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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"
"reflect"
"sync/atomic"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/header"
)
var _ NetworkInterface = (*NIC)(nil)
// NIC represents a "network interface card" to which the networking stack is
// attached.
type NIC struct {
LinkEndpoint
stack *Stack
id tcpip.NICID
name string
context NICContext
stats NICStats
neigh *neighborCache
// The network endpoints themselves may be modified by calling the interface's
// methods, but the map reference and entries must be constant.
networkEndpoints map[tcpip.NetworkProtocolNumber]NetworkEndpoint
linkAddrResolvers map[tcpip.NetworkProtocolNumber]LinkAddressResolver
// enabled is set to 1 when the NIC is enabled and 0 when it is disabled.
//
// Must be accessed using atomic operations.
enabled uint32
// linkResQueue holds packets that are waiting for link resolution to
// complete.
linkResQueue packetsPendingLinkResolution
linkAddrCache *linkAddrCache
mu struct {
sync.RWMutex
spoofing bool
promiscuous bool
// packetEPs is protected by mu, but the contained packetEndpointList are
// not.
packetEPs map[tcpip.NetworkProtocolNumber]*packetEndpointList
}
}
// NICStats hold statistics for a NIC.
type NICStats struct {
Tx DirectionStats
Rx DirectionStats
DisabledRx DirectionStats
Neighbor NeighborStats
}
func makeNICStats() NICStats {
var s NICStats
tcpip.InitStatCounters(reflect.ValueOf(&s).Elem())
return s
}
// DirectionStats includes packet and byte counts.
type DirectionStats struct {
Packets *tcpip.StatCounter
Bytes *tcpip.StatCounter
}
type packetEndpointList struct {
mu sync.RWMutex
// eps is protected by mu, but the contained PacketEndpoint values are not.
eps []PacketEndpoint
}
func (p *packetEndpointList) add(ep PacketEndpoint) {
p.mu.Lock()
defer p.mu.Unlock()
p.eps = append(p.eps, ep)
}
func (p *packetEndpointList) remove(ep PacketEndpoint) {
p.mu.Lock()
defer p.mu.Unlock()
for i, epOther := range p.eps {
if epOther == ep {
p.eps = append(p.eps[:i], p.eps[i+1:]...)
break
}
}
}
// forEach calls fn with each endpoints in p while holding the read lock on p.
func (p *packetEndpointList) forEach(fn func(PacketEndpoint)) {
p.mu.RLock()
defer p.mu.RUnlock()
for _, ep := range p.eps {
fn(ep)
}
}
// newNIC returns a new NIC using the default NDP configurations from stack.
func newNIC(stack *Stack, id tcpip.NICID, name string, ep LinkEndpoint, ctx NICContext) *NIC {
// TODO(b/141011931): Validate a LinkEndpoint (ep) is valid. For
// example, make sure that the link address it provides is a valid
// unicast ethernet address.
// TODO(b/143357959): RFC 8200 section 5 requires that IPv6 endpoints
// observe an MTU of at least 1280 bytes. Ensure that this requirement
// of IPv6 is supported on this endpoint's LinkEndpoint.
nic := &NIC{
LinkEndpoint: ep,
stack: stack,
id: id,
name: name,
context: ctx,
stats: makeNICStats(),
networkEndpoints: make(map[tcpip.NetworkProtocolNumber]NetworkEndpoint),
linkAddrResolvers: make(map[tcpip.NetworkProtocolNumber]LinkAddressResolver),
}
nic.linkResQueue.init(nic)
nic.linkAddrCache = newLinkAddrCache(nic, ageLimit, resolutionTimeout, resolutionAttempts)
nic.mu.packetEPs = make(map[tcpip.NetworkProtocolNumber]*packetEndpointList)
// Check for Neighbor Unreachability Detection support.
var nud NUDHandler
if ep.Capabilities()&CapabilityResolutionRequired != 0 && stack.useNeighborCache {
rng := rand.New(rand.NewSource(stack.clock.NowNanoseconds()))
nic.neigh = &neighborCache{
nic: nic,
state: NewNUDState(stack.nudConfigs, rng),
cache: make(map[tcpip.Address]*neighborEntry, neighborCacheSize),
}
// An interface value that holds a nil pointer but non-nil type is not the
// same as the nil interface. Because of this, nud must only be assignd if
// nic.neigh is non-nil since a nil reference to a neighborCache is not
// valid.
//
// See https://golang.org/doc/faq#nil_error for more information.
nud = nic.neigh
}
// Register supported packet and network endpoint protocols.
for _, netProto := range header.Ethertypes {
nic.mu.packetEPs[netProto] = new(packetEndpointList)
}
for _, netProto := range stack.networkProtocols {
netNum := netProto.Number()
nic.mu.packetEPs[netNum] = new(packetEndpointList)
netEP := netProto.NewEndpoint(nic, nic.linkAddrCache, nud, nic)
nic.networkEndpoints[netNum] = netEP
if r, ok := netEP.(LinkAddressResolver); ok {
nic.linkAddrResolvers[r.LinkAddressProtocol()] = r
}
}
nic.LinkEndpoint.Attach(nic)
return nic
}
func (n *NIC) getNetworkEndpoint(proto tcpip.NetworkProtocolNumber) NetworkEndpoint {
return n.networkEndpoints[proto]
}
// Enabled implements NetworkInterface.
func (n *NIC) Enabled() bool {
return atomic.LoadUint32(&n.enabled) == 1
}
// setEnabled sets the enabled status for the NIC.
//
// Returns true if the enabled status was updated.
func (n *NIC) setEnabled(v bool) bool {
if v {
return atomic.SwapUint32(&n.enabled, 1) == 0
}
return atomic.SwapUint32(&n.enabled, 0) == 1
}
// disable disables n.
//
// It undoes the work done by enable.
func (n *NIC) disable() {
n.mu.Lock()
n.disableLocked()
n.mu.Unlock()
}
// disableLocked disables n.
//
// It undoes the work done by enable.
//
// n MUST be locked.
func (n *NIC) disableLocked() {
if !n.Enabled() {
return
}
// TODO(gvisor.dev/issue/1491): Should Routes that are currently bound to n be
// invalidated? Currently, Routes will continue to work when a NIC is enabled
// again, and applications may not know that the underlying NIC was ever
// disabled.
for _, ep := range n.networkEndpoints {
ep.Disable()
}
// Clear the neighbour table (including static entries) as we cannot guarantee
// that the current neighbour table will be valid when the NIC is enabled
// again.
//
// This matches linux's behaviour at the time of writing:
// https://github.com/torvalds/linux/blob/71c061d2443814de15e177489d5cc00a4a253ef3/net/core/neighbour.c#L371
switch err := n.clearNeighbors(); err.(type) {
case nil, *tcpip.ErrNotSupported:
default:
panic(fmt.Sprintf("n.clearNeighbors(): %s", err))
}
if !n.setEnabled(false) {
panic("should have only done work to disable the NIC if it was enabled")
}
}
// enable enables n.
//
// If the stack has IPv6 enabled, enable will join the IPv6 All-Nodes Multicast
// address (ff02::1), start DAD for permanent addresses, and start soliciting
// routers if the stack is not operating as a router. If the stack is also
// configured to auto-generate a link-local address, one will be generated.
func (n *NIC) enable() tcpip.Error {
n.mu.Lock()
defer n.mu.Unlock()
if !n.setEnabled(true) {
return nil
}
for _, ep := range n.networkEndpoints {
if err := ep.Enable(); err != nil {
return err
}
}
return nil
}
// remove detaches NIC from the link endpoint and releases network endpoint
// resources. This guarantees no packets between this NIC and the network
// stack.
func (n *NIC) remove() tcpip.Error {
n.mu.Lock()
defer n.mu.Unlock()
n.disableLocked()
for _, ep := range n.networkEndpoints {
ep.Close()
}
// Detach from link endpoint, so no packet comes in.
n.LinkEndpoint.Attach(nil)
return nil
}
// setPromiscuousMode enables or disables promiscuous mode.
func (n *NIC) setPromiscuousMode(enable bool) {
n.mu.Lock()
n.mu.promiscuous = enable
n.mu.Unlock()
}
// Promiscuous implements NetworkInterface.
func (n *NIC) Promiscuous() bool {
n.mu.RLock()
rv := n.mu.promiscuous
n.mu.RUnlock()
return rv
}
// IsLoopback implements NetworkInterface.
func (n *NIC) IsLoopback() bool {
return n.LinkEndpoint.Capabilities()&CapabilityLoopback != 0
}
// WritePacket implements NetworkLinkEndpoint.
func (n *NIC) WritePacket(r *Route, gso *GSO, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) tcpip.Error {
_, err := n.enqueuePacketBuffer(r, gso, protocol, pkt)
return err
}
func (n *NIC) writePacketBuffer(r RouteInfo, gso *GSO, protocol tcpip.NetworkProtocolNumber, pkt pendingPacketBuffer) (int, tcpip.Error) {
switch pkt := pkt.(type) {
case *PacketBuffer:
if err := n.writePacket(r, gso, protocol, pkt); err != nil {
return 0, err
}
return 1, nil
case *PacketBufferList:
return n.writePackets(r, gso, protocol, *pkt)
default:
panic(fmt.Sprintf("unrecognized pending packet buffer type = %T", pkt))
}
}
func (n *NIC) enqueuePacketBuffer(r *Route, gso *GSO, protocol tcpip.NetworkProtocolNumber, pkt pendingPacketBuffer) (int, tcpip.Error) {
routeInfo, _, err := r.resolvedFields(nil)
switch err.(type) {
case nil:
return n.writePacketBuffer(routeInfo, gso, protocol, pkt)
case *tcpip.ErrWouldBlock:
// As per relevant RFCs, we should queue packets while we wait for link
// resolution to complete.
//
// RFC 1122 section 2.3.2.2 (for IPv4):
// The link layer SHOULD save (rather than discard) at least
// one (the latest) packet of each set of packets destined to
// the same unresolved IP address, and transmit the saved
// packet when the address has been resolved.
//
// RFC 4861 section 7.2.2 (for IPv6):
// While waiting for address resolution to complete, the sender MUST, for
// each neighbor, retain a small queue of packets waiting for address
// resolution to complete. The queue MUST hold at least one packet, and
// MAY contain more. However, the number of queued packets per neighbor
// SHOULD be limited to some small value. When a queue overflows, the new
// arrival SHOULD replace the oldest entry. Once address resolution
// completes, the node transmits any queued packets.
return n.linkResQueue.enqueue(r, gso, protocol, pkt)
default:
return 0, err
}
}
// WritePacketToRemote implements NetworkInterface.
func (n *NIC) WritePacketToRemote(remoteLinkAddr tcpip.LinkAddress, gso *GSO, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) tcpip.Error {
var r RouteInfo
r.NetProto = protocol
r.RemoteLinkAddress = remoteLinkAddr
return n.writePacket(r, gso, protocol, pkt)
}
func (n *NIC) writePacket(r RouteInfo, gso *GSO, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) tcpip.Error {
// WritePacket takes ownership of pkt, calculate numBytes first.
numBytes := pkt.Size()
pkt.EgressRoute = r
pkt.GSOOptions = gso
pkt.NetworkProtocolNumber = protocol
if err := n.LinkEndpoint.WritePacket(r, gso, protocol, pkt); err != nil {
return err
}
n.stats.Tx.Packets.Increment()
n.stats.Tx.Bytes.IncrementBy(uint64(numBytes))
return nil
}
// WritePackets implements NetworkLinkEndpoint.
func (n *NIC) WritePackets(r *Route, gso *GSO, pkts PacketBufferList, protocol tcpip.NetworkProtocolNumber) (int, tcpip.Error) {
return n.enqueuePacketBuffer(r, gso, protocol, &pkts)
}
func (n *NIC) writePackets(r RouteInfo, gso *GSO, protocol tcpip.NetworkProtocolNumber, pkts PacketBufferList) (int, tcpip.Error) {
for pkt := pkts.Front(); pkt != nil; pkt = pkt.Next() {
pkt.EgressRoute = r
pkt.GSOOptions = gso
pkt.NetworkProtocolNumber = protocol
}
writtenPackets, err := n.LinkEndpoint.WritePackets(r, gso, pkts, protocol)
n.stats.Tx.Packets.IncrementBy(uint64(writtenPackets))
writtenBytes := 0
for i, pb := 0, pkts.Front(); i < writtenPackets && pb != nil; i, pb = i+1, pb.Next() {
writtenBytes += pb.Size()
}
n.stats.Tx.Bytes.IncrementBy(uint64(writtenBytes))
return writtenPackets, err
}
// setSpoofing enables or disables address spoofing.
func (n *NIC) setSpoofing(enable bool) {
n.mu.Lock()
n.mu.spoofing = enable
n.mu.Unlock()
}
// primaryAddress returns an address that can be used to communicate with
// remoteAddr.
func (n *NIC) primaryEndpoint(protocol tcpip.NetworkProtocolNumber, remoteAddr tcpip.Address) AssignableAddressEndpoint {
ep, ok := n.networkEndpoints[protocol]
if !ok {
return nil
}
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
return nil
}
n.mu.RLock()
spoofing := n.mu.spoofing
n.mu.RUnlock()
return addressableEndpoint.AcquireOutgoingPrimaryAddress(remoteAddr, spoofing)
}
type getAddressBehaviour int
const (
// spoofing indicates that the NIC's spoofing flag should be observed when
// getting a NIC's address endpoint.
spoofing getAddressBehaviour = iota
// promiscuous indicates that the NIC's promiscuous flag should be observed
// when getting a NIC's address endpoint.
promiscuous
)
func (n *NIC) getAddress(protocol tcpip.NetworkProtocolNumber, dst tcpip.Address) AssignableAddressEndpoint {
return n.getAddressOrCreateTemp(protocol, dst, CanBePrimaryEndpoint, promiscuous)
}
func (n *NIC) hasAddress(protocol tcpip.NetworkProtocolNumber, addr tcpip.Address) bool {
ep := n.getAddressOrCreateTempInner(protocol, addr, false, NeverPrimaryEndpoint)
if ep != nil {
ep.DecRef()
return true
}
return false
}
// findEndpoint finds the endpoint, if any, with the given address.
func (n *NIC) findEndpoint(protocol tcpip.NetworkProtocolNumber, address tcpip.Address, peb PrimaryEndpointBehavior) AssignableAddressEndpoint {
return n.getAddressOrCreateTemp(protocol, address, peb, spoofing)
}
// getAddressEpOrCreateTemp returns the address endpoint for the given protocol
// and address.
//
// If none exists a temporary one may be created if we are in promiscuous mode
// or spoofing. Promiscuous mode will only be checked if promiscuous is true.
// Similarly, spoofing will only be checked if spoofing is true.
//
// If the address is the IPv4 broadcast address for an endpoint's network, that
// endpoint will be returned.
func (n *NIC) getAddressOrCreateTemp(protocol tcpip.NetworkProtocolNumber, address tcpip.Address, peb PrimaryEndpointBehavior, tempRef getAddressBehaviour) AssignableAddressEndpoint {
n.mu.RLock()
var spoofingOrPromiscuous bool
switch tempRef {
case spoofing:
spoofingOrPromiscuous = n.mu.spoofing
case promiscuous:
spoofingOrPromiscuous = n.mu.promiscuous
}
n.mu.RUnlock()
return n.getAddressOrCreateTempInner(protocol, address, spoofingOrPromiscuous, peb)
}
// getAddressOrCreateTempInner is like getAddressEpOrCreateTemp except a boolean
// is passed to indicate whether or not we should generate temporary endpoints.
func (n *NIC) getAddressOrCreateTempInner(protocol tcpip.NetworkProtocolNumber, address tcpip.Address, createTemp bool, peb PrimaryEndpointBehavior) AssignableAddressEndpoint {
ep, ok := n.networkEndpoints[protocol]
if !ok {
return nil
}
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
return nil
}
return addressableEndpoint.AcquireAssignedAddress(address, createTemp, peb)
}
// addAddress adds a new address to n, so that it starts accepting packets
// targeted at the given address (and network protocol).
func (n *NIC) addAddress(protocolAddress tcpip.ProtocolAddress, peb PrimaryEndpointBehavior) tcpip.Error {
ep, ok := n.networkEndpoints[protocolAddress.Protocol]
if !ok {
return &tcpip.ErrUnknownProtocol{}
}
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
return &tcpip.ErrNotSupported{}
}
addressEndpoint, err := addressableEndpoint.AddAndAcquirePermanentAddress(protocolAddress.AddressWithPrefix, peb, AddressConfigStatic, false /* deprecated */)
if err == nil {
// We have no need for the address endpoint.
addressEndpoint.DecRef()
}
return err
}
// allPermanentAddresses returns all permanent addresses associated with
// this NIC.
func (n *NIC) allPermanentAddresses() []tcpip.ProtocolAddress {
var addrs []tcpip.ProtocolAddress
for p, ep := range n.networkEndpoints {
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
continue
}
for _, a := range addressableEndpoint.PermanentAddresses() {
addrs = append(addrs, tcpip.ProtocolAddress{Protocol: p, AddressWithPrefix: a})
}
}
return addrs
}
// primaryAddresses returns the primary addresses associated with this NIC.
func (n *NIC) primaryAddresses() []tcpip.ProtocolAddress {
var addrs []tcpip.ProtocolAddress
for p, ep := range n.networkEndpoints {
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
continue
}
for _, a := range addressableEndpoint.PrimaryAddresses() {
addrs = append(addrs, tcpip.ProtocolAddress{Protocol: p, AddressWithPrefix: a})
}
}
return addrs
}
// primaryAddress returns the primary address associated with this NIC.
//
// primaryAddress will return the first non-deprecated address if such an
// address exists. If no non-deprecated address exists, the first deprecated
// address will be returned.
func (n *NIC) primaryAddress(proto tcpip.NetworkProtocolNumber) tcpip.AddressWithPrefix {
ep, ok := n.networkEndpoints[proto]
if !ok {
return tcpip.AddressWithPrefix{}
}
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
return tcpip.AddressWithPrefix{}
}
return addressableEndpoint.MainAddress()
}
// removeAddress removes an address from n.
func (n *NIC) removeAddress(addr tcpip.Address) tcpip.Error {
for _, ep := range n.networkEndpoints {
addressableEndpoint, ok := ep.(AddressableEndpoint)
if !ok {
continue
}
switch err := addressableEndpoint.RemovePermanentAddress(addr); err.(type) {
case *tcpip.ErrBadLocalAddress:
continue
default:
return err
}
}
return &tcpip.ErrBadLocalAddress{}
}
func (n *NIC) confirmReachable(addr tcpip.Address) {
if n := n.neigh; n != nil {
n.handleUpperLevelConfirmation(addr)
}
}
func (n *NIC) getLinkAddress(addr, localAddr tcpip.Address, protocol tcpip.NetworkProtocolNumber, onResolve func(LinkResolutionResult)) tcpip.Error {
linkRes, ok := n.linkAddrResolvers[protocol]
if !ok {
return &tcpip.ErrNotSupported{}
}
if linkAddr, ok := linkRes.ResolveStaticAddress(addr); ok {
onResolve(LinkResolutionResult{LinkAddress: linkAddr, Success: true})
return nil
}
_, _, err := n.getNeighborLinkAddress(addr, localAddr, linkRes, onResolve)
return err
}
func (n *NIC) getNeighborLinkAddress(addr, localAddr tcpip.Address, linkRes LinkAddressResolver, onResolve func(LinkResolutionResult)) (tcpip.LinkAddress, <-chan struct{}, tcpip.Error) {
if n.neigh != nil {
entry, ch, err := n.neigh.entry(addr, localAddr, linkRes, onResolve)
return entry.LinkAddr, ch, err
}
return n.linkAddrCache.get(addr, linkRes, localAddr, onResolve)
}
func (n *NIC) neighbors() ([]NeighborEntry, tcpip.Error) {
if n.neigh == nil {
return nil, &tcpip.ErrNotSupported{}
}
return n.neigh.entries(), nil
}
func (n *NIC) addStaticNeighbor(addr tcpip.Address, linkAddress tcpip.LinkAddress) tcpip.Error {
if n.neigh == nil {
return &tcpip.ErrNotSupported{}
}
n.neigh.addStaticEntry(addr, linkAddress)
return nil
}
func (n *NIC) removeNeighbor(addr tcpip.Address) tcpip.Error {
if n.neigh == nil {
return &tcpip.ErrNotSupported{}
}
if !n.neigh.removeEntry(addr) {
return &tcpip.ErrBadAddress{}
}
return nil
}
func (n *NIC) clearNeighbors() tcpip.Error {
if n.neigh == nil {
return &tcpip.ErrNotSupported{}
}
n.neigh.clear()
return nil
}
// joinGroup adds a new endpoint for the given multicast address, if none
// exists yet. Otherwise it just increments its count.
func (n *NIC) joinGroup(protocol tcpip.NetworkProtocolNumber, addr tcpip.Address) tcpip.Error {
// TODO(b/143102137): When implementing MLD, make sure MLD packets are
// not sent unless a valid link-local address is available for use on n
// as an MLD packet's source address must be a link-local address as
// outlined in RFC 3810 section 5.
ep, ok := n.networkEndpoints[protocol]
if !ok {
return &tcpip.ErrNotSupported{}
}
gep, ok := ep.(GroupAddressableEndpoint)
if !ok {
return &tcpip.ErrNotSupported{}
}
return gep.JoinGroup(addr)
}
// leaveGroup decrements the count for the given multicast address, and when it
// reaches zero removes the endpoint for this address.
func (n *NIC) leaveGroup(protocol tcpip.NetworkProtocolNumber, addr tcpip.Address) tcpip.Error {
ep, ok := n.networkEndpoints[protocol]
if !ok {
return &tcpip.ErrNotSupported{}
}
gep, ok := ep.(GroupAddressableEndpoint)
if !ok {
return &tcpip.ErrNotSupported{}
}
return gep.LeaveGroup(addr)
}
// isInGroup returns true if n has joined the multicast group addr.
func (n *NIC) isInGroup(addr tcpip.Address) bool {
for _, ep := range n.networkEndpoints {
gep, ok := ep.(GroupAddressableEndpoint)
if !ok {
continue
}
if gep.IsInGroup(addr) {
return true
}
}
return false
}
// DeliverNetworkPacket finds the appropriate network protocol endpoint and
// hands the packet over for further processing. This function is called when
// the NIC receives a packet from the link endpoint.
// Note that the ownership of the slice backing vv is retained by the caller.
// This rule applies only to the slice itself, not to the items of the slice;
// the ownership of the items is not retained by the caller.
func (n *NIC) DeliverNetworkPacket(remote, local tcpip.LinkAddress, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) {
n.mu.RLock()
enabled := n.Enabled()
// If the NIC is not yet enabled, don't receive any packets.
if !enabled {
n.mu.RUnlock()
n.stats.DisabledRx.Packets.Increment()
n.stats.DisabledRx.Bytes.IncrementBy(uint64(pkt.Data.Size()))
return
}
n.stats.Rx.Packets.Increment()
n.stats.Rx.Bytes.IncrementBy(uint64(pkt.Data.Size()))
networkEndpoint, ok := n.networkEndpoints[protocol]
if !ok {
n.mu.RUnlock()
n.stack.stats.UnknownProtocolRcvdPackets.Increment()
return
}
// If no local link layer address is provided, assume it was sent
// directly to this NIC.
if local == "" {
local = n.LinkEndpoint.LinkAddress()
}
pkt.RXTransportChecksumValidated = n.LinkEndpoint.Capabilities()&CapabilityRXChecksumOffload != 0
// Are any packet type sockets listening for this network protocol?
protoEPs := n.mu.packetEPs[protocol]
// Other packet type sockets that are listening for all protocols.
anyEPs := n.mu.packetEPs[header.EthernetProtocolAll]
n.mu.RUnlock()
// Deliver to interested packet endpoints without holding NIC lock.
deliverPacketEPs := func(ep PacketEndpoint) {
p := pkt.Clone()
p.PktType = tcpip.PacketHost
ep.HandlePacket(n.id, local, protocol, p)
}
if protoEPs != nil {
protoEPs.forEach(deliverPacketEPs)
}
if anyEPs != nil {
anyEPs.forEach(deliverPacketEPs)
}
// Parse headers.
netProto := n.stack.NetworkProtocolInstance(protocol)
transProtoNum, hasTransportHdr, ok := netProto.Parse(pkt)
if !ok {
// The packet is too small to contain a network header.
n.stack.stats.MalformedRcvdPackets.Increment()
return
}
if hasTransportHdr {
pkt.TransportProtocolNumber = transProtoNum
// Parse the transport header if present.
if state, ok := n.stack.transportProtocols[transProtoNum]; ok {
state.proto.Parse(pkt)
}
}
if n.stack.handleLocal && !n.IsLoopback() {
src, _ := netProto.ParseAddresses(pkt.NetworkHeader().View())
if r := n.getAddress(protocol, src); r != nil {
r.DecRef()
// The source address is one of our own, so we never should have gotten a
// packet like this unless handleLocal is false. Loopback also calls this
// function even though the packets didn't come from the physical interface
// so don't drop those.
n.stack.stats.IP.InvalidSourceAddressesReceived.Increment()
return
}
}
networkEndpoint.HandlePacket(pkt)
}
// DeliverOutboundPacket implements NetworkDispatcher.DeliverOutboundPacket.
func (n *NIC) DeliverOutboundPacket(remote, local tcpip.LinkAddress, protocol tcpip.NetworkProtocolNumber, pkt *PacketBuffer) {
n.mu.RLock()
// We do not deliver to protocol specific packet endpoints as on Linux
// only ETH_P_ALL endpoints get outbound packets.
// Add any other packet sockets that maybe listening for all protocols.
eps := n.mu.packetEPs[header.EthernetProtocolAll]
n.mu.RUnlock()
eps.forEach(func(ep PacketEndpoint) {
p := pkt.Clone()
p.PktType = tcpip.PacketOutgoing
// Add the link layer header as outgoing packets are intercepted
// before the link layer header is created.
n.LinkEndpoint.AddHeader(local, remote, protocol, p)
ep.HandlePacket(n.id, local, protocol, p)
})
}
// DeliverTransportPacket delivers the packets to the appropriate transport
// protocol endpoint.
func (n *NIC) DeliverTransportPacket(protocol tcpip.TransportProtocolNumber, pkt *PacketBuffer) TransportPacketDisposition {
state, ok := n.stack.transportProtocols[protocol]
if !ok {
n.stack.stats.UnknownProtocolRcvdPackets.Increment()
return TransportPacketProtocolUnreachable
}
transProto := state.proto
// Raw socket packets are delivered based solely on the transport
// protocol number. We do not inspect the payload to ensure it's
// validly formed.
n.stack.demux.deliverRawPacket(protocol, pkt)
// TransportHeader is empty only when pkt is an ICMP packet or was reassembled
// from fragments.
if pkt.TransportHeader().View().IsEmpty() {
// TODO(gvisor.dev/issue/170): ICMP packets don't have their TransportHeader
// fields set yet, parse it here. See icmp/protocol.go:protocol.Parse for a
// full explanation.
if protocol == header.ICMPv4ProtocolNumber || protocol == header.ICMPv6ProtocolNumber {
// ICMP packets may be longer, but until icmp.Parse is implemented, here
// we parse it using the minimum size.
if _, ok := pkt.TransportHeader().Consume(transProto.MinimumPacketSize()); !ok {
n.stack.stats.MalformedRcvdPackets.Increment()
// We consider a malformed transport packet handled because there is
// nothing the caller can do.
return TransportPacketHandled
}
} else if !transProto.Parse(pkt) {
n.stack.stats.MalformedRcvdPackets.Increment()
return TransportPacketHandled
}
}
srcPort, dstPort, err := transProto.ParsePorts(pkt.TransportHeader().View())
if err != nil {
n.stack.stats.MalformedRcvdPackets.Increment()
return TransportPacketHandled
}
netProto, ok := n.stack.networkProtocols[pkt.NetworkProtocolNumber]
if !ok {
panic(fmt.Sprintf("expected network protocol = %d, have = %#v", pkt.NetworkProtocolNumber, n.stack.networkProtocolNumbers()))
}
src, dst := netProto.ParseAddresses(pkt.NetworkHeader().View())
id := TransportEndpointID{
LocalPort: dstPort,
LocalAddress: dst,
RemotePort: srcPort,
RemoteAddress: src,
}
if n.stack.demux.deliverPacket(protocol, pkt, id) {
return TransportPacketHandled
}
// Try to deliver to per-stack default handler.
if state.defaultHandler != nil {
if state.defaultHandler(id, pkt) {
return TransportPacketHandled
}
}
// We could not find an appropriate destination for this packet so
// give the protocol specific error handler a chance to handle it.
// If it doesn't handle it then we should do so.
switch res := transProto.HandleUnknownDestinationPacket(id, pkt); res {
case UnknownDestinationPacketMalformed:
n.stack.stats.MalformedRcvdPackets.Increment()
return TransportPacketHandled
case UnknownDestinationPacketUnhandled:
return TransportPacketDestinationPortUnreachable
case UnknownDestinationPacketHandled:
return TransportPacketHandled
default:
panic(fmt.Sprintf("unrecognized result from HandleUnknownDestinationPacket = %d", res))
}
}
// DeliverTransportControlPacket delivers control packets to the appropriate
// transport protocol endpoint.
func (n *NIC) DeliverTransportControlPacket(local, remote tcpip.Address, net tcpip.NetworkProtocolNumber, trans tcpip.TransportProtocolNumber, typ ControlType, extra uint32, pkt *PacketBuffer) {
state, ok := n.stack.transportProtocols[trans]
if !ok {
return
}
transProto := state.proto
// ICMPv4 only guarantees that 8 bytes of the transport protocol will
// be present in the payload. We know that the ports are within the
// first 8 bytes for all known transport protocols.
transHeader, ok := pkt.Data.PullUp(8)
if !ok {
return
}
srcPort, dstPort, err := transProto.ParsePorts(transHeader)
if err != nil {
return
}
id := TransportEndpointID{srcPort, local, dstPort, remote}
if n.stack.demux.deliverControlPacket(n, net, trans, typ, extra, pkt, id) {
return
}
}
// ID implements NetworkInterface.
func (n *NIC) ID() tcpip.NICID {
return n.id
}
// Name implements NetworkInterface.
func (n *NIC) Name() string {
return n.name
}
// nudConfigs gets the NUD configurations for n.
func (n *NIC) nudConfigs() (NUDConfigurations, tcpip.Error) {
if n.neigh == nil {
return NUDConfigurations{}, &tcpip.ErrNotSupported{}
}
return n.neigh.config(), nil
}
// setNUDConfigs sets the NUD configurations for n.
//
// Note, if c contains invalid NUD configuration values, it will be fixed to
// use default values for the erroneous values.
func (n *NIC) setNUDConfigs(c NUDConfigurations) tcpip.Error {
if n.neigh == nil {
return &tcpip.ErrNotSupported{}
}
c.resetInvalidFields()
n.neigh.setConfig(c)
return nil
}
func (n *NIC) registerPacketEndpoint(netProto tcpip.NetworkProtocolNumber, ep PacketEndpoint) tcpip.Error {
n.mu.Lock()
defer n.mu.Unlock()
eps, ok := n.mu.packetEPs[netProto]
if !ok {
return &tcpip.ErrNotSupported{}
}
eps.add(ep)
return nil
}
func (n *NIC) unregisterPacketEndpoint(netProto tcpip.NetworkProtocolNumber, ep PacketEndpoint) {
n.mu.Lock()
defer n.mu.Unlock()
eps, ok := n.mu.packetEPs[netProto]
if !ok {
return
}
eps.remove(ep)
}
// isValidForOutgoing returns true if the endpoint can be used to send out a
// packet. It requires the endpoint to not be marked expired (i.e., its address
// has been removed) unless the NIC is in spoofing mode, or temporary.
func (n *NIC) isValidForOutgoing(ep AssignableAddressEndpoint) bool {
n.mu.RLock()
spoofing := n.mu.spoofing
n.mu.RUnlock()
return n.Enabled() && ep.IsAssigned(spoofing)
}
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