvMMsg" case PacketMMap: return "PacketMMap" default: return fmt.Sprintf("unknown packet dispatch mode '%d'", p) } } var _ stack.LinkEndpoint = (*endpoint)(nil) var _ stack.GSOEndpoint = (*endpoint)(nil) type endpoint struct { // fds is the set of file descriptors each identifying one inbound/outbound // channel. The endpoint will dispatch from all inbound channels as well as // hash outbound packets to specific channels based on the packet hash. fds []int // mtu (maximum transmission unit) is the maximum size of a packet. mtu uint32 // hdrSize specifies the link-layer header size. If set to 0, no header // is added/removed; otherwise an ethernet header is used. hdrSize int // addr is the address of the endpoint. addr tcpip.LinkAddress // caps holds the endpoint capabilities. caps stack.LinkEndpointCapabilities // closed is a function to be called when the FD's peer (if any) closes // its end of the communication pipe. closed func(tcpip.Error) inboundDispatchers []linkDispatcher dispatcher stack.NetworkDispatcher // packetDispatchMode controls the packet dispatcher used by this // endpoint. packetDispatchMode PacketDispatchMode // gsoMaxSize is the maximum GSO packet size. It is zero if GSO is // disabled. gsoMaxSize uint32 // wg keeps track of running goroutines. wg sync.WaitGroup // gsoKind is the supported kind of GSO. gsoKind stack.SupportedGSO // maxSyscallHeaderBytes has the same meaning as // Options.MaxSyscallHeaderBytes. maxSyscallHeaderBytes uintptr // writevMaxIovs is the maximum number of iovecs that may be passed to // rawfile.NonBlockingWriteIovec, as possibly limited by // maxSyscallHeaderBytes. (No analogous limit is defined for // rawfile.NonBlockingSendMMsg, since in that case the maximum number of // iovecs also depends on the number of mmsghdrs. Instead, if sendBatch // encounters a packet whose iovec count is limited by // maxSyscallHeaderBytes, it falls back to writing the packet using writev // via WritePacket.) writevMaxIovs int } // Options specify the details about the fd-based endpoint to be created. type Options struct { // FDs is a set of FDs used to read/write packets. FDs []int // MTU is the mtu to use for this endpoint. MTU uint32 // EthernetHeader if true, indicates that the endpoint should read/write // ethernet frames instead of IP packets. EthernetHeader bool // ClosedFunc is a function to be called when an endpoint's peer (if // any) closes its end of the communication pipe. ClosedFunc func(tcpip.Error) // Address is the link address for this endpoint. Only used if // EthernetHeader is true. Address tcpip.LinkAddress // SaveRestore if true, indicates that this NIC capability set should // include CapabilitySaveRestore SaveRestore bool // DisconnectOk if true, indicates that this NIC capability set should // include CapabilityDisconnectOk. DisconnectOk bool // GSOMaxSize is the maximum GSO packet size. It is zero if GSO is // disabled. GSOMaxSize uint32 // SoftwareGSOEnabled indicates whether software GSO is enabled or not. SoftwareGSOEnabled bool // PacketDispatchMode specifies the type of inbound dispatcher to be // used for this endpoint. PacketDispatchMode PacketDispatchMode // TXChecksumOffload if true, indicates that this endpoints capability // set should include CapabilityTXChecksumOffload. TXChecksumOffload bool // RXChecksumOffload if true, indicates that this endpoints capability // set should include CapabilityRXChecksumOffload. RXChecksumOffload bool // If MaxSyscallHeaderBytes is non-zero, it is the maximum number of bytes // of struct iovec, msghdr, and mmsghdr that may be passed by each host // system call. MaxSyscallHeaderBytes int } // fanoutID is used for AF_PACKET based endpoints to enable PACKET_FANOUT // support in the host kernel. This allows us to use multiple FD's to receive // from the same underlying NIC. The fanoutID needs to be the same for a given // set of FD's that point to the same NIC. Trying to set the PACKET_FANOUT // option for an FD with a fanoutID already in use by another FD for a different // NIC will return an EINVAL. // // Since fanoutID must be unique within the network namespace, we start with // the PID to avoid collisions. The only way to be sure of avoiding collisions // is to run in a new network namespace. // // Must be accessed using atomic operations. var fanoutID int32 = int32(unix.Getpid()) // New creates a new fd-based endpoint. // // Makes fd non-blocking, but does not take ownership of fd, which must remain // open for the lifetime of the returned endpoint (until after the endpoint has // stopped being using and Wait returns). func New(opts *Options) (stack.LinkEndpoint, error) { caps := stack.LinkEndpointCapabilities(0) if opts.RXChecksumOffload { caps |= stack.CapabilityRXChecksumOffload } if opts.TXChecksumOffload { caps |= stack.CapabilityTXChecksumOffload } hdrSize := 0 if opts.EthernetHeader { hdrSize = header.EthernetMinimumSize caps |= stack.CapabilityResolutionRequired } if opts.SaveRestore { caps |= stack.CapabilitySaveRestore } if opts.DisconnectOk { caps |= stack.CapabilityDisconnectOk } if len(opts.FDs) == 0 { return nil, fmt.Errorf("opts.FD is empty, at least one FD must be specified") } if opts.MaxSyscallHeaderBytes < 0 { return nil, fmt.Errorf("opts.MaxSyscallHeaderBytes is negative") } e := &endpoint{ fds: opts.FDs, mtu: opts.MTU, caps: caps, closed: opts.ClosedFunc, addr: opts.Address, hdrSize: hdrSize, packetDispatchMode: opts.PacketDispatchMode, maxSyscallHeaderBytes: uintptr(opts.MaxSyscallHeaderBytes), writevMaxIovs: rawfile.MaxIovs, } if e.maxSyscallHeaderBytes != 0 { if max := int(e.maxSyscallHeaderBytes / rawfile.SizeofIovec); max < e.writevMaxIovs { e.writevMaxIovs = max } } // Increment fanoutID to ensure that we don't re-use the same fanoutID for // the next endpoint. fid := atomic.AddInt32(&fanoutID, 1) // Create per channel dispatchers. for i := 0; i < len(e.fds); i++ { fd := e.fds[i] if err := unix.SetNonblock(fd, true); err != nil { return nil, fmt.Errorf("unix.SetNonblock(%v) failed: %v", fd, err) } isSocket, err := isSocketFD(fd) if err != nil { return nil, err } if isSocket { if opts.GSOMaxSize != 0 { if opts.SoftwareGSOEnabled { e.gsoKind = stack.SWGSOSupported } else { e.gsoKind = stack.HWGSOSupported } e.gsoMaxSize = opts.GSOMaxSize } } inboundDispatcher, err := createInboundDispatcher(e, fd, isSocket, fid) if err != nil { return nil, fmt.Errorf("createInboundDispatcher(...) = %v", err) } e.inboundDispatchers = append(e.inboundDispatchers, inboundDispatcher) } return e, nil } func createInboundDispatcher(e *endpoint, fd int, isSocket bool, fID int32) (linkDispatcher, error) { // By default use the readv() dispatcher as it works with all kinds of // FDs (tap/tun/unix domain sockets and af_packet). inboundDispatcher, err := newReadVDispatcher(fd, e) if err != nil { return nil, fmt.Errorf("newReadVDispatcher(%d, %+v) = %v", fd, e, err) } if isSocket { sa, err := unix.Getsockname(fd) if err != nil { return nil, fmt.Errorf("unix.Getsockname(%d) = %v", fd, err) } switch sa.(type) { case *unix.SockaddrLinklayer: // Enable PACKET_FANOUT mode if the underlying socket is of type // AF_PACKET. We do not enable PACKET_FANOUT_FLAG_DEFRAG as that will // prevent gvisor from receiving fragmented packets and the host does the // reassembly on our behalf before delivering the fragments. This makes it // hard to test fragmentation reassembly code in Netstack. // // See: include/uapi/linux/if_packet.h (struct fanout_args). // // NOTE: We are using SetSockOptInt here even though the underlying // option is actually a struct. The code follows the example in the // kernel documentation as described at the link below: // // See: https://www.kernel.org/doc/Documentation/networking/packet_mmap.txt // // This works out because the actual implementation for the option zero // initializes the structure and will initialize the max_members field // to a proper value if zero. // // See: https://github.com/torvalds/linux/blob/7acac4b3196caee5e21fb5ea53f8bc124e6a16fc/net/packet/af_packet.c#L3881 const fanoutType = unix.PACKET_FANOUT_HASH fanoutArg := (int(fID) & 0xffff) | fanoutType<<16 if err := unix.SetsockoptInt(fd, unix.SOL_PACKET, unix.PACKET_FANOUT, fanoutArg); err != nil { return nil, fmt.Errorf("failed to enable PACKET_FANOUT option: %v", err) } } switch e.packetDispatchMode { case PacketMMap: inboundDispatcher, err = newPacketMMapDispatcher(fd, e) if err != nil { return nil, fmt.Errorf("newPacketMMapDispatcher(%d, %+v) = %v", fd, e, err) } case RecvMMsg: // If the provided FD is a socket then we optimize // packet reads by using recvmmsg() instead of read() to // read packets in a batch. inboundDispatcher, err = newRecvMMsgDispatcher(fd, e) if err != nil { return nil, fmt.Errorf("newRecvMMsgDispatcher(%d, %+v) = %v", fd, e, err) } } } return inboundDispatcher, nil } func isSocketFD(fd int) (bool, error) { var stat unix.Stat_t if err := unix.Fstat(fd, &stat); err != nil { return false, fmt.Errorf("unix.Fstat(%v,...) failed: %v", fd, err) } return (stat.Mode & unix.S_IFSOCK) == unix.S_IFSOCK, nil } // Attach launches the goroutine that reads packets from the file descriptor and // dispatches them via the provided dispatcher. func (e *endpoint) Attach(dispatcher stack.NetworkDispatcher) { e.dispatcher = dispatcher // Link endpoints are not savable. When transportation endpoints are // saved, they stop sending outgoing packets and all incoming packets // are rejected. for i := range e.inboundDispatchers { e.wg.Add(1) go func(i int) { // S/R-SAFE: See above. e.dispatchLoop(e.inboundDispatchers[i]) e.wg.Done() }(i) } } // IsAttached implements stack.LinkEndpoint.IsAttached. func (e *endpoint) IsAttached() bool { return e.dispatcher != nil } // MTU implements stack.LinkEndpoint.MTU. It returns the value initialized // during construction. func (e *endpoint) MTU() uint32 { return e.mtu } // Capabilities implements stack.LinkEndpoint.Capabilities. func (e *endpoint) Capabilities() stack.LinkEndpointCapabilities { return e.caps } // MaxHeaderLength returns the maximum size of the link-layer header. func (e *endpoint) MaxHeaderLength() uint16 { return uint16(e.hdrSize) } // LinkAddress returns the link address of this endpoint. func (e *endpoint) LinkAddress() tcpip.LinkAddress { return e.addr } // Wait implements stack.LinkEndpoint.Wait. It waits for the endpoint to stop // reading from its FD. func (e *endpoint) Wait() { e.wg.Wait() } // virtioNetHdr is declared in linux/virtio_net.h. type virtioNetHdr struct { flags uint8 gsoType uint8 hdrLen uint16 gsoSize uint16 csumStart uint16 csumOffset uint16 } // marshal serializes h to a newly-allocated byte slice, in little-endian byte // order. // // Note: Virtio v1.0 onwards specifies little-endian as the byte ordering used // for general serialization. This makes it difficult to use go-marshal for // virtio types, as go-marshal implicitly uses the native byte ordering. func (h *virtioNetHdr) marshal() []byte { buf := [virtioNetHdrSize]byte{ 0: byte(h.flags), 1: byte(h.gsoType), // Manually lay out the fields in little-endian byte order. Little endian => // least significant bit goes to the lower address. 2: byte(h.hdrLen), 3: byte(h.hdrLen >> 8), 4: byte(h.gsoSize), 5: byte(h.gsoSize >> 8), 6: byte(h.csumStart), 7: byte(h.csumStart >> 8), 8: byte(h.csumOffset), 9: byte(h.csumOffset >> 8), } return buf[:] } // These constants are declared in linux/virtio_net.h. const ( _VIRTIO_NET_HDR_F_NEEDS_CSUM = 1 _VIRTIO_NET_HDR_GSO_TCPV4 = 1 _VIRTIO_NET_HDR_GSO_TCPV6 = 4 ) // AddHeader implements stack.LinkEndpoint.AddHeader. func (e *endpoint) AddHeader(local, remote tcpip.LinkAddress, protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) { if e.hdrSize > 0 { // Add ethernet header if needed. eth := header.Ethernet(pkt.LinkHeader().Push(header.EthernetMinimumSize)) ethHdr := &header.EthernetFields{ DstAddr: remote, Type: protocol, } // Preserve the src address if it's set in the route. if local != "" { ethHdr.SrcAddr = local } else { ethHdr.SrcAddr = e.addr } eth.Encode(ethHdr) } } // WritePacket writes outbound packets to the file descriptor. If it is not // currently writable, the packet is dropped. func (e *endpoint) WritePacket(r stack.RouteInfo, protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) tcpip.Error { if e.hdrSize > 0 { e.AddHeader(r.LocalLinkAddress, r.RemoteLinkAddress, protocol, pkt) } fd := e.fds[pkt.Hash%uint32(len(e.fds))] var vnetHdrBuf []byte if e.gsoKind == stack.HWGSOSupported { vnetHdr := virtioNetHdr{} if pkt.GSOOptions.Type != stack.GSONone { vnetHdr.hdrLen = uint16(pkt.HeaderSize()) if pkt.GSOOptions.NeedsCsum { vnetHdr.flags = _VIRTIO_NET_HDR_F_NEEDS_CSUM vnetHdr.csumStart = header.EthernetMinimumSize + pkt.GSOOptions.L3HdrLen vnetHdr.csumOffset = pkt.GSOOptions.CsumOffset } if pkt.GSOOptions.Type != stack.GSONone && uint16(pkt.Data().Size()) > pkt.GSOOptions.MSS { switch pkt.GSOOptions.Type { case stack.GSOTCPv4: vnetHdr.gsoType = _VIRTIO_NET_HDR_GSO_TCPV4 case stack.GSOTCPv6: vnetHdr.gsoType = _VIRTIO_NET_HDR_GSO_TCPV6 default: panic(fmt.Sprintf("Unknown gso type: %v", pkt.GSOOptions.Type)) } vnetHdr.gsoSize = pkt.GSOOptions.MSS } } vnetHdrBuf = vnetHdr.marshal() } views := pkt.Views() numIovecs := len(views) if len(vnetHdrBuf) != 0 { numIovecs++ } if numIovecs > e.writevMaxIovs { numIovecs = e.writevMaxIovs } // Allocate small iovec arrays on the stack. var iovecsArr [8]unix.Iovec iovecs := iovecsArr[:0] if numIovecs > len(iovecsArr) { iovecs = make([]unix.Iovec, 0, numIovecs) } iovecs = rawfile.AppendIovecFromBytes(iovecs, vnetHdrBuf, numIovecs) for _, v := range views { iovecs = rawfile.AppendIovecFromBytes(iovecs, v, numIovecs) } return rawfile.NonBlockingWriteIovec(fd, iovecs) } func (e *endpoint) sendBatch(batchFD int, pkts []*stack.PacketBuffer) (int, tcpip.Error) { // Send a batch of packets through batchFD. mmsgHdrsStorage := make([]rawfile.MMsgHdr, 0, len(pkts)) packets := 0 for packets < len(pkts) { mmsgHdrs := mmsgHdrsStorage batch := pkts[packets:] syscallHeaderBytes := uintptr(0) for _, pkt := range batch { if e.hdrSize > 0 { e.AddHeader(pkt.EgressRoute.LocalLinkAddress, pkt.EgressRoute.RemoteLinkAddress, pkt.NetworkProtocolNumber, pkt) } var vnetHdrBuf []byte if e.gsoKind == stack.HWGSOSupported { vnetHdr := virtioNetHdr{} if pkt.GSOOptions.Type != stack.GSONone { vnetHdr.hdrLen = uint16(pkt.HeaderSize()) if pkt.GSOOptions.NeedsCsum { vnetHdr.flags = _VIRTIO_NET_HDR_F_NEEDS_CSUM vnetHdr.csumStart = header.EthernetMinimumSize + pkt.GSOOptions.L3HdrLen vnetHdr.csumOffset = pkt.GSOOptions.CsumOffset } if pkt.GSOOptions.Type != stack.GSONone && uint16(pkt.Data().Size()) > pkt.GSOOptions.MSS { switch pkt.GSOOptions.Type { case stack.GSOTCPv4: vnetHdr.gsoType = _VIRTIO_NET_HDR_GSO_TCPV4 case stack.GSOTCPv6: vnetHdr.gsoType = _VIRTIO_NET_HDR_GSO_TCPV6 default: panic(fmt.Sprintf("Unknown gso type: %v", pkt.GSOOptions.Type)) } vnetHdr.gsoSize = pkt.GSOOptions.MSS } } vnetHdrBuf = vnetHdr.marshal() } views := pkt.Views() numIovecs := len(views) if len(vnetHdrBuf) != 0 { numIovecs++ } if numIovecs > rawfile.MaxIovs { numIovecs = rawfile.MaxIovs } if e.maxSyscallHeaderBytes != 0 { syscallHeaderBytes += rawfile.SizeofMMsgHdr + uintptr(numIovecs)*rawfile.SizeofIovec if syscallHeaderBytes > e.maxSyscallHeaderBytes { // We can't fit this packet into this call to sendmmsg(). // We could potentially do so if we reduced numIovecs // further, but this might incur considerable extra // copying. Leave it to the next batch instead. break } } // We can't easily allocate iovec arrays on the stack here since // they will escape this loop iteration via mmsgHdrs. iovecs := make([]unix.Iovec, 0, numIovecs) iovecs = rawfile.AppendIovecFromBytes(iovecs, vnetHdrBuf, numIovecs) for _, v := range views { iovecs = rawfile.AppendIovecFromBytes(iovecs, v, numIovecs) } var mmsgHdr rawfile.MMsgHdr mmsgHdr.Msg.Iov = &iovecs[0] mmsgHdr.Msg.SetIovlen(len(iovecs)) mmsgHdrs = append(mmsgHdrs, mmsgHdr) } if len(mmsgHdrs) == 0 { // We can't fit batch[0] into a mmsghdr while staying under // e.maxSyscallHeaderBytes. Use WritePacket, which will avoid the // mmsghdr (by using writev) and re-buffer iovecs more aggressively // if necessary (by using e.writevMaxIovs instead of // rawfile.MaxIovs). pkt := batch[0] if err := e.WritePacket(pkt.EgressRoute, pkt.NetworkProtocolNumber, pkt); err != nil { return packets, err } packets++ } else { for len(mmsgHdrs) > 0 { sent, err := rawfile.NonBlockingSendMMsg(batchFD, mmsgHdrs) if err != nil { return packets, err } packets += sent mmsgHdrs = mmsgHdrs[sent:] } } } return packets, nil } // WritePackets writes outbound packets to the underlying file descriptors. If // one is not currently writable, the packet is dropped. // // Being a batch API, each packet in pkts should have the following // fields populated: // - pkt.EgressRoute // - pkt.GSOOptions // - pkt.NetworkProtocolNumber func (e *endpoint) WritePackets(_ stack.RouteInfo, pkts stack.PacketBufferList, _ tcpip.NetworkProtocolNumber) (int, tcpip.Error) { // Preallocate to avoid repeated reallocation as we append to batch. // batchSz is 47 because when SWGSO is in use then a single 65KB TCP // segment can get split into 46 segments of 1420 bytes and a single 216 // byte segment. const batchSz = 47 batch := make([]*stack.PacketBuffer, 0, batchSz) batchFD := -1 sentPackets := 0 for pkt := pkts.Front(); pkt != nil; pkt = pkt.Next() { if len(batch) == 0 { batchFD = e.fds[pkt.Hash%uint32(len(e.fds))] } pktFD := e.fds[pkt.Hash%uint32(len(e.fds))] if sendNow := pktFD != batchFD; !sendNow { batch = append(batch, pkt) continue } n, err := e.sendBatch(batchFD, batch) sentPackets += n if err != nil { return sentPackets, err } batch = batch[:0] batch = append(batch, pkt) batchFD = pktFD } if len(batch) != 0 { n, err := e.sendBatch(batchFD, batch) sentPackets += n if err != nil { return sentPackets, err } } return sentPackets, nil } // viewsEqual tests whether v1 and v2 refer to the same backing bytes. func viewsEqual(vs1, vs2 []buffer.View) bool { return len(vs1) == len(vs2) && (len(vs1) == 0 || &vs1[0] == &vs2[0]) } // InjectOutobund implements stack.InjectableEndpoint.InjectOutbound. func (e *endpoint) InjectOutbound(dest tcpip.Address, packet []byte) tcpip.Error { return rawfile.NonBlockingWrite(e.fds[0], packet) } // dispatchLoop reads packets from the file descriptor in a loop and dispatches // them to the network stack. func (e *endpoint) dispatchLoop(inboundDispatcher linkDispatcher) tcpip.Error { for { cont, err := inboundDispatcher.dispatch() if err != nil || !cont { if e.closed != nil { e.closed(err) } return err } } } // GSOMaxSize implements stack.GSOEndpoint. func (e *endpoint) GSOMaxSize() uint32 { return e.gsoMaxSize } // SupportsHWGSO implements stack.GSOEndpoint. func (e *endpoint) SupportedGSO() stack.SupportedGSO { return e.gsoKind } // ARPHardwareType implements stack.LinkEndpoint.ARPHardwareType. func (e *endpoint) ARPHardwareType() header.ARPHardwareType { if e.hdrSize > 0 { return header.ARPHardwareEther } return header.ARPHardwareNone } // InjectableEndpoint is an injectable fd-based endpoint. The endpoint writes // to the FD, but does not read from it. All reads come from injected packets. type InjectableEndpoint struct { endpoint dispatcher stack.NetworkDispatcher } // Attach saves the stack network-layer dispatcher for use later when packets // are injected. func (e *InjectableEndpoint) Attach(dispatcher stack.NetworkDispatcher) { e.dispatcher = dispatcher } // InjectInbound injects an inbound packet. func (e *InjectableEndpoint) InjectInbound(protocol tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) { e.dispatcher.DeliverNetworkPacket("" /* remote */, "" /* local */, protocol, pkt) } // NewInjectable creates a new fd-based InjectableEndpoint. func NewInjectable(fd int, mtu uint32, capabilities stack.LinkEndpointCapabilities) *InjectableEndpoint { unix.SetNonblock(fd, true) return &InjectableEndpoint{endpoint: endpoint{ fds: []int{fd}, mtu: mtu, caps: capabilities, writevMaxIovs: rawfile.MaxIovs, }} }