// 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 udp import ( "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/iptables" "gvisor.dev/gvisor/pkg/tcpip/ports" "gvisor.dev/gvisor/pkg/tcpip/stack" "gvisor.dev/gvisor/pkg/waiter" ) // +stateify savable type udpPacket struct { udpPacketEntry senderAddress tcpip.FullAddress data buffer.VectorisedView `state:".(buffer.VectorisedView)"` timestamp int64 } // EndpointState represents the state of a UDP endpoint. type EndpointState uint32 // Endpoint states. Note that are represented in a netstack-specific manner and // may not be meaningful externally. Specifically, they need to be translated to // Linux's representation for these states if presented to userspace. const ( StateInitial EndpointState = iota StateBound StateConnected StateClosed ) // String implements fmt.Stringer.String. func (s EndpointState) String() string { switch s { case StateInitial: return "INITIAL" case StateBound: return "BOUND" case StateConnected: return "CONNECTING" case StateClosed: return "CLOSED" default: return "UNKNOWN" } } // endpoint represents a UDP endpoint. This struct serves as the interface // between users of the endpoint and the protocol implementation; it is legal to // have concurrent goroutines make calls into the endpoint, they are properly // synchronized. // // It implements tcpip.Endpoint. // // +stateify savable type endpoint struct { stack.TransportEndpointInfo // The following fields are initialized at creation time and do not // change throughout the lifetime of the endpoint. stack *stack.Stack `state:"manual"` waiterQueue *waiter.Queue uniqueID uint64 // The following fields are used to manage the receive queue, and are // protected by rcvMu. rcvMu sync.Mutex `state:"nosave"` rcvReady bool rcvList udpPacketList rcvBufSizeMax int `state:".(int)"` rcvBufSize int rcvClosed bool // The following fields are protected by the mu mutex. mu sync.RWMutex `state:"nosave"` sndBufSize int state EndpointState route stack.Route `state:"manual"` dstPort uint16 v6only bool ttl uint8 multicastTTL uint8 multicastAddr tcpip.Address multicastNICID tcpip.NICID multicastLoop bool reusePort bool bindToDevice tcpip.NICID broadcast bool // Values used to reserve a port or register a transport endpoint. // (which ever happens first). boundBindToDevice tcpip.NICID boundPortFlags ports.Flags // sendTOS represents IPv4 TOS or IPv6 TrafficClass, // applied while sending packets. Defaults to 0 as on Linux. sendTOS uint8 // shutdownFlags represent the current shutdown state of the endpoint. shutdownFlags tcpip.ShutdownFlags // multicastMemberships that need to be remvoed when the endpoint is // closed. Protected by the mu mutex. multicastMemberships []multicastMembership // effectiveNetProtos contains the network protocols actually in use. In // most cases it will only contain "netProto", but in cases like IPv6 // endpoints with v6only set to false, this could include multiple // protocols (e.g., IPv6 and IPv4) or a single different protocol (e.g., // IPv4 when IPv6 endpoint is bound or connected to an IPv4 mapped // address). effectiveNetProtos []tcpip.NetworkProtocolNumber // TODO(b/142022063): Add ability to save and restore per endpoint stats. stats tcpip.TransportEndpointStats `state:"nosave"` } // +stateify savable type multicastMembership struct { nicID tcpip.NICID multicastAddr tcpip.Address } func newEndpoint(s *stack.Stack, netProto tcpip.NetworkProtocolNumber, waiterQueue *waiter.Queue) *endpoint { return &endpoint{ stack: s, TransportEndpointInfo: stack.TransportEndpointInfo{ NetProto: netProto, TransProto: header.UDPProtocolNumber, }, waiterQueue: waiterQueue, // RFC 1075 section 5.4 recommends a TTL of 1 for membership // requests. // // RFC 5135 4.2.1 appears to assume that IGMP messages have a // TTL of 1. // // RFC 5135 Appendix A defines TTL=1: A multicast source that // wants its traffic to not traverse a router (e.g., leave a // home network) may find it useful to send traffic with IP // TTL=1. // // Linux defaults to TTL=1. multicastTTL: 1, multicastLoop: true, rcvBufSizeMax: 32 * 1024, sndBufSize: 32 * 1024, state: StateInitial, uniqueID: s.UniqueID(), } } // UniqueID implements stack.TransportEndpoint.UniqueID. func (e *endpoint) UniqueID() uint64 { return e.uniqueID } // Close puts the endpoint in a closed state and frees all resources // associated with it. func (e *endpoint) Close() { e.mu.Lock() e.shutdownFlags = tcpip.ShutdownRead | tcpip.ShutdownWrite switch e.state { case StateBound, StateConnected: e.stack.UnregisterTransportEndpoint(e.RegisterNICID, e.effectiveNetProtos, ProtocolNumber, e.ID, e, e.boundBindToDevice) e.stack.ReleasePort(e.effectiveNetProtos, ProtocolNumber, e.ID.LocalAddress, e.ID.LocalPort, e.boundPortFlags, e.boundBindToDevice) e.boundBindToDevice = 0 e.boundPortFlags = ports.Flags{} } for _, mem := range e.multicastMemberships { e.stack.LeaveGroup(e.NetProto, mem.nicID, mem.multicastAddr) } e.multicastMemberships = nil // Close the receive list and drain it. e.rcvMu.Lock() e.rcvClosed = true e.rcvBufSize = 0 for !e.rcvList.Empty() { p := e.rcvList.Front() e.rcvList.Remove(p) } e.rcvMu.Unlock() e.route.Release() // Update the state. e.state = StateClosed e.mu.Unlock() e.waiterQueue.Notify(waiter.EventHUp | waiter.EventErr | waiter.EventIn | waiter.EventOut) } // ModerateRecvBuf implements tcpip.Endpoint.ModerateRecvBuf. func (e *endpoint) ModerateRecvBuf(copied int) {} // IPTables implements tcpip.Endpoint.IPTables. func (e *endpoint) IPTables() (iptables.IPTables, error) { return e.stack.IPTables(), nil } // Read reads data from the endpoint. This method does not block if // there is no data pending. func (e *endpoint) Read(addr *tcpip.FullAddress) (buffer.View, tcpip.ControlMessages, *tcpip.Error) { e.rcvMu.Lock() if e.rcvList.Empty() { err := tcpip.ErrWouldBlock if e.rcvClosed { e.stats.ReadErrors.ReadClosed.Increment() err = tcpip.ErrClosedForReceive } e.rcvMu.Unlock() return buffer.View{}, tcpip.ControlMessages{}, err } p := e.rcvList.Front() e.rcvList.Remove(p) e.rcvBufSize -= p.data.Size() e.rcvMu.Unlock() if addr != nil { *addr = p.senderAddress } return p.data.ToView(), tcpip.ControlMessages{HasTimestamp: true, Timestamp: p.timestamp}, nil } // prepareForWrite prepares the endpoint for sending data. In particular, it // binds it if it's still in the initial state. To do so, it must first // reacquire the mutex in exclusive mode. // // Returns true for retry if preparation should be retried. func (e *endpoint) prepareForWrite(to *tcpip.FullAddress) (retry bool, err *tcpip.Error) { switch e.state { case StateInitial: case StateConnected: return false, nil case StateBound: if to == nil { return false, tcpip.ErrDestinationRequired } return false, nil default: return false, tcpip.ErrInvalidEndpointState } e.mu.RUnlock() defer e.mu.RLock() e.mu.Lock() defer e.mu.Unlock() // The state changed when we released the shared locked and re-acquired // it in exclusive mode. Try again. if e.state != StateInitial { return true, nil } // The state is still 'initial', so try to bind the endpoint. if err := e.bindLocked(tcpip.FullAddress{}); err != nil { return false, err } return true, nil } // connectRoute establishes a route to the specified interface or the // configured multicast interface if no interface is specified and the // specified address is a multicast address. func (e *endpoint) connectRoute(nicID tcpip.NICID, addr tcpip.FullAddress, netProto tcpip.NetworkProtocolNumber) (stack.Route, tcpip.NICID, *tcpip.Error) { localAddr := e.ID.LocalAddress if isBroadcastOrMulticast(localAddr) { // A packet can only originate from a unicast address (i.e., an interface). localAddr = "" } if header.IsV4MulticastAddress(addr.Addr) || header.IsV6MulticastAddress(addr.Addr) { if nicID == 0 { nicID = e.multicastNICID } if localAddr == "" && nicID == 0 { localAddr = e.multicastAddr } } // Find a route to the desired destination. r, err := e.stack.FindRoute(nicID, localAddr, addr.Addr, netProto, e.multicastLoop) if err != nil { return stack.Route{}, 0, err } return r, nicID, nil } // Write writes data to the endpoint's peer. This method does not block // if the data cannot be written. func (e *endpoint) Write(p tcpip.Payloader, opts tcpip.WriteOptions) (int64, <-chan struct{}, *tcpip.Error) { n, ch, err := e.write(p, opts) switch err { case nil: e.stats.PacketsSent.Increment() case tcpip.ErrMessageTooLong, tcpip.ErrInvalidOptionValue: e.stats.WriteErrors.InvalidArgs.Increment() case tcpip.ErrClosedForSend: e.stats.WriteErrors.WriteClosed.Increment() case tcpip.ErrInvalidEndpointState: e.stats.WriteErrors.InvalidEndpointState.Increment() case tcpip.ErrNoLinkAddress: e.stats.SendErrors.NoLinkAddr.Increment() case tcpip.ErrNoRoute, tcpip.ErrBroadcastDisabled, tcpip.ErrNetworkUnreachable: // Errors indicating any problem with IP routing of the packet. e.stats.SendErrors.NoRoute.Increment() default: // For all other errors when writing to the network layer. e.stats.SendErrors.SendToNetworkFailed.Increment() } return n, ch, err } func (e *endpoint) write(p tcpip.Payloader, opts tcpip.WriteOptions) (int64, <-chan struct{}, *tcpip.Error) { // MSG_MORE is unimplemented. (This also means that MSG_EOR is a no-op.) if opts.More { return 0, nil, tcpip.ErrInvalidOptionValue } to := opts.To e.mu.RLock() defer e.mu.RUnlock() // If we've shutdown with SHUT_WR we are in an invalid state for sending. if e.shutdownFlags&tcpip.ShutdownWrite != 0 { return 0, nil, tcpip.ErrClosedForSend } // Prepare for write. for { retry, err := e.prepareForWrite(to) if err != nil { return 0, nil, err } if !retry { break } } var route *stack.Route var dstPort uint16 if to == nil { route = &e.route dstPort = e.dstPort if route.IsResolutionRequired() { // Promote lock to exclusive if using a shared route, given that it may need to // change in Route.Resolve() call below. e.mu.RUnlock() defer e.mu.RLock() e.mu.Lock() defer e.mu.Unlock() // Recheck state after lock was re-acquired. if e.state != StateConnected { return 0, nil, tcpip.ErrInvalidEndpointState } } } else { // Reject destination address if it goes through a different // NIC than the endpoint was bound to. nicID := to.NIC if e.BindNICID != 0 { if nicID != 0 && nicID != e.BindNICID { return 0, nil, tcpip.ErrNoRoute } nicID = e.BindNICID } if to.Addr == header.IPv4Broadcast && !e.broadcast { return 0, nil, tcpip.ErrBroadcastDisabled } netProto, err := e.checkV4Mapped(to) if err != nil { return 0, nil, err } r, _, err := e.connectRoute(nicID, *to, netProto) if err != nil { return 0, nil, err } defer r.Release() route = &r dstPort = to.Port } if route.IsResolutionRequired() { if ch, err := route.Resolve(nil); err != nil { if err == tcpip.ErrWouldBlock { return 0, ch, tcpip.ErrNoLinkAddress } return 0, nil, err } } v, err := p.FullPayload() if err != nil { return 0, nil, err } if len(v) > header.UDPMaximumPacketSize { // Payload can't possibly fit in a packet. return 0, nil, tcpip.ErrMessageTooLong } ttl := e.ttl useDefaultTTL := ttl == 0 if header.IsV4MulticastAddress(route.RemoteAddress) || header.IsV6MulticastAddress(route.RemoteAddress) { ttl = e.multicastTTL // Multicast allows a 0 TTL. useDefaultTTL = false } if err := sendUDP(route, buffer.View(v).ToVectorisedView(), e.ID.LocalPort, dstPort, ttl, useDefaultTTL, e.sendTOS); err != nil { return 0, nil, err } return int64(len(v)), nil, nil } // Peek only returns data from a single datagram, so do nothing here. func (e *endpoint) Peek([][]byte) (int64, tcpip.ControlMessages, *tcpip.Error) { return 0, tcpip.ControlMessages{}, nil } // SetSockOptBool implements tcpip.Endpoint.SetSockOptBool. func (e *endpoint) SetSockOptBool(opt tcpip.SockOptBool, v bool) *tcpip.Error { switch opt { case tcpip.V6OnlyOption: // We only recognize this option on v6 endpoints. if e.NetProto != header.IPv6ProtocolNumber { return tcpip.ErrInvalidEndpointState } e.mu.Lock() defer e.mu.Unlock() // We only allow this to be set when we're in the initial state. if e.state != StateInitial { return tcpip.ErrInvalidEndpointState } e.v6only = v } return nil } // SetSockOptInt implements tcpip.Endpoint.SetSockOptInt. func (e *endpoint) SetSockOptInt(opt tcpip.SockOptInt, v int) *tcpip.Error { return nil } // SetSockOpt implements tcpip.Endpoint.SetSockOpt. func (e *endpoint) SetSockOpt(opt interface{}) *tcpip.Error { switch v := opt.(type) { case tcpip.TTLOption: e.mu.Lock() e.ttl = uint8(v) e.mu.Unlock() case tcpip.MulticastTTLOption: e.mu.Lock() e.multicastTTL = uint8(v) e.mu.Unlock() case tcpip.MulticastInterfaceOption: e.mu.Lock() defer e.mu.Unlock() fa := tcpip.FullAddress{Addr: v.InterfaceAddr} netProto, err := e.checkV4Mapped(&fa) if err != nil { return err } nic := v.NIC addr := fa.Addr if nic == 0 && addr == "" { e.multicastAddr = "" e.multicastNICID = 0 break } if nic != 0 { if !e.stack.CheckNIC(nic) { return tcpip.ErrBadLocalAddress } } else { nic = e.stack.CheckLocalAddress(0, netProto, addr) if nic == 0 { return tcpip.ErrBadLocalAddress } } if e.BindNICID != 0 && e.BindNICID != nic { return tcpip.ErrInvalidEndpointState } e.multicastNICID = nic e.multicastAddr = addr case tcpip.AddMembershipOption: if !header.IsV4MulticastAddress(v.MulticastAddr) && !header.IsV6MulticastAddress(v.MulticastAddr) { return tcpip.ErrInvalidOptionValue } nicID := v.NIC // The interface address is considered not-set if it is empty or contains // all-zeros. The former represent the zero-value in golang, the latter the // same in a setsockopt(IP_ADD_MEMBERSHIP, &ip_mreqn) syscall. allZeros := header.IPv4Any if len(v.InterfaceAddr) == 0 || v.InterfaceAddr == allZeros { if nicID == 0 { r, err := e.stack.FindRoute(0, "", v.MulticastAddr, header.IPv4ProtocolNumber, false /* multicastLoop */) if err == nil { nicID = r.NICID() r.Release() } } } else { nicID = e.stack.CheckLocalAddress(nicID, e.NetProto, v.InterfaceAddr) } if nicID == 0 { return tcpip.ErrUnknownDevice } memToInsert := multicastMembership{nicID: nicID, multicastAddr: v.MulticastAddr} e.mu.Lock() defer e.mu.Unlock() for _, mem := range e.multicastMemberships { if mem == memToInsert { return tcpip.ErrPortInUse } } if err := e.stack.JoinGroup(e.NetProto, nicID, v.MulticastAddr); err != nil { return err } e.multicastMemberships = append(e.multicastMemberships, memToInsert) case tcpip.RemoveMembershipOption: if !header.IsV4MulticastAddress(v.MulticastAddr) && !header.IsV6MulticastAddress(v.MulticastAddr) { return tcpip.ErrInvalidOptionValue } nicID := v.NIC if v.InterfaceAddr == header.IPv4Any { if nicID == 0 { r, err := e.stack.FindRoute(0, "", v.MulticastAddr, header.IPv4ProtocolNumber, false /* multicastLoop */) if err == nil { nicID = r.NICID() r.Release() } } } else { nicID = e.stack.CheckLocalAddress(nicID, e.NetProto, v.InterfaceAddr) } if nicID == 0 { return tcpip.ErrUnknownDevice } memToRemove := multicastMembership{nicID: nicID, multicastAddr: v.MulticastAddr} memToRemoveIndex := -1 e.mu.Lock() defer e.mu.Unlock() for i, mem := range e.multicastMemberships { if mem == memToRemove { memToRemoveIndex = i break } } if memToRemoveIndex == -1 { return tcpip.ErrBadLocalAddress } if err := e.stack.LeaveGroup(e.NetProto, nicID, v.MulticastAddr); err != nil { return err } e.multicastMemberships[memToRemoveIndex] = e.multicastMemberships[len(e.multicastMemberships)-1] e.multicastMemberships = e.multicastMemberships[:len(e.multicastMemberships)-1] case tcpip.MulticastLoopOption: e.mu.Lock() e.multicastLoop = bool(v) e.mu.Unlock() case tcpip.ReusePortOption: e.mu.Lock() e.reusePort = v != 0 e.mu.Unlock() case tcpip.BindToDeviceOption: id := tcpip.NICID(v) if id != 0 && !e.stack.HasNIC(id) { return tcpip.ErrUnknownDevice } e.mu.Lock() e.bindToDevice = id e.mu.Unlock() return nil case tcpip.BroadcastOption: e.mu.Lock() e.broadcast = v != 0 e.mu.Unlock() return nil case tcpip.IPv4TOSOption: e.mu.Lock() e.sendTOS = uint8(v) e.mu.Unlock() return nil case tcpip.IPv6TrafficClassOption: e.mu.Lock() e.sendTOS = uint8(v) e.mu.Unlock() return nil } return nil } // GetSockOptBool implements tcpip.Endpoint.GetSockOptBool. func (e *endpoint) GetSockOptBool(opt tcpip.SockOptBool) (bool, *tcpip.Error) { switch opt { case tcpip.V6OnlyOption: // We only recognize this option on v6 endpoints. if e.NetProto != header.IPv6ProtocolNumber { return false, tcpip.ErrUnknownProtocolOption } e.mu.Lock() v := e.v6only e.mu.Unlock() return v, nil } return false, tcpip.ErrUnknownProtocolOption } // GetSockOptInt implements tcpip.Endpoint.GetSockOptInt. func (e *endpoint) GetSockOptInt(opt tcpip.SockOptInt) (int, *tcpip.Error) { switch opt { case tcpip.ReceiveQueueSizeOption: v := 0 e.rcvMu.Lock() if !e.rcvList.Empty() { p := e.rcvList.Front() v = p.data.Size() } e.rcvMu.Unlock() return v, nil case tcpip.SendBufferSizeOption: e.mu.Lock() v := e.sndBufSize e.mu.Unlock() return v, nil case tcpip.ReceiveBufferSizeOption: e.rcvMu.Lock() v := e.rcvBufSizeMax e.rcvMu.Unlock() return v, nil } return -1, tcpip.ErrUnknownProtocolOption } // GetSockOpt implements tcpip.Endpoint.GetSockOpt. func (e *endpoint) GetSockOpt(opt interface{}) *tcpip.Error { switch o := opt.(type) { case tcpip.ErrorOption: return nil case *tcpip.TTLOption: e.mu.Lock() *o = tcpip.TTLOption(e.ttl) e.mu.Unlock() return nil case *tcpip.MulticastTTLOption: e.mu.Lock() *o = tcpip.MulticastTTLOption(e.multicastTTL) e.mu.Unlock() return nil case *tcpip.MulticastInterfaceOption: e.mu.Lock() *o = tcpip.MulticastInterfaceOption{ e.multicastNICID, e.multicastAddr, } e.mu.Unlock() return nil case *tcpip.MulticastLoopOption: e.mu.RLock() v := e.multicastLoop e.mu.RUnlock() *o = tcpip.MulticastLoopOption(v) return nil case *tcpip.ReuseAddressOption: *o = 0 return nil case *tcpip.ReusePortOption: e.mu.RLock() v := e.reusePort e.mu.RUnlock() *o = 0 if v { *o = 1 } return nil case *tcpip.BindToDeviceOption: e.mu.RLock() *o = tcpip.BindToDeviceOption(e.bindToDevice) e.mu.RUnlock() return nil case *tcpip.KeepaliveEnabledOption: *o = 0 return nil case *tcpip.BroadcastOption: e.mu.RLock() v := e.broadcast e.mu.RUnlock() *o = 0 if v { *o = 1 } return nil case *tcpip.IPv4TOSOption: e.mu.RLock() *o = tcpip.IPv4TOSOption(e.sendTOS) e.mu.RUnlock() return nil case *tcpip.IPv6TrafficClassOption: e.mu.RLock() *o = tcpip.IPv6TrafficClassOption(e.sendTOS) e.mu.RUnlock() return nil default: return tcpip.ErrUnknownProtocolOption } } // sendUDP sends a UDP segment via the provided network endpoint and under the // provided identity. func sendUDP(r *stack.Route, data buffer.VectorisedView, localPort, remotePort uint16, ttl uint8, useDefaultTTL bool, tos uint8) *tcpip.Error { // Allocate a buffer for the UDP header. hdr := buffer.NewPrependable(header.UDPMinimumSize + int(r.MaxHeaderLength())) // Initialize the header. udp := header.UDP(hdr.Prepend(header.UDPMinimumSize)) length := uint16(hdr.UsedLength() + data.Size()) udp.Encode(&header.UDPFields{ SrcPort: localPort, DstPort: remotePort, Length: length, }) // Only calculate the checksum if offloading isn't supported. if r.Capabilities()&stack.CapabilityTXChecksumOffload == 0 { xsum := r.PseudoHeaderChecksum(ProtocolNumber, length) for _, v := range data.Views() { xsum = header.Checksum(v, xsum) } udp.SetChecksum(^udp.CalculateChecksum(xsum)) } if useDefaultTTL { ttl = r.DefaultTTL() } if err := r.WritePacket(nil /* gso */, stack.NetworkHeaderParams{Protocol: ProtocolNumber, TTL: ttl, TOS: tos}, tcpip.PacketBuffer{ Header: hdr, Data: data, TransportHeader: buffer.View(udp), }); err != nil { r.Stats().UDP.PacketSendErrors.Increment() return err } // Track count of packets sent. r.Stats().UDP.PacketsSent.Increment() return nil } func (e *endpoint) checkV4Mapped(addr *tcpip.FullAddress) (tcpip.NetworkProtocolNumber, *tcpip.Error) { unwrapped, netProto, err := e.TransportEndpointInfo.AddrNetProto(*addr, e.v6only) if err != nil { return 0, err } *addr = unwrapped return netProto, nil } // Disconnect implements tcpip.Endpoint.Disconnect. func (e *endpoint) Disconnect() *tcpip.Error { e.mu.Lock() defer e.mu.Unlock() if e.state != StateConnected { return nil } var ( id stack.TransportEndpointID btd tcpip.NICID ) // Exclude ephemerally bound endpoints. if e.BindNICID != 0 || e.ID.LocalAddress == "" { var err *tcpip.Error id = stack.TransportEndpointID{ LocalPort: e.ID.LocalPort, LocalAddress: e.ID.LocalAddress, } id, btd, err = e.registerWithStack(e.RegisterNICID, e.effectiveNetProtos, id) if err != nil { return err } e.state = StateBound } else { if e.ID.LocalPort != 0 { // Release the ephemeral port. e.stack.ReleasePort(e.effectiveNetProtos, ProtocolNumber, e.ID.LocalAddress, e.ID.LocalPort, e.boundPortFlags, e.boundBindToDevice) e.boundPortFlags = ports.Flags{} } e.state = StateInitial } e.stack.UnregisterTransportEndpoint(e.RegisterNICID, e.effectiveNetProtos, ProtocolNumber, e.ID, e, e.boundBindToDevice) e.ID = id e.boundBindToDevice = btd e.route.Release() e.route = stack.Route{} e.dstPort = 0 return nil } // Connect connects the endpoint to its peer. Specifying a NIC is optional. func (e *endpoint) Connect(addr tcpip.FullAddress) *tcpip.Error { netProto, err := e.checkV4Mapped(&addr) if err != nil { return err } if addr.Port == 0 { // We don't support connecting to port zero. return tcpip.ErrInvalidEndpointState } e.mu.Lock() defer e.mu.Unlock() nicID := addr.NIC var localPort uint16 switch e.state { case StateInitial: case StateBound, StateConnected: localPort = e.ID.LocalPort if e.BindNICID == 0 { break } if nicID != 0 && nicID != e.BindNICID { return tcpip.ErrInvalidEndpointState } nicID = e.BindNICID default: return tcpip.ErrInvalidEndpointState } r, nicID, err := e.connectRoute(nicID, addr, netProto) if err != nil { return err } defer r.Release() id := stack.TransportEndpointID{ LocalAddress: e.ID.LocalAddress, LocalPort: localPort, RemotePort: addr.Port, RemoteAddress: r.RemoteAddress, } if e.state == StateInitial { id.LocalAddress = r.LocalAddress } // Even if we're connected, this endpoint can still be used to send // packets on a different network protocol, so we register both even if // v6only is set to false and this is an ipv6 endpoint. netProtos := []tcpip.NetworkProtocolNumber{netProto} if netProto == header.IPv6ProtocolNumber && !e.v6only { netProtos = []tcpip.NetworkProtocolNumber{ header.IPv4ProtocolNumber, header.IPv6ProtocolNumber, } } id, btd, err := e.registerWithStack(nicID, netProtos, id) if err != nil { return err } // Remove the old registration. if e.ID.LocalPort != 0 { e.stack.UnregisterTransportEndpoint(e.RegisterNICID, e.effectiveNetProtos, ProtocolNumber, e.ID, e, e.boundBindToDevice) } e.ID = id e.boundBindToDevice = btd e.route = r.Clone() e.dstPort = addr.Port e.RegisterNICID = nicID e.effectiveNetProtos = netProtos e.state = StateConnected e.rcvMu.Lock() e.rcvReady = true e.rcvMu.Unlock() return nil } // ConnectEndpoint is not supported. func (*endpoint) ConnectEndpoint(tcpip.Endpoint) *tcpip.Error { return tcpip.ErrInvalidEndpointState } // Shutdown closes the read and/or write end of the endpoint connection // to its peer. func (e *endpoint) Shutdown(flags tcpip.ShutdownFlags) *tcpip.Error { e.mu.Lock() defer e.mu.Unlock() // A socket in the bound state can still receive multicast messages, // so we need to notify waiters on shutdown. if e.state != StateBound && e.state != StateConnected { return tcpip.ErrNotConnected } e.shutdownFlags |= flags if flags&tcpip.ShutdownRead != 0 { e.rcvMu.Lock() wasClosed := e.rcvClosed e.rcvClosed = true e.rcvMu.Unlock() if !wasClosed { e.waiterQueue.Notify(waiter.EventIn) } } return nil } // Listen is not supported by UDP, it just fails. func (*endpoint) Listen(int) *tcpip.Error { return tcpip.ErrNotSupported } // Accept is not supported by UDP, it just fails. func (*endpoint) Accept() (tcpip.Endpoint, *waiter.Queue, *tcpip.Error) { return nil, nil, tcpip.ErrNotSupported } func (e *endpoint) registerWithStack(nicID tcpip.NICID, netProtos []tcpip.NetworkProtocolNumber, id stack.TransportEndpointID) (stack.TransportEndpointID, tcpip.NICID, *tcpip.Error) { if e.ID.LocalPort == 0 { flags := ports.Flags{ LoadBalanced: e.reusePort, // FIXME(b/129164367): Support SO_REUSEADDR. MostRecent: false, } port, err := e.stack.ReservePort(netProtos, ProtocolNumber, id.LocalAddress, id.LocalPort, flags, e.bindToDevice) if err != nil { return id, e.bindToDevice, err } e.boundPortFlags = flags id.LocalPort = port } err := e.stack.RegisterTransportEndpoint(nicID, netProtos, ProtocolNumber, id, e, e.reusePort, e.bindToDevice) if err != nil { e.stack.ReleasePort(netProtos, ProtocolNumber, id.LocalAddress, id.LocalPort, e.boundPortFlags, e.bindToDevice) e.boundPortFlags = ports.Flags{} } return id, e.bindToDevice, err } func (e *endpoint) bindLocked(addr tcpip.FullAddress) *tcpip.Error { // Don't allow binding once endpoint is not in the initial state // anymore. if e.state != StateInitial { return tcpip.ErrInvalidEndpointState } netProto, err := e.checkV4Mapped(&addr) if err != nil { return err } // Expand netProtos to include v4 and v6 if the caller is binding to a // wildcard (empty) address, and this is an IPv6 endpoint with v6only // set to false. netProtos := []tcpip.NetworkProtocolNumber{netProto} if netProto == header.IPv6ProtocolNumber && !e.v6only && addr.Addr == "" { netProtos = []tcpip.NetworkProtocolNumber{ header.IPv6ProtocolNumber, header.IPv4ProtocolNumber, } } nicID := addr.NIC if len(addr.Addr) != 0 && !isBroadcastOrMulticast(addr.Addr) { // A local unicast address was specified, verify that it's valid. nicID = e.stack.CheckLocalAddress(addr.NIC, netProto, addr.Addr) if nicID == 0 { return tcpip.ErrBadLocalAddress } } id := stack.TransportEndpointID{ LocalPort: addr.Port, LocalAddress: addr.Addr, } id, btd, err := e.registerWithStack(nicID, netProtos, id) if err != nil { return err } e.ID = id e.boundBindToDevice = btd e.RegisterNICID = nicID e.effectiveNetProtos = netProtos // Mark endpoint as bound. e.state = StateBound e.rcvMu.Lock() e.rcvReady = true e.rcvMu.Unlock() return nil } // Bind binds the endpoint to a specific local address and port. // Specifying a NIC is optional. func (e *endpoint) Bind(addr tcpip.FullAddress) *tcpip.Error { e.mu.Lock() defer e.mu.Unlock() err := e.bindLocked(addr) if err != nil { return err } // Save the effective NICID generated by bindLocked. e.BindNICID = e.RegisterNICID return nil } // GetLocalAddress returns the address to which the endpoint is bound. func (e *endpoint) GetLocalAddress() (tcpip.FullAddress, *tcpip.Error) { e.mu.RLock() defer e.mu.RUnlock() addr := e.ID.LocalAddress if e.state == StateConnected { addr = e.route.LocalAddress } return tcpip.FullAddress{ NIC: e.RegisterNICID, Addr: addr, Port: e.ID.LocalPort, }, nil } // GetRemoteAddress returns the address to which the endpoint is connected. func (e *endpoint) GetRemoteAddress() (tcpip.FullAddress, *tcpip.Error) { e.mu.RLock() defer e.mu.RUnlock() if e.state != StateConnected { return tcpip.FullAddress{}, tcpip.ErrNotConnected } return tcpip.FullAddress{ NIC: e.RegisterNICID, Addr: e.ID.RemoteAddress, Port: e.ID.RemotePort, }, nil } // Readiness returns the current readiness of the endpoint. For example, if // waiter.EventIn is set, the endpoint is immediately readable. func (e *endpoint) Readiness(mask waiter.EventMask) waiter.EventMask { // The endpoint is always writable. result := waiter.EventOut & mask // Determine if the endpoint is readable if requested. if (mask & waiter.EventIn) != 0 { e.rcvMu.Lock() if !e.rcvList.Empty() || e.rcvClosed { result |= waiter.EventIn } e.rcvMu.Unlock() } return result } // HandlePacket is called by the stack when new packets arrive to this transport // endpoint. func (e *endpoint) HandlePacket(r *stack.Route, id stack.TransportEndpointID, pkt tcpip.PacketBuffer) { // Get the header then trim it from the view. hdr := header.UDP(pkt.Data.First()) if int(hdr.Length()) > pkt.Data.Size() { // Malformed packet. e.stack.Stats().UDP.MalformedPacketsReceived.Increment() e.stats.ReceiveErrors.MalformedPacketsReceived.Increment() return } pkt.Data.TrimFront(header.UDPMinimumSize) e.rcvMu.Lock() e.stack.Stats().UDP.PacketsReceived.Increment() e.stats.PacketsReceived.Increment() // Drop the packet if our buffer is currently full. if !e.rcvReady || e.rcvClosed { e.rcvMu.Unlock() e.stack.Stats().UDP.ReceiveBufferErrors.Increment() e.stats.ReceiveErrors.ClosedReceiver.Increment() return } if e.rcvBufSize >= e.rcvBufSizeMax { e.rcvMu.Unlock() e.stack.Stats().UDP.ReceiveBufferErrors.Increment() e.stats.ReceiveErrors.ReceiveBufferOverflow.Increment() return } wasEmpty := e.rcvBufSize == 0 // Push new packet into receive list and increment the buffer size. packet := &udpPacket{ senderAddress: tcpip.FullAddress{ NIC: r.NICID(), Addr: id.RemoteAddress, Port: hdr.SourcePort(), }, } packet.data = pkt.Data e.rcvList.PushBack(packet) e.rcvBufSize += pkt.Data.Size() packet.timestamp = e.stack.NowNanoseconds() e.rcvMu.Unlock() // Notify any waiters that there's data to be read now. if wasEmpty { e.waiterQueue.Notify(waiter.EventIn) } } // HandleControlPacket implements stack.TransportEndpoint.HandleControlPacket. func (e *endpoint) HandleControlPacket(id stack.TransportEndpointID, typ stack.ControlType, extra uint32, pkt tcpip.PacketBuffer) { } // State implements tcpip.Endpoint.State. func (e *endpoint) State() uint32 { e.mu.Lock() defer e.mu.Unlock() return uint32(e.state) } // Info returns a copy of the endpoint info. func (e *endpoint) Info() tcpip.EndpointInfo { e.mu.RLock() // Make a copy of the endpoint info. ret := e.TransportEndpointInfo e.mu.RUnlock() return &ret } // Stats returns a pointer to the endpoint stats. func (e *endpoint) Stats() tcpip.EndpointStats { return &e.stats } // Wait implements tcpip.Endpoint.Wait. func (*endpoint) Wait() {} func isBroadcastOrMulticast(a tcpip.Address) bool { return a == header.IPv4Broadcast || header.IsV4MulticastAddress(a) || header.IsV6MulticastAddress(a) }