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|
// 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 stack
import (
"fmt"
"math/rand"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/hash/jenkins"
"gvisor.dev/gvisor/pkg/tcpip/header"
"gvisor.dev/gvisor/pkg/tcpip/ports"
)
type protocolIDs struct {
network tcpip.NetworkProtocolNumber
transport tcpip.TransportProtocolNumber
}
// transportEndpoints manages all endpoints of a given protocol. It has its own
// mutex so as to reduce interference between protocols.
type transportEndpoints struct {
// mu protects all fields of the transportEndpoints.
mu sync.RWMutex
endpoints map[TransportEndpointID]*endpointsByNIC
// rawEndpoints contains endpoints for raw sockets, which receive all
// traffic of a given protocol regardless of port.
rawEndpoints []RawTransportEndpoint
}
// unregisterEndpoint unregisters the endpoint with the given id such that it
// won't receive any more packets.
func (eps *transportEndpoints) unregisterEndpoint(id TransportEndpointID, ep TransportEndpoint, flags ports.Flags, bindToDevice tcpip.NICID) {
eps.mu.Lock()
defer eps.mu.Unlock()
epsByNIC, ok := eps.endpoints[id]
if !ok {
return
}
if !epsByNIC.unregisterEndpoint(bindToDevice, ep, flags) {
return
}
delete(eps.endpoints, id)
}
func (eps *transportEndpoints) transportEndpoints() []TransportEndpoint {
eps.mu.RLock()
defer eps.mu.RUnlock()
es := make([]TransportEndpoint, 0, len(eps.endpoints))
for _, e := range eps.endpoints {
es = append(es, e.transportEndpoints()...)
}
return es
}
// iterEndpointsLocked yields all endpointsByNIC in eps that match id, in
// descending order of match quality. If a call to yield returns false,
// iterEndpointsLocked stops iteration and returns immediately.
//
// Preconditions: eps.mu must be locked.
func (eps *transportEndpoints) iterEndpointsLocked(id TransportEndpointID, yield func(*endpointsByNIC) bool) {
// Try to find a match with the id as provided.
if ep, ok := eps.endpoints[id]; ok {
if !yield(ep) {
return
}
}
// Try to find a match with the id minus the local address.
nid := id
nid.LocalAddress = ""
if ep, ok := eps.endpoints[nid]; ok {
if !yield(ep) {
return
}
}
// Try to find a match with the id minus the remote part.
nid.LocalAddress = id.LocalAddress
nid.RemoteAddress = ""
nid.RemotePort = 0
if ep, ok := eps.endpoints[nid]; ok {
if !yield(ep) {
return
}
}
// Try to find a match with only the local port.
nid.LocalAddress = ""
if ep, ok := eps.endpoints[nid]; ok {
if !yield(ep) {
return
}
}
}
// findAllEndpointsLocked returns all endpointsByNIC in eps that match id, in
// descending order of match quality.
//
// Preconditions: eps.mu must be locked.
func (eps *transportEndpoints) findAllEndpointsLocked(id TransportEndpointID) []*endpointsByNIC {
var matchedEPs []*endpointsByNIC
eps.iterEndpointsLocked(id, func(ep *endpointsByNIC) bool {
matchedEPs = append(matchedEPs, ep)
return true
})
return matchedEPs
}
// findEndpointLocked returns the endpoint that most closely matches the given id.
//
// Preconditions: eps.mu must be locked.
func (eps *transportEndpoints) findEndpointLocked(id TransportEndpointID) *endpointsByNIC {
var matchedEP *endpointsByNIC
eps.iterEndpointsLocked(id, func(ep *endpointsByNIC) bool {
matchedEP = ep
return false
})
return matchedEP
}
type endpointsByNIC struct {
mu sync.RWMutex
endpoints map[tcpip.NICID]*multiPortEndpoint
// seed is a random secret for a jenkins hash.
seed uint32
}
func (epsByNIC *endpointsByNIC) transportEndpoints() []TransportEndpoint {
epsByNIC.mu.RLock()
defer epsByNIC.mu.RUnlock()
var eps []TransportEndpoint
for _, ep := range epsByNIC.endpoints {
eps = append(eps, ep.transportEndpoints()...)
}
return eps
}
// HandlePacket is called by the stack when new packets arrive to this transport
// endpoint.
func (epsByNIC *endpointsByNIC) handlePacket(r *Route, id TransportEndpointID, pkt *PacketBuffer) {
epsByNIC.mu.RLock()
mpep, ok := epsByNIC.endpoints[r.nic.ID()]
if !ok {
if mpep, ok = epsByNIC.endpoints[0]; !ok {
epsByNIC.mu.RUnlock() // Don't use defer for performance reasons.
return
}
}
// If this is a broadcast or multicast datagram, deliver the datagram to all
// endpoints bound to the right device.
if isInboundMulticastOrBroadcast(r) {
mpep.handlePacketAll(r, id, pkt)
epsByNIC.mu.RUnlock() // Don't use defer for performance reasons.
return
}
// multiPortEndpoints are guaranteed to have at least one element.
transEP := selectEndpoint(id, mpep, epsByNIC.seed)
if queuedProtocol, mustQueue := mpep.demux.queuedProtocols[protocolIDs{mpep.netProto, mpep.transProto}]; mustQueue {
queuedProtocol.QueuePacket(r, transEP, id, pkt)
epsByNIC.mu.RUnlock()
return
}
transEP.HandlePacket(r, id, pkt)
epsByNIC.mu.RUnlock() // Don't use defer for performance reasons.
}
// HandleControlPacket implements stack.TransportEndpoint.HandleControlPacket.
func (epsByNIC *endpointsByNIC) handleControlPacket(n *NIC, id TransportEndpointID, typ ControlType, extra uint32, pkt *PacketBuffer) {
epsByNIC.mu.RLock()
defer epsByNIC.mu.RUnlock()
mpep, ok := epsByNIC.endpoints[n.ID()]
if !ok {
mpep, ok = epsByNIC.endpoints[0]
}
if !ok {
return
}
// TODO(eyalsoha): Why don't we look at id to see if this packet needs to
// broadcast like we are doing with handlePacket above?
// multiPortEndpoints are guaranteed to have at least one element.
selectEndpoint(id, mpep, epsByNIC.seed).HandleControlPacket(id, typ, extra, pkt)
}
// registerEndpoint returns true if it succeeds. It fails and returns
// false if ep already has an element with the same key.
func (epsByNIC *endpointsByNIC) registerEndpoint(d *transportDemuxer, netProto tcpip.NetworkProtocolNumber, transProto tcpip.TransportProtocolNumber, t TransportEndpoint, flags ports.Flags, bindToDevice tcpip.NICID) *tcpip.Error {
epsByNIC.mu.Lock()
defer epsByNIC.mu.Unlock()
multiPortEp, ok := epsByNIC.endpoints[bindToDevice]
if !ok {
multiPortEp = &multiPortEndpoint{
demux: d,
netProto: netProto,
transProto: transProto,
}
epsByNIC.endpoints[bindToDevice] = multiPortEp
}
return multiPortEp.singleRegisterEndpoint(t, flags)
}
func (epsByNIC *endpointsByNIC) checkEndpoint(d *transportDemuxer, netProto tcpip.NetworkProtocolNumber, transProto tcpip.TransportProtocolNumber, flags ports.Flags, bindToDevice tcpip.NICID) *tcpip.Error {
epsByNIC.mu.RLock()
defer epsByNIC.mu.RUnlock()
multiPortEp, ok := epsByNIC.endpoints[bindToDevice]
if !ok {
return nil
}
return multiPortEp.singleCheckEndpoint(flags)
}
// unregisterEndpoint returns true if endpointsByNIC has to be unregistered.
func (epsByNIC *endpointsByNIC) unregisterEndpoint(bindToDevice tcpip.NICID, t TransportEndpoint, flags ports.Flags) bool {
epsByNIC.mu.Lock()
defer epsByNIC.mu.Unlock()
multiPortEp, ok := epsByNIC.endpoints[bindToDevice]
if !ok {
return false
}
if multiPortEp.unregisterEndpoint(t, flags) {
delete(epsByNIC.endpoints, bindToDevice)
}
return len(epsByNIC.endpoints) == 0
}
// transportDemuxer demultiplexes packets targeted at a transport endpoint
// (i.e., after they've been parsed by the network layer). It does two levels
// of demultiplexing: first based on the network and transport protocols, then
// based on endpoints IDs. It should only be instantiated via
// newTransportDemuxer.
type transportDemuxer struct {
// protocol is immutable.
protocol map[protocolIDs]*transportEndpoints
queuedProtocols map[protocolIDs]queuedTransportProtocol
}
// queuedTransportProtocol if supported by a protocol implementation will cause
// the dispatcher to delivery packets to the QueuePacket method instead of
// calling HandlePacket directly on the endpoint.
type queuedTransportProtocol interface {
QueuePacket(r *Route, ep TransportEndpoint, id TransportEndpointID, pkt *PacketBuffer)
}
func newTransportDemuxer(stack *Stack) *transportDemuxer {
d := &transportDemuxer{
protocol: make(map[protocolIDs]*transportEndpoints),
queuedProtocols: make(map[protocolIDs]queuedTransportProtocol),
}
// Add each network and transport pair to the demuxer.
for netProto := range stack.networkProtocols {
for proto := range stack.transportProtocols {
protoIDs := protocolIDs{netProto, proto}
d.protocol[protoIDs] = &transportEndpoints{
endpoints: make(map[TransportEndpointID]*endpointsByNIC),
}
qTransProto, isQueued := (stack.transportProtocols[proto].proto).(queuedTransportProtocol)
if isQueued {
d.queuedProtocols[protoIDs] = qTransProto
}
}
}
return d
}
// registerEndpoint registers the given endpoint with the dispatcher such that
// packets that match the endpoint ID are delivered to it.
func (d *transportDemuxer) registerEndpoint(netProtos []tcpip.NetworkProtocolNumber, protocol tcpip.TransportProtocolNumber, id TransportEndpointID, ep TransportEndpoint, flags ports.Flags, bindToDevice tcpip.NICID) *tcpip.Error {
for i, n := range netProtos {
if err := d.singleRegisterEndpoint(n, protocol, id, ep, flags, bindToDevice); err != nil {
d.unregisterEndpoint(netProtos[:i], protocol, id, ep, flags, bindToDevice)
return err
}
}
return nil
}
// checkEndpoint checks if an endpoint can be registered with the dispatcher.
func (d *transportDemuxer) checkEndpoint(netProtos []tcpip.NetworkProtocolNumber, protocol tcpip.TransportProtocolNumber, id TransportEndpointID, flags ports.Flags, bindToDevice tcpip.NICID) *tcpip.Error {
for _, n := range netProtos {
if err := d.singleCheckEndpoint(n, protocol, id, flags, bindToDevice); err != nil {
return err
}
}
return nil
}
// multiPortEndpoint is a container for TransportEndpoints which are bound to
// the same pair of address and port. endpointsArr always has at least one
// element.
//
// FIXME(gvisor.dev/issue/873): Restore this properly. Currently, we just save
// this to ensure that the underlying endpoints get saved/restored, but not not
// use the restored copy.
//
// +stateify savable
type multiPortEndpoint struct {
mu sync.RWMutex `state:"nosave"`
demux *transportDemuxer
netProto tcpip.NetworkProtocolNumber
transProto tcpip.TransportProtocolNumber
// endpoints stores the transport endpoints in the order in which they
// were bound. This is required for UDP SO_REUSEADDR.
endpoints []TransportEndpoint
flags ports.FlagCounter
}
func (ep *multiPortEndpoint) transportEndpoints() []TransportEndpoint {
ep.mu.RLock()
eps := append([]TransportEndpoint(nil), ep.endpoints...)
ep.mu.RUnlock()
return eps
}
// reciprocalScale scales a value into range [0, n).
//
// This is similar to val % n, but faster.
// See http://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
func reciprocalScale(val, n uint32) uint32 {
return uint32((uint64(val) * uint64(n)) >> 32)
}
// selectEndpoint calculates a hash of destination and source addresses and
// ports then uses it to select a socket. In this case, all packets from one
// address will be sent to same endpoint.
func selectEndpoint(id TransportEndpointID, mpep *multiPortEndpoint, seed uint32) TransportEndpoint {
if len(mpep.endpoints) == 1 {
return mpep.endpoints[0]
}
if mpep.flags.IntersectionRefs().ToFlags().Effective().MostRecent {
return mpep.endpoints[len(mpep.endpoints)-1]
}
payload := []byte{
byte(id.LocalPort),
byte(id.LocalPort >> 8),
byte(id.RemotePort),
byte(id.RemotePort >> 8),
}
h := jenkins.Sum32(seed)
h.Write(payload)
h.Write([]byte(id.LocalAddress))
h.Write([]byte(id.RemoteAddress))
hash := h.Sum32()
idx := reciprocalScale(hash, uint32(len(mpep.endpoints)))
return mpep.endpoints[idx]
}
func (ep *multiPortEndpoint) handlePacketAll(r *Route, id TransportEndpointID, pkt *PacketBuffer) {
ep.mu.RLock()
queuedProtocol, mustQueue := ep.demux.queuedProtocols[protocolIDs{ep.netProto, ep.transProto}]
// HandlePacket takes ownership of pkt, so each endpoint needs
// its own copy except for the final one.
for _, endpoint := range ep.endpoints[:len(ep.endpoints)-1] {
if mustQueue {
queuedProtocol.QueuePacket(r, endpoint, id, pkt.Clone())
} else {
endpoint.HandlePacket(r, id, pkt.Clone())
}
}
if endpoint := ep.endpoints[len(ep.endpoints)-1]; mustQueue {
queuedProtocol.QueuePacket(r, endpoint, id, pkt)
} else {
endpoint.HandlePacket(r, id, pkt)
}
ep.mu.RUnlock() // Don't use defer for performance reasons.
}
// singleRegisterEndpoint tries to add an endpoint to the multiPortEndpoint
// list. The list might be empty already.
func (ep *multiPortEndpoint) singleRegisterEndpoint(t TransportEndpoint, flags ports.Flags) *tcpip.Error {
ep.mu.Lock()
defer ep.mu.Unlock()
bits := flags.Bits() & ports.MultiBindFlagMask
if len(ep.endpoints) != 0 {
// If it was previously bound, we need to check if we can bind again.
if ep.flags.TotalRefs() > 0 && bits&ep.flags.IntersectionRefs() == 0 {
return tcpip.ErrPortInUse
}
}
ep.endpoints = append(ep.endpoints, t)
ep.flags.AddRef(bits)
return nil
}
func (ep *multiPortEndpoint) singleCheckEndpoint(flags ports.Flags) *tcpip.Error {
ep.mu.RLock()
defer ep.mu.RUnlock()
bits := flags.Bits() & ports.MultiBindFlagMask
if len(ep.endpoints) != 0 {
// If it was previously bound, we need to check if we can bind again.
if ep.flags.TotalRefs() > 0 && bits&ep.flags.IntersectionRefs() == 0 {
return tcpip.ErrPortInUse
}
}
return nil
}
// unregisterEndpoint returns true if multiPortEndpoint has to be unregistered.
func (ep *multiPortEndpoint) unregisterEndpoint(t TransportEndpoint, flags ports.Flags) bool {
ep.mu.Lock()
defer ep.mu.Unlock()
for i, endpoint := range ep.endpoints {
if endpoint == t {
copy(ep.endpoints[i:], ep.endpoints[i+1:])
ep.endpoints[len(ep.endpoints)-1] = nil
ep.endpoints = ep.endpoints[:len(ep.endpoints)-1]
ep.flags.DropRef(flags.Bits() & ports.MultiBindFlagMask)
break
}
}
return len(ep.endpoints) == 0
}
func (d *transportDemuxer) singleRegisterEndpoint(netProto tcpip.NetworkProtocolNumber, protocol tcpip.TransportProtocolNumber, id TransportEndpointID, ep TransportEndpoint, flags ports.Flags, bindToDevice tcpip.NICID) *tcpip.Error {
if id.RemotePort != 0 {
// SO_REUSEPORT only applies to bound/listening endpoints.
flags.LoadBalanced = false
}
eps, ok := d.protocol[protocolIDs{netProto, protocol}]
if !ok {
return tcpip.ErrUnknownProtocol
}
eps.mu.Lock()
defer eps.mu.Unlock()
epsByNIC, ok := eps.endpoints[id]
if !ok {
epsByNIC = &endpointsByNIC{
endpoints: make(map[tcpip.NICID]*multiPortEndpoint),
seed: rand.Uint32(),
}
eps.endpoints[id] = epsByNIC
}
return epsByNIC.registerEndpoint(d, netProto, protocol, ep, flags, bindToDevice)
}
func (d *transportDemuxer) singleCheckEndpoint(netProto tcpip.NetworkProtocolNumber, protocol tcpip.TransportProtocolNumber, id TransportEndpointID, flags ports.Flags, bindToDevice tcpip.NICID) *tcpip.Error {
if id.RemotePort != 0 {
// SO_REUSEPORT only applies to bound/listening endpoints.
flags.LoadBalanced = false
}
eps, ok := d.protocol[protocolIDs{netProto, protocol}]
if !ok {
return tcpip.ErrUnknownProtocol
}
eps.mu.RLock()
defer eps.mu.RUnlock()
epsByNIC, ok := eps.endpoints[id]
if !ok {
return nil
}
return epsByNIC.checkEndpoint(d, netProto, protocol, flags, bindToDevice)
}
// unregisterEndpoint unregisters the endpoint with the given id such that it
// won't receive any more packets.
func (d *transportDemuxer) unregisterEndpoint(netProtos []tcpip.NetworkProtocolNumber, protocol tcpip.TransportProtocolNumber, id TransportEndpointID, ep TransportEndpoint, flags ports.Flags, bindToDevice tcpip.NICID) {
if id.RemotePort != 0 {
// SO_REUSEPORT only applies to bound/listening endpoints.
flags.LoadBalanced = false
}
for _, n := range netProtos {
if eps, ok := d.protocol[protocolIDs{n, protocol}]; ok {
eps.unregisterEndpoint(id, ep, flags, bindToDevice)
}
}
}
// deliverPacket attempts to find one or more matching transport endpoints, and
// then, if matches are found, delivers the packet to them. Returns true if
// the packet no longer needs to be handled.
func (d *transportDemuxer) deliverPacket(r *Route, protocol tcpip.TransportProtocolNumber, pkt *PacketBuffer, id TransportEndpointID) bool {
eps, ok := d.protocol[protocolIDs{r.NetProto, protocol}]
if !ok {
return false
}
// If the packet is a UDP broadcast or multicast, then find all matching
// transport endpoints.
if protocol == header.UDPProtocolNumber && isInboundMulticastOrBroadcast(r) {
eps.mu.RLock()
destEPs := eps.findAllEndpointsLocked(id)
eps.mu.RUnlock()
// Fail if we didn't find at least one matching transport endpoint.
if len(destEPs) == 0 {
r.Stats().UDP.UnknownPortErrors.Increment()
return false
}
// handlePacket takes ownership of pkt, so each endpoint needs its own
// copy except for the final one.
for _, ep := range destEPs[:len(destEPs)-1] {
ep.handlePacket(r, id, pkt.Clone())
}
destEPs[len(destEPs)-1].handlePacket(r, id, pkt)
return true
}
// If the packet is a TCP packet with a unspecified source or non-unicast
// destination address, then do nothing further and instruct the caller to do
// the same. The network layer handles address validation for specified source
// addresses.
if protocol == header.TCPProtocolNumber && (!isSpecified(r.LocalAddress) || !isSpecified(r.RemoteAddress) || isInboundMulticastOrBroadcast(r)) {
// TCP can only be used to communicate between a single source and a
// single destination; the addresses must be unicast.
r.Stats().TCP.InvalidSegmentsReceived.Increment()
return true
}
eps.mu.RLock()
ep := eps.findEndpointLocked(id)
eps.mu.RUnlock()
if ep == nil {
if protocol == header.UDPProtocolNumber {
r.Stats().UDP.UnknownPortErrors.Increment()
}
return false
}
ep.handlePacket(r, id, pkt)
return true
}
// deliverRawPacket attempts to deliver the given packet and returns whether it
// was delivered successfully.
func (d *transportDemuxer) deliverRawPacket(r *Route, protocol tcpip.TransportProtocolNumber, pkt *PacketBuffer) bool {
eps, ok := d.protocol[protocolIDs{r.NetProto, protocol}]
if !ok {
return false
}
// As in net/ipv4/ip_input.c:ip_local_deliver, attempt to deliver via
// raw endpoint first. If there are multiple raw endpoints, they all
// receive the packet.
foundRaw := false
eps.mu.RLock()
for _, rawEP := range eps.rawEndpoints {
// Each endpoint gets its own copy of the packet for the sake
// of save/restore.
rawEP.HandlePacket(r, pkt)
foundRaw = true
}
eps.mu.RUnlock()
return foundRaw
}
// deliverControlPacket attempts to deliver the given control packet. Returns
// true if it found an endpoint, false otherwise.
func (d *transportDemuxer) deliverControlPacket(n *NIC, net tcpip.NetworkProtocolNumber, trans tcpip.TransportProtocolNumber, typ ControlType, extra uint32, pkt *PacketBuffer, id TransportEndpointID) bool {
eps, ok := d.protocol[protocolIDs{net, trans}]
if !ok {
return false
}
eps.mu.RLock()
ep := eps.findEndpointLocked(id)
eps.mu.RUnlock()
if ep == nil {
return false
}
ep.handleControlPacket(n, id, typ, extra, pkt)
return true
}
// findTransportEndpoint find a single endpoint that most closely matches the provided id.
func (d *transportDemuxer) findTransportEndpoint(netProto tcpip.NetworkProtocolNumber, transProto tcpip.TransportProtocolNumber, id TransportEndpointID, r *Route) TransportEndpoint {
eps, ok := d.protocol[protocolIDs{netProto, transProto}]
if !ok {
return nil
}
eps.mu.RLock()
epsByNIC := eps.findEndpointLocked(id)
if epsByNIC == nil {
eps.mu.RUnlock()
return nil
}
epsByNIC.mu.RLock()
eps.mu.RUnlock()
mpep, ok := epsByNIC.endpoints[r.nic.ID()]
if !ok {
if mpep, ok = epsByNIC.endpoints[0]; !ok {
epsByNIC.mu.RUnlock() // Don't use defer for performance reasons.
return nil
}
}
ep := selectEndpoint(id, mpep, epsByNIC.seed)
epsByNIC.mu.RUnlock()
return ep
}
// registerRawEndpoint registers the given endpoint with the dispatcher such
// that packets of the appropriate protocol are delivered to it. A single
// packet can be sent to one or more raw endpoints along with a non-raw
// endpoint.
func (d *transportDemuxer) registerRawEndpoint(netProto tcpip.NetworkProtocolNumber, transProto tcpip.TransportProtocolNumber, ep RawTransportEndpoint) *tcpip.Error {
eps, ok := d.protocol[protocolIDs{netProto, transProto}]
if !ok {
return tcpip.ErrNotSupported
}
eps.mu.Lock()
eps.rawEndpoints = append(eps.rawEndpoints, ep)
eps.mu.Unlock()
return nil
}
// unregisterRawEndpoint unregisters the raw endpoint for the given transport
// protocol such that it won't receive any more packets.
func (d *transportDemuxer) unregisterRawEndpoint(netProto tcpip.NetworkProtocolNumber, transProto tcpip.TransportProtocolNumber, ep RawTransportEndpoint) {
eps, ok := d.protocol[protocolIDs{netProto, transProto}]
if !ok {
panic(fmt.Errorf("tried to unregister endpoint with unsupported network and transport protocol pair: %d, %d", netProto, transProto))
}
eps.mu.Lock()
for i, rawEP := range eps.rawEndpoints {
if rawEP == ep {
lastIdx := len(eps.rawEndpoints) - 1
eps.rawEndpoints[i] = eps.rawEndpoints[lastIdx]
eps.rawEndpoints[lastIdx] = nil
eps.rawEndpoints = eps.rawEndpoints[:lastIdx]
break
}
}
eps.mu.Unlock()
}
func isInboundMulticastOrBroadcast(r *Route) bool {
return r.IsInboundBroadcast() || header.IsV4MulticastAddress(r.LocalAddress) || header.IsV6MulticastAddress(r.LocalAddress)
}
func isSpecified(addr tcpip.Address) bool {
return addr != header.IPv4Any && addr != header.IPv6Any
}
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