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|
// Copyright 2020 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 ipv6 contains the implementation of the ipv6 network protocol.
package ipv6
import (
"encoding/binary"
"fmt"
"hash/fnv"
"sort"
"sync/atomic"
"time"
"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/header/parse"
"gvisor.dev/gvisor/pkg/tcpip/network/fragmentation"
"gvisor.dev/gvisor/pkg/tcpip/network/hash"
"gvisor.dev/gvisor/pkg/tcpip/stack"
)
const (
// As per RFC 8200 section 4.5:
// If insufficient fragments are received to complete reassembly of a packet
// within 60 seconds of the reception of the first-arriving fragment of that
// packet, reassembly of that packet must be abandoned.
//
// Linux also uses 60 seconds for reassembly timeout:
// https://github.com/torvalds/linux/blob/47ec5303d73ea344e84f46660fff693c57641386/include/net/ipv6.h#L456
reassembleTimeout = 60 * time.Second
// ProtocolNumber is the ipv6 protocol number.
ProtocolNumber = header.IPv6ProtocolNumber
// maxTotalSize is maximum size that can be encoded in the 16-bit
// PayloadLength field of the ipv6 header.
maxPayloadSize = 0xffff
// DefaultTTL is the default hop limit for IPv6 Packets egressed by
// Netstack.
DefaultTTL = 64
// buckets for fragment identifiers
buckets = 2048
)
var _ stack.GroupAddressableEndpoint = (*endpoint)(nil)
var _ stack.AddressableEndpoint = (*endpoint)(nil)
var _ stack.NetworkEndpoint = (*endpoint)(nil)
var _ stack.NDPEndpoint = (*endpoint)(nil)
var _ NDPEndpoint = (*endpoint)(nil)
type endpoint struct {
nic stack.NetworkInterface
linkAddrCache stack.LinkAddressCache
nud stack.NUDHandler
dispatcher stack.TransportDispatcher
protocol *protocol
stack *stack.Stack
// enabled is set to 1 when the endpoint is enabled and 0 when it is
// disabled.
//
// Must be accessed using atomic operations.
enabled uint32
mu struct {
sync.RWMutex
addressableEndpointState stack.AddressableEndpointState
ndp ndpState
}
}
// NICNameFromID is a function that returns a stable name for the specified NIC,
// even if different NIC IDs are used to refer to the same NIC in different
// program runs. It is used when generating opaque interface identifiers (IIDs).
// If the NIC was created with a name, it is passed to NICNameFromID.
//
// NICNameFromID SHOULD return unique NIC names so unique opaque IIDs are
// generated for the same prefix on differnt NICs.
type NICNameFromID func(tcpip.NICID, string) string
// OpaqueInterfaceIdentifierOptions holds the options related to the generation
// of opaque interface indentifiers (IIDs) as defined by RFC 7217.
type OpaqueInterfaceIdentifierOptions struct {
// NICNameFromID is a function that returns a stable name for a specified NIC,
// even if the NIC ID changes over time.
//
// Must be specified to generate the opaque IID.
NICNameFromID NICNameFromID
// SecretKey is a pseudo-random number used as the secret key when generating
// opaque IIDs as defined by RFC 7217. The key SHOULD be at least
// header.OpaqueIIDSecretKeyMinBytes bytes and MUST follow minimum randomness
// requirements for security as outlined by RFC 4086. SecretKey MUST NOT
// change between program runs, unless explicitly changed.
//
// OpaqueInterfaceIdentifierOptions takes ownership of SecretKey. SecretKey
// MUST NOT be modified after Stack is created.
//
// May be nil, but a nil value is highly discouraged to maintain
// some level of randomness between nodes.
SecretKey []byte
}
// InvalidateDefaultRouter implements stack.NDPEndpoint.
func (e *endpoint) InvalidateDefaultRouter(rtr tcpip.Address) {
e.mu.Lock()
defer e.mu.Unlock()
e.mu.ndp.invalidateDefaultRouter(rtr)
}
// SetNDPConfigurations implements NDPEndpoint.
func (e *endpoint) SetNDPConfigurations(c NDPConfigurations) {
c.validate()
e.mu.Lock()
defer e.mu.Unlock()
e.mu.ndp.configs = c
}
// hasTentativeAddr returns true if addr is tentative on e.
func (e *endpoint) hasTentativeAddr(addr tcpip.Address) bool {
e.mu.RLock()
addressEndpoint := e.getAddressRLocked(addr)
e.mu.RUnlock()
return addressEndpoint != nil && addressEndpoint.GetKind() == stack.PermanentTentative
}
// dupTentativeAddrDetected attempts to inform e that a tentative addr is a
// duplicate on a link.
//
// dupTentativeAddrDetected removes the tentative address if it exists. If the
// address was generated via SLAAC, an attempt is made to generate a new
// address.
func (e *endpoint) dupTentativeAddrDetected(addr tcpip.Address) *tcpip.Error {
e.mu.Lock()
defer e.mu.Unlock()
addressEndpoint := e.getAddressRLocked(addr)
if addressEndpoint == nil {
return tcpip.ErrBadAddress
}
if addressEndpoint.GetKind() != stack.PermanentTentative {
return tcpip.ErrInvalidEndpointState
}
// If the address is a SLAAC address, do not invalidate its SLAAC prefix as an
// attempt will be made to generate a new address for it.
if err := e.removePermanentEndpointLocked(addressEndpoint, false /* allowSLAACInvalidation */); err != nil {
return err
}
prefix := addressEndpoint.AddressWithPrefix().Subnet()
switch t := addressEndpoint.ConfigType(); t {
case stack.AddressConfigStatic:
case stack.AddressConfigSlaac:
e.mu.ndp.regenerateSLAACAddr(prefix)
case stack.AddressConfigSlaacTemp:
// Do not reset the generation attempts counter for the prefix as the
// temporary address is being regenerated in response to a DAD conflict.
e.mu.ndp.regenerateTempSLAACAddr(prefix, false /* resetGenAttempts */)
default:
panic(fmt.Sprintf("unrecognized address config type = %d", t))
}
return nil
}
// transitionForwarding transitions the endpoint's forwarding status to
// forwarding.
//
// Must only be called when the forwarding status changes.
func (e *endpoint) transitionForwarding(forwarding bool) {
e.mu.Lock()
defer e.mu.Unlock()
if !e.Enabled() {
return
}
if forwarding {
// When transitioning into an IPv6 router, host-only state (NDP discovered
// routers, discovered on-link prefixes, and auto-generated addresses) is
// cleaned up/invalidated and NDP router solicitations are stopped.
e.mu.ndp.stopSolicitingRouters()
e.mu.ndp.cleanupState(true /* hostOnly */)
} else {
// When transitioning into an IPv6 host, NDP router solicitations are
// started.
e.mu.ndp.startSolicitingRouters()
}
}
// Enable implements stack.NetworkEndpoint.
func (e *endpoint) Enable() *tcpip.Error {
e.mu.Lock()
defer e.mu.Unlock()
// If the NIC is not enabled, the endpoint can't do anything meaningful so
// don't enable the endpoint.
if !e.nic.Enabled() {
return tcpip.ErrNotPermitted
}
// If the endpoint is already enabled, there is nothing for it to do.
if !e.setEnabled(true) {
return nil
}
// Join the IPv6 All-Nodes Multicast group if the stack is configured to
// use IPv6. This is required to ensure that this node properly receives
// and responds to the various NDP messages that are destined to the
// all-nodes multicast address. An example is the Neighbor Advertisement
// when we perform Duplicate Address Detection, or Router Advertisement
// when we do Router Discovery. See RFC 4862, section 5.4.2 and RFC 4861
// section 4.2 for more information.
//
// Also auto-generate an IPv6 link-local address based on the endpoint's
// link address if it is configured to do so. Note, each interface is
// required to have IPv6 link-local unicast address, as per RFC 4291
// section 2.1.
// Join the All-Nodes multicast group before starting DAD as responses to DAD
// (NDP NS) messages may be sent to the All-Nodes multicast group if the
// source address of the NDP NS is the unspecified address, as per RFC 4861
// section 7.2.4.
if _, err := e.mu.addressableEndpointState.JoinGroup(header.IPv6AllNodesMulticastAddress); err != nil {
return err
}
// Perform DAD on the all the unicast IPv6 endpoints that are in the permanent
// state.
//
// Addresses may have aleady completed DAD but in the time since the endpoint
// was last enabled, other devices may have acquired the same addresses.
var err *tcpip.Error
e.mu.addressableEndpointState.ReadOnly().ForEach(func(addressEndpoint stack.AddressEndpoint) bool {
addr := addressEndpoint.AddressWithPrefix().Address
if !header.IsV6UnicastAddress(addr) {
return true
}
switch addressEndpoint.GetKind() {
case stack.Permanent:
addressEndpoint.SetKind(stack.PermanentTentative)
fallthrough
case stack.PermanentTentative:
err = e.mu.ndp.startDuplicateAddressDetection(addr, addressEndpoint)
return err == nil
default:
return true
}
})
if err != nil {
return err
}
// Do not auto-generate an IPv6 link-local address for loopback devices.
if e.protocol.autoGenIPv6LinkLocal && !e.nic.IsLoopback() {
// The valid and preferred lifetime is infinite for the auto-generated
// link-local address.
e.mu.ndp.doSLAAC(header.IPv6LinkLocalPrefix.Subnet(), header.NDPInfiniteLifetime, header.NDPInfiniteLifetime)
}
// If we are operating as a router, then do not solicit routers since we
// won't process the RAs anyway.
//
// Routers do not process Router Advertisements (RA) the same way a host
// does. That is, routers do not learn from RAs (e.g. on-link prefixes
// and default routers). Therefore, soliciting RAs from other routers on
// a link is unnecessary for routers.
if !e.protocol.Forwarding() {
e.mu.ndp.startSolicitingRouters()
}
return nil
}
// Enabled implements stack.NetworkEndpoint.
func (e *endpoint) Enabled() bool {
return e.nic.Enabled() && e.isEnabled()
}
// isEnabled returns true if the endpoint is enabled, regardless of the
// enabled status of the NIC.
func (e *endpoint) isEnabled() bool {
return atomic.LoadUint32(&e.enabled) == 1
}
// setEnabled sets the enabled status for the endpoint.
//
// Returns true if the enabled status was updated.
func (e *endpoint) setEnabled(v bool) bool {
if v {
return atomic.SwapUint32(&e.enabled, 1) == 0
}
return atomic.SwapUint32(&e.enabled, 0) == 1
}
// Disable implements stack.NetworkEndpoint.
func (e *endpoint) Disable() {
e.mu.Lock()
defer e.mu.Unlock()
e.disableLocked()
}
func (e *endpoint) disableLocked() {
if !e.setEnabled(false) {
return
}
e.mu.ndp.stopSolicitingRouters()
e.mu.ndp.cleanupState(false /* hostOnly */)
e.stopDADForPermanentAddressesLocked()
// The endpoint may have already left the multicast group.
if _, err := e.mu.addressableEndpointState.LeaveGroup(header.IPv6AllNodesMulticastAddress); err != nil && err != tcpip.ErrBadLocalAddress {
panic(fmt.Sprintf("unexpected error when leaving group = %s: %s", header.IPv6AllNodesMulticastAddress, err))
}
}
// stopDADForPermanentAddressesLocked stops DAD for all permaneent addresses.
//
// Precondition: e.mu must be write locked.
func (e *endpoint) stopDADForPermanentAddressesLocked() {
// Stop DAD for all the tentative unicast addresses.
e.mu.addressableEndpointState.ReadOnly().ForEach(func(addressEndpoint stack.AddressEndpoint) bool {
if addressEndpoint.GetKind() != stack.PermanentTentative {
return true
}
addr := addressEndpoint.AddressWithPrefix().Address
if header.IsV6UnicastAddress(addr) {
e.mu.ndp.stopDuplicateAddressDetection(addr)
}
return true
})
}
// DefaultTTL is the default hop limit for this endpoint.
func (e *endpoint) DefaultTTL() uint8 {
return e.protocol.DefaultTTL()
}
// MTU implements stack.NetworkEndpoint.MTU. It returns the link-layer MTU minus
// the network layer max header length.
func (e *endpoint) MTU() uint32 {
return calculateMTU(e.nic.MTU())
}
// MaxHeaderLength returns the maximum length needed by ipv6 headers (and
// underlying protocols).
func (e *endpoint) MaxHeaderLength() uint16 {
return e.nic.MaxHeaderLength() + header.IPv6MinimumSize
}
func (e *endpoint) addIPHeader(r *stack.Route, pkt *stack.PacketBuffer, params stack.NetworkHeaderParams) {
length := uint16(pkt.Size())
ip := header.IPv6(pkt.NetworkHeader().Push(header.IPv6MinimumSize))
ip.Encode(&header.IPv6Fields{
PayloadLength: length,
NextHeader: uint8(params.Protocol),
HopLimit: params.TTL,
TrafficClass: params.TOS,
SrcAddr: r.LocalAddress,
DstAddr: r.RemoteAddress,
})
pkt.NetworkProtocolNumber = ProtocolNumber
}
func (e *endpoint) packetMustBeFragmented(pkt *stack.PacketBuffer, gso *stack.GSO) bool {
return (gso == nil || gso.Type == stack.GSONone) && pkt.Size() > int(e.nic.MTU())
}
// handleFragments fragments pkt and calls the handler function on each
// fragment. It returns the number of fragments handled and the number of
// fragments left to be processed. The IP header must already be present in the
// original packet. The mtu is the maximum size of the packets. The transport
// header protocol number is required to avoid parsing the IPv6 extension
// headers.
func (e *endpoint) handleFragments(r *stack.Route, gso *stack.GSO, mtu uint32, pkt *stack.PacketBuffer, transProto tcpip.TransportProtocolNumber, handler func(*stack.PacketBuffer) *tcpip.Error) (int, int, *tcpip.Error) {
fragMTU := int(calculateFragmentInnerMTU(mtu, pkt))
if fragMTU < pkt.TransportHeader().View().Size() {
// As per RFC 8200 Section 4.5, the Transport Header is expected to be small
// enough to fit in the first fragment.
return 0, 1, tcpip.ErrMessageTooLong
}
pf := fragmentation.MakePacketFragmenter(pkt, fragMTU, calculateFragmentReserve(pkt))
id := atomic.AddUint32(&e.protocol.ids[hashRoute(r, e.protocol.hashIV)%buckets], 1)
networkHeader := header.IPv6(pkt.NetworkHeader().View())
var n int
for {
fragPkt, more := buildNextFragment(&pf, networkHeader, transProto, id)
if err := handler(fragPkt); err != nil {
return n, pf.RemainingFragmentCount() + 1, err
}
n++
if !more {
return n, pf.RemainingFragmentCount(), nil
}
}
}
// WritePacket writes a packet to the given destination address and protocol.
func (e *endpoint) WritePacket(r *stack.Route, gso *stack.GSO, params stack.NetworkHeaderParams, pkt *stack.PacketBuffer) *tcpip.Error {
e.addIPHeader(r, pkt, params)
return e.writePacket(r, gso, pkt, params.Protocol)
}
func (e *endpoint) writePacket(r *stack.Route, gso *stack.GSO, pkt *stack.PacketBuffer, protocol tcpip.TransportProtocolNumber) *tcpip.Error {
// iptables filtering. All packets that reach here are locally
// generated.
nicName := e.protocol.stack.FindNICNameFromID(e.nic.ID())
ipt := e.protocol.stack.IPTables()
if ok := ipt.Check(stack.Output, pkt, gso, r, "", nicName); !ok {
// iptables is telling us to drop the packet.
r.Stats().IP.IPTablesOutputDropped.Increment()
return nil
}
// If the packet is manipulated as per NAT Output rules, handle packet
// based on destination address and do not send the packet to link
// layer.
//
// TODO(gvisor.dev/issue/170): We should do this for every
// packet, rather than only NATted packets, but removing this check
// short circuits broadcasts before they are sent out to other hosts.
if pkt.NatDone {
netHeader := header.IPv6(pkt.NetworkHeader().View())
if ep, err := e.protocol.stack.FindNetworkEndpoint(ProtocolNumber, netHeader.DestinationAddress()); err == nil {
route := r.ReverseRoute(netHeader.SourceAddress(), netHeader.DestinationAddress())
ep.HandlePacket(&route, pkt)
return nil
}
}
if r.Loop&stack.PacketLoop != 0 {
loopedR := r.MakeLoopedRoute()
e.HandlePacket(&loopedR, stack.NewPacketBuffer(stack.PacketBufferOptions{
// The inbound path expects an unparsed packet.
Data: buffer.NewVectorisedView(pkt.Size(), pkt.Views()),
}))
loopedR.Release()
}
if r.Loop&stack.PacketOut == 0 {
return nil
}
if e.packetMustBeFragmented(pkt, gso) {
sent, remain, err := e.handleFragments(r, gso, e.nic.MTU(), pkt, protocol, func(fragPkt *stack.PacketBuffer) *tcpip.Error {
// TODO(gvisor.dev/issue/3884): Evaluate whether we want to send each
// fragment one by one using WritePacket() (current strategy) or if we
// want to create a PacketBufferList from the fragments and feed it to
// WritePackets(). It'll be faster but cost more memory.
return e.nic.WritePacket(r, gso, ProtocolNumber, fragPkt)
})
r.Stats().IP.PacketsSent.IncrementBy(uint64(sent))
r.Stats().IP.OutgoingPacketErrors.IncrementBy(uint64(remain))
return err
}
if err := e.nic.WritePacket(r, gso, ProtocolNumber, pkt); err != nil {
r.Stats().IP.OutgoingPacketErrors.Increment()
return err
}
r.Stats().IP.PacketsSent.Increment()
return nil
}
// WritePackets implements stack.NetworkEndpoint.WritePackets.
func (e *endpoint) WritePackets(r *stack.Route, gso *stack.GSO, pkts stack.PacketBufferList, params stack.NetworkHeaderParams) (int, *tcpip.Error) {
if r.Loop&stack.PacketLoop != 0 {
panic("not implemented")
}
if r.Loop&stack.PacketOut == 0 {
return pkts.Len(), nil
}
for pb := pkts.Front(); pb != nil; pb = pb.Next() {
e.addIPHeader(r, pb, params)
if e.packetMustBeFragmented(pb, gso) {
// Keep track of the packet that is about to be fragmented so it can be
// removed once the fragmentation is done.
originalPkt := pb
if _, _, err := e.handleFragments(r, gso, e.nic.MTU(), pb, params.Protocol, func(fragPkt *stack.PacketBuffer) *tcpip.Error {
// Modify the packet list in place with the new fragments.
pkts.InsertAfter(pb, fragPkt)
pb = fragPkt
return nil
}); err != nil {
r.Stats().IP.OutgoingPacketErrors.IncrementBy(uint64(pkts.Len()))
return 0, err
}
// Remove the packet that was just fragmented and process the rest.
pkts.Remove(originalPkt)
}
}
// iptables filtering. All packets that reach here are locally
// generated.
nicName := e.protocol.stack.FindNICNameFromID(e.nic.ID())
ipt := e.protocol.stack.IPTables()
dropped, natPkts := ipt.CheckPackets(stack.Output, pkts, gso, r, nicName)
if len(dropped) == 0 && len(natPkts) == 0 {
// Fast path: If no packets are to be dropped then we can just invoke the
// faster WritePackets API directly.
n, err := e.nic.WritePackets(r, gso, pkts, ProtocolNumber)
r.Stats().IP.PacketsSent.IncrementBy(uint64(n))
if err != nil {
r.Stats().IP.OutgoingPacketErrors.IncrementBy(uint64(pkts.Len() - n))
}
return n, err
}
r.Stats().IP.IPTablesOutputDropped.IncrementBy(uint64(len(dropped)))
// Slow path as we are dropping some packets in the batch degrade to
// emitting one packet at a time.
n := 0
for pkt := pkts.Front(); pkt != nil; pkt = pkt.Next() {
if _, ok := dropped[pkt]; ok {
continue
}
if _, ok := natPkts[pkt]; ok {
netHeader := header.IPv6(pkt.NetworkHeader().View())
if ep, err := e.protocol.stack.FindNetworkEndpoint(ProtocolNumber, netHeader.DestinationAddress()); err == nil {
src := netHeader.SourceAddress()
dst := netHeader.DestinationAddress()
route := r.ReverseRoute(src, dst)
ep.HandlePacket(&route, pkt)
n++
continue
}
}
if err := e.nic.WritePacket(r, gso, ProtocolNumber, pkt); err != nil {
r.Stats().IP.PacketsSent.IncrementBy(uint64(n))
r.Stats().IP.OutgoingPacketErrors.IncrementBy(uint64(pkts.Len() - n + len(dropped)))
// Dropped packets aren't errors, so include them in
// the return value.
return n + len(dropped), err
}
n++
}
r.Stats().IP.PacketsSent.IncrementBy(uint64(n))
// Dropped packets aren't errors, so include them in the return value.
return n + len(dropped), nil
}
// WriteHeaderIncludedPacker implements stack.NetworkEndpoint.
func (e *endpoint) WriteHeaderIncludedPacket(r *stack.Route, pkt *stack.PacketBuffer) *tcpip.Error {
// The packet already has an IP header, but there are a few required checks.
h, ok := pkt.Data.PullUp(header.IPv6MinimumSize)
if !ok {
return tcpip.ErrMalformedHeader
}
ip := header.IPv6(h)
// Always set the payload length.
pktSize := pkt.Data.Size()
ip.SetPayloadLength(uint16(pktSize - header.IPv6MinimumSize))
// Set the source address when zero.
if ip.SourceAddress() == header.IPv6Any {
ip.SetSourceAddress(r.LocalAddress)
}
// Set the destination. If the packet already included a destination, it will
// be part of the route anyways.
ip.SetDestinationAddress(r.RemoteAddress)
// Populate the packet buffer's network header and don't allow an invalid
// packet to be sent.
//
// Note that parsing only makes sure that the packet is well formed as per the
// wire format. We also want to check if the header's fields are valid before
// sending the packet.
proto, _, _, _, ok := parse.IPv6(pkt)
if !ok || !header.IPv6(pkt.NetworkHeader().View()).IsValid(pktSize) {
return tcpip.ErrMalformedHeader
}
return e.writePacket(r, nil /* gso */, pkt, proto)
}
// HandlePacket is called by the link layer when new ipv6 packets arrive for
// this endpoint.
func (e *endpoint) HandlePacket(r *stack.Route, pkt *stack.PacketBuffer) {
if !e.isEnabled() {
return
}
h := header.IPv6(pkt.NetworkHeader().View())
if !h.IsValid(pkt.Data.Size() + pkt.NetworkHeader().View().Size() + pkt.TransportHeader().View().Size()) {
r.Stats().IP.MalformedPacketsReceived.Increment()
return
}
// As per RFC 4291 section 2.7:
// Multicast addresses must not be used as source addresses in IPv6
// packets or appear in any Routing header.
if header.IsV6MulticastAddress(r.RemoteAddress) {
r.Stats().IP.InvalidSourceAddressesReceived.Increment()
return
}
// vv consists of:
// - Any IPv6 header bytes after the first 40 (i.e. extensions).
// - The transport header, if present.
// - Any other payload data.
vv := pkt.NetworkHeader().View()[header.IPv6MinimumSize:].ToVectorisedView()
vv.AppendView(pkt.TransportHeader().View())
vv.Append(pkt.Data)
it := header.MakeIPv6PayloadIterator(header.IPv6ExtensionHeaderIdentifier(h.NextHeader()), vv)
hasFragmentHeader := false
// iptables filtering. All packets that reach here are intended for
// this machine and need not be forwarded.
ipt := e.protocol.stack.IPTables()
if ok := ipt.Check(stack.Input, pkt, nil, nil, "", ""); !ok {
// iptables is telling us to drop the packet.
r.Stats().IP.IPTablesInputDropped.Increment()
return
}
for {
// Keep track of the start of the previous header so we can report the
// special case of a Hop by Hop at a location other than at the start.
previousHeaderStart := it.HeaderOffset()
extHdr, done, err := it.Next()
if err != nil {
r.Stats().IP.MalformedPacketsReceived.Increment()
return
}
if done {
break
}
switch extHdr := extHdr.(type) {
case header.IPv6HopByHopOptionsExtHdr:
// As per RFC 8200 section 4.1, the Hop By Hop extension header is
// restricted to appear immediately after an IPv6 fixed header.
if previousHeaderStart != 0 {
_ = e.protocol.returnError(r, &icmpReasonParameterProblem{
code: header.ICMPv6UnknownHeader,
pointer: previousHeaderStart,
}, pkt)
return
}
optsIt := extHdr.Iter()
for {
opt, done, err := optsIt.Next()
if err != nil {
r.Stats().IP.MalformedPacketsReceived.Increment()
return
}
if done {
break
}
// We currently do not support any IPv6 Hop By Hop extension header
// options.
switch opt.UnknownAction() {
case header.IPv6OptionUnknownActionSkip:
case header.IPv6OptionUnknownActionDiscard:
return
case header.IPv6OptionUnknownActionDiscardSendICMPNoMulticastDest:
if header.IsV6MulticastAddress(r.LocalAddress) {
return
}
fallthrough
case header.IPv6OptionUnknownActionDiscardSendICMP:
// This case satisfies a requirement of RFC 8200 section 4.2
// which states that an unknown option starting with bits [10] should:
//
// discard the packet and, regardless of whether or not the
// packet's Destination Address was a multicast address, send an
// ICMP Parameter Problem, Code 2, message to the packet's
// Source Address, pointing to the unrecognized Option Type.
//
_ = e.protocol.returnError(r, &icmpReasonParameterProblem{
code: header.ICMPv6UnknownOption,
pointer: it.ParseOffset() + optsIt.OptionOffset(),
respondToMulticast: true,
}, pkt)
return
default:
panic(fmt.Sprintf("unrecognized action for an unrecognized Hop By Hop extension header option = %d", opt))
}
}
case header.IPv6RoutingExtHdr:
// As per RFC 8200 section 4.4, if a node encounters a routing header with
// an unrecognized routing type value, with a non-zero Segments Left
// value, the node must discard the packet and send an ICMP Parameter
// Problem, Code 0 to the packet's Source Address, pointing to the
// unrecognized Routing Type.
//
// If the Segments Left is 0, the node must ignore the Routing extension
// header and process the next header in the packet.
//
// Note, the stack does not yet handle any type of routing extension
// header, so we just make sure Segments Left is zero before processing
// the next extension header.
if extHdr.SegmentsLeft() != 0 {
_ = e.protocol.returnError(r, &icmpReasonParameterProblem{
code: header.ICMPv6ErroneousHeader,
pointer: it.ParseOffset(),
}, pkt)
return
}
case header.IPv6FragmentExtHdr:
hasFragmentHeader = true
if extHdr.IsAtomic() {
// This fragment extension header indicates that this packet is an
// atomic fragment. An atomic fragment is a fragment that contains
// all the data required to reassemble a full packet. As per RFC 6946,
// atomic fragments must not interfere with "normal" fragmented traffic
// so we skip processing the fragment instead of feeding it through the
// reassembly process below.
continue
}
// Don't consume the iterator if we have the first fragment because we
// will use it to validate that the first fragment holds the upper layer
// header.
rawPayload := it.AsRawHeader(extHdr.FragmentOffset() != 0 /* consume */)
if extHdr.FragmentOffset() == 0 {
// Check that the iterator ends with a raw payload as the first fragment
// should include all headers up to and including any upper layer
// headers, as per RFC 8200 section 4.5; only upper layer data
// (non-headers) should follow the fragment extension header.
var lastHdr header.IPv6PayloadHeader
for {
it, done, err := it.Next()
if err != nil {
r.Stats().IP.MalformedPacketsReceived.Increment()
r.Stats().IP.MalformedFragmentsReceived.Increment()
return
}
if done {
break
}
lastHdr = it
}
// If the last header is a raw header, then the last portion of the IPv6
// payload is not a known IPv6 extension header. Note, this does not
// mean that the last portion is an upper layer header or not an
// extension header because:
// 1) we do not yet support all extension headers
// 2) we do not validate the upper layer header before reassembling.
//
// This check makes sure that a known IPv6 extension header is not
// present after the Fragment extension header in a non-initial
// fragment.
//
// TODO(#2196): Support IPv6 Authentication and Encapsulated
// Security Payload extension headers.
// TODO(#2333): Validate that the upper layer header is valid.
switch lastHdr.(type) {
case header.IPv6RawPayloadHeader:
default:
r.Stats().IP.MalformedPacketsReceived.Increment()
r.Stats().IP.MalformedFragmentsReceived.Increment()
return
}
}
fragmentPayloadLen := rawPayload.Buf.Size()
if fragmentPayloadLen == 0 {
// Drop the packet as it's marked as a fragment but has no payload.
r.Stats().IP.MalformedPacketsReceived.Increment()
r.Stats().IP.MalformedFragmentsReceived.Increment()
return
}
// The packet is a fragment, let's try to reassemble it.
start := extHdr.FragmentOffset() * header.IPv6FragmentExtHdrFragmentOffsetBytesPerUnit
// Drop the fragment if the size of the reassembled payload would exceed
// the maximum payload size.
if int(start)+fragmentPayloadLen > header.IPv6MaximumPayloadSize {
r.Stats().IP.MalformedPacketsReceived.Increment()
r.Stats().IP.MalformedFragmentsReceived.Increment()
return
}
// Note that pkt doesn't have its transport header set after reassembly,
// and won't until DeliverNetworkPacket sets it.
data, proto, ready, err := e.protocol.fragmentation.Process(
// IPv6 ignores the Protocol field since the ID only needs to be unique
// across source-destination pairs, as per RFC 8200 section 4.5.
fragmentation.FragmentID{
Source: h.SourceAddress(),
Destination: h.DestinationAddress(),
ID: extHdr.ID(),
},
start,
start+uint16(fragmentPayloadLen)-1,
extHdr.More(),
uint8(rawPayload.Identifier),
rawPayload.Buf,
)
if err != nil {
r.Stats().IP.MalformedPacketsReceived.Increment()
r.Stats().IP.MalformedFragmentsReceived.Increment()
return
}
pkt.Data = data
if ready {
// We create a new iterator with the reassembled packet because we could
// have more extension headers in the reassembled payload, as per RFC
// 8200 section 4.5. We also use the NextHeader value from the first
// fragment.
it = header.MakeIPv6PayloadIterator(header.IPv6ExtensionHeaderIdentifier(proto), pkt.Data)
}
case header.IPv6DestinationOptionsExtHdr:
optsIt := extHdr.Iter()
for {
opt, done, err := optsIt.Next()
if err != nil {
r.Stats().IP.MalformedPacketsReceived.Increment()
return
}
if done {
break
}
// We currently do not support any IPv6 Destination extension header
// options.
switch opt.UnknownAction() {
case header.IPv6OptionUnknownActionSkip:
case header.IPv6OptionUnknownActionDiscard:
return
case header.IPv6OptionUnknownActionDiscardSendICMPNoMulticastDest:
if header.IsV6MulticastAddress(r.LocalAddress) {
return
}
fallthrough
case header.IPv6OptionUnknownActionDiscardSendICMP:
// This case satisfies a requirement of RFC 8200 section 4.2
// which states that an unknown option starting with bits [10] should:
//
// discard the packet and, regardless of whether or not the
// packet's Destination Address was a multicast address, send an
// ICMP Parameter Problem, Code 2, message to the packet's
// Source Address, pointing to the unrecognized Option Type.
//
_ = e.protocol.returnError(r, &icmpReasonParameterProblem{
code: header.ICMPv6UnknownOption,
pointer: it.ParseOffset() + optsIt.OptionOffset(),
respondToMulticast: true,
}, pkt)
return
default:
panic(fmt.Sprintf("unrecognized action for an unrecognized Destination extension header option = %d", opt))
}
}
case header.IPv6RawPayloadHeader:
// If the last header in the payload isn't a known IPv6 extension header,
// handle it as if it is transport layer data.
// For unfragmented packets, extHdr still contains the transport header.
// Get rid of it.
//
// For reassembled fragments, pkt.TransportHeader is unset, so this is a
// no-op and pkt.Data begins with the transport header.
extHdr.Buf.TrimFront(pkt.TransportHeader().View().Size())
pkt.Data = extHdr.Buf
r.Stats().IP.PacketsDelivered.Increment()
if p := tcpip.TransportProtocolNumber(extHdr.Identifier); p == header.ICMPv6ProtocolNumber {
pkt.TransportProtocolNumber = p
e.handleICMP(r, pkt, hasFragmentHeader)
} else {
r.Stats().IP.PacketsDelivered.Increment()
switch res := e.dispatcher.DeliverTransportPacket(r, p, pkt); res {
case stack.TransportPacketHandled:
case stack.TransportPacketDestinationPortUnreachable:
// As per RFC 4443 section 3.1:
// A destination node SHOULD originate a Destination Unreachable
// message with Code 4 in response to a packet for which the
// transport protocol (e.g., UDP) has no listener, if that transport
// protocol has no alternative means to inform the sender.
_ = e.protocol.returnError(r, &icmpReasonPortUnreachable{}, pkt)
case stack.TransportPacketProtocolUnreachable:
// As per RFC 8200 section 4. (page 7):
// Extension headers are numbered from IANA IP Protocol Numbers
// [IANA-PN], the same values used for IPv4 and IPv6. When
// processing a sequence of Next Header values in a packet, the
// first one that is not an extension header [IANA-EH] indicates
// that the next item in the packet is the corresponding upper-layer
// header.
// With more related information on page 8:
// If, as a result of processing a header, the destination node is
// required to proceed to the next header but the Next Header value
// in the current header is unrecognized by the node, it should
// discard the packet and send an ICMP Parameter Problem message to
// the source of the packet, with an ICMP Code value of 1
// ("unrecognized Next Header type encountered") and the ICMP
// Pointer field containing the offset of the unrecognized value
// within the original packet.
//
// Which when taken together indicate that an unknown protocol should
// be treated as an unrecognized next header value.
_ = e.protocol.returnError(r, &icmpReasonParameterProblem{
code: header.ICMPv6UnknownHeader,
pointer: it.ParseOffset(),
}, pkt)
default:
panic(fmt.Sprintf("unrecognized result from DeliverTransportPacket = %d", res))
}
}
default:
_ = e.protocol.returnError(r, &icmpReasonParameterProblem{
code: header.ICMPv6UnknownHeader,
pointer: it.ParseOffset(),
}, pkt)
r.Stats().UnknownProtocolRcvdPackets.Increment()
return
}
}
}
// Close cleans up resources associated with the endpoint.
func (e *endpoint) Close() {
e.mu.Lock()
e.disableLocked()
e.mu.ndp.removeSLAACAddresses(false /* keepLinkLocal */)
e.stopDADForPermanentAddressesLocked()
e.mu.addressableEndpointState.Cleanup()
e.mu.Unlock()
e.protocol.forgetEndpoint(e)
}
// NetworkProtocolNumber implements stack.NetworkEndpoint.NetworkProtocolNumber.
func (e *endpoint) NetworkProtocolNumber() tcpip.NetworkProtocolNumber {
return e.protocol.Number()
}
// AddAndAcquirePermanentAddress implements stack.AddressableEndpoint.
func (e *endpoint) AddAndAcquirePermanentAddress(addr tcpip.AddressWithPrefix, peb stack.PrimaryEndpointBehavior, configType stack.AddressConfigType, deprecated bool) (stack.AddressEndpoint, *tcpip.Error) {
// TODO(b/169350103): add checks here after making sure we no longer receive
// an empty address.
e.mu.Lock()
defer e.mu.Unlock()
return e.addAndAcquirePermanentAddressLocked(addr, peb, configType, deprecated)
}
// addAndAcquirePermanentAddressLocked is like AddAndAcquirePermanentAddress but
// with locking requirements.
//
// addAndAcquirePermanentAddressLocked also joins the passed address's
// solicited-node multicast group and start duplicate address detection.
//
// Precondition: e.mu must be write locked.
func (e *endpoint) addAndAcquirePermanentAddressLocked(addr tcpip.AddressWithPrefix, peb stack.PrimaryEndpointBehavior, configType stack.AddressConfigType, deprecated bool) (stack.AddressEndpoint, *tcpip.Error) {
addressEndpoint, err := e.mu.addressableEndpointState.AddAndAcquirePermanentAddress(addr, peb, configType, deprecated)
if err != nil {
return nil, err
}
if !header.IsV6UnicastAddress(addr.Address) {
return addressEndpoint, nil
}
snmc := header.SolicitedNodeAddr(addr.Address)
if _, err := e.mu.addressableEndpointState.JoinGroup(snmc); err != nil {
return nil, err
}
addressEndpoint.SetKind(stack.PermanentTentative)
if e.Enabled() {
if err := e.mu.ndp.startDuplicateAddressDetection(addr.Address, addressEndpoint); err != nil {
return nil, err
}
}
return addressEndpoint, nil
}
// RemovePermanentAddress implements stack.AddressableEndpoint.
func (e *endpoint) RemovePermanentAddress(addr tcpip.Address) *tcpip.Error {
e.mu.Lock()
defer e.mu.Unlock()
addressEndpoint := e.getAddressRLocked(addr)
if addressEndpoint == nil || !addressEndpoint.GetKind().IsPermanent() {
return tcpip.ErrBadLocalAddress
}
return e.removePermanentEndpointLocked(addressEndpoint, true)
}
// removePermanentEndpointLocked is like removePermanentAddressLocked except
// it works with a stack.AddressEndpoint.
//
// Precondition: e.mu must be write locked.
func (e *endpoint) removePermanentEndpointLocked(addressEndpoint stack.AddressEndpoint, allowSLAACInvalidation bool) *tcpip.Error {
addr := addressEndpoint.AddressWithPrefix()
unicast := header.IsV6UnicastAddress(addr.Address)
if unicast {
e.mu.ndp.stopDuplicateAddressDetection(addr.Address)
// If we are removing an address generated via SLAAC, cleanup
// its SLAAC resources and notify the integrator.
switch addressEndpoint.ConfigType() {
case stack.AddressConfigSlaac:
e.mu.ndp.cleanupSLAACAddrResourcesAndNotify(addr, allowSLAACInvalidation)
case stack.AddressConfigSlaacTemp:
e.mu.ndp.cleanupTempSLAACAddrResourcesAndNotify(addr, allowSLAACInvalidation)
}
}
if err := e.mu.addressableEndpointState.RemovePermanentEndpoint(addressEndpoint); err != nil {
return err
}
if !unicast {
return nil
}
snmc := header.SolicitedNodeAddr(addr.Address)
if _, err := e.mu.addressableEndpointState.LeaveGroup(snmc); err != nil && err != tcpip.ErrBadLocalAddress {
return err
}
return nil
}
// hasPermanentAddressLocked returns true if the endpoint has a permanent
// address equal to the passed address.
//
// Precondition: e.mu must be read or write locked.
func (e *endpoint) hasPermanentAddressRLocked(addr tcpip.Address) bool {
addressEndpoint := e.getAddressRLocked(addr)
if addressEndpoint == nil {
return false
}
return addressEndpoint.GetKind().IsPermanent()
}
// getAddressRLocked returns the endpoint for the passed address.
//
// Precondition: e.mu must be read or write locked.
func (e *endpoint) getAddressRLocked(localAddr tcpip.Address) stack.AddressEndpoint {
return e.mu.addressableEndpointState.ReadOnly().Lookup(localAddr)
}
// MainAddress implements stack.AddressableEndpoint.
func (e *endpoint) MainAddress() tcpip.AddressWithPrefix {
e.mu.RLock()
defer e.mu.RUnlock()
return e.mu.addressableEndpointState.MainAddress()
}
// AcquireAssignedAddress implements stack.AddressableEndpoint.
func (e *endpoint) AcquireAssignedAddress(localAddr tcpip.Address, allowTemp bool, tempPEB stack.PrimaryEndpointBehavior) stack.AddressEndpoint {
e.mu.Lock()
defer e.mu.Unlock()
return e.acquireAddressOrCreateTempLocked(localAddr, allowTemp, tempPEB)
}
// acquireAddressOrCreateTempLocked is like AcquireAssignedAddress but with
// locking requirements.
//
// Precondition: e.mu must be write locked.
func (e *endpoint) acquireAddressOrCreateTempLocked(localAddr tcpip.Address, allowTemp bool, tempPEB stack.PrimaryEndpointBehavior) stack.AddressEndpoint {
return e.mu.addressableEndpointState.AcquireAssignedAddress(localAddr, allowTemp, tempPEB)
}
// AcquireOutgoingPrimaryAddress implements stack.AddressableEndpoint.
func (e *endpoint) AcquireOutgoingPrimaryAddress(remoteAddr tcpip.Address, allowExpired bool) stack.AddressEndpoint {
e.mu.RLock()
defer e.mu.RUnlock()
return e.acquireOutgoingPrimaryAddressRLocked(remoteAddr, allowExpired)
}
// acquireOutgoingPrimaryAddressRLocked is like AcquireOutgoingPrimaryAddress
// but with locking requirements.
//
// Precondition: e.mu must be read locked.
func (e *endpoint) acquireOutgoingPrimaryAddressRLocked(remoteAddr tcpip.Address, allowExpired bool) stack.AddressEndpoint {
// addrCandidate is a candidate for Source Address Selection, as per
// RFC 6724 section 5.
type addrCandidate struct {
addressEndpoint stack.AddressEndpoint
scope header.IPv6AddressScope
}
if len(remoteAddr) == 0 {
return e.mu.addressableEndpointState.AcquireOutgoingPrimaryAddress(remoteAddr, allowExpired)
}
// Create a candidate set of available addresses we can potentially use as a
// source address.
var cs []addrCandidate
e.mu.addressableEndpointState.ReadOnly().ForEachPrimaryEndpoint(func(addressEndpoint stack.AddressEndpoint) {
// If r is not valid for outgoing connections, it is not a valid endpoint.
if !addressEndpoint.IsAssigned(allowExpired) {
return
}
addr := addressEndpoint.AddressWithPrefix().Address
scope, err := header.ScopeForIPv6Address(addr)
if err != nil {
// Should never happen as we got r from the primary IPv6 endpoint list and
// ScopeForIPv6Address only returns an error if addr is not an IPv6
// address.
panic(fmt.Sprintf("header.ScopeForIPv6Address(%s): %s", addr, err))
}
cs = append(cs, addrCandidate{
addressEndpoint: addressEndpoint,
scope: scope,
})
})
remoteScope, err := header.ScopeForIPv6Address(remoteAddr)
if err != nil {
// primaryIPv6Endpoint should never be called with an invalid IPv6 address.
panic(fmt.Sprintf("header.ScopeForIPv6Address(%s): %s", remoteAddr, err))
}
// Sort the addresses as per RFC 6724 section 5 rules 1-3.
//
// TODO(b/146021396): Implement rules 4-8 of RFC 6724 section 5.
sort.Slice(cs, func(i, j int) bool {
sa := cs[i]
sb := cs[j]
// Prefer same address as per RFC 6724 section 5 rule 1.
if sa.addressEndpoint.AddressWithPrefix().Address == remoteAddr {
return true
}
if sb.addressEndpoint.AddressWithPrefix().Address == remoteAddr {
return false
}
// Prefer appropriate scope as per RFC 6724 section 5 rule 2.
if sa.scope < sb.scope {
return sa.scope >= remoteScope
} else if sb.scope < sa.scope {
return sb.scope < remoteScope
}
// Avoid deprecated addresses as per RFC 6724 section 5 rule 3.
if saDep, sbDep := sa.addressEndpoint.Deprecated(), sb.addressEndpoint.Deprecated(); saDep != sbDep {
// If sa is not deprecated, it is preferred over sb.
return sbDep
}
// Prefer temporary addresses as per RFC 6724 section 5 rule 7.
if saTemp, sbTemp := sa.addressEndpoint.ConfigType() == stack.AddressConfigSlaacTemp, sb.addressEndpoint.ConfigType() == stack.AddressConfigSlaacTemp; saTemp != sbTemp {
return saTemp
}
// sa and sb are equal, return the endpoint that is closest to the front of
// the primary endpoint list.
return i < j
})
// Return the most preferred address that can have its reference count
// incremented.
for _, c := range cs {
if c.addressEndpoint.IncRef() {
return c.addressEndpoint
}
}
return nil
}
// PrimaryAddresses implements stack.AddressableEndpoint.
func (e *endpoint) PrimaryAddresses() []tcpip.AddressWithPrefix {
e.mu.RLock()
defer e.mu.RUnlock()
return e.mu.addressableEndpointState.PrimaryAddresses()
}
// PermanentAddresses implements stack.AddressableEndpoint.
func (e *endpoint) PermanentAddresses() []tcpip.AddressWithPrefix {
e.mu.RLock()
defer e.mu.RUnlock()
return e.mu.addressableEndpointState.PermanentAddresses()
}
// JoinGroup implements stack.GroupAddressableEndpoint.
func (e *endpoint) JoinGroup(addr tcpip.Address) (bool, *tcpip.Error) {
if !header.IsV6MulticastAddress(addr) {
return false, tcpip.ErrBadAddress
}
e.mu.Lock()
defer e.mu.Unlock()
return e.mu.addressableEndpointState.JoinGroup(addr)
}
// LeaveGroup implements stack.GroupAddressableEndpoint.
func (e *endpoint) LeaveGroup(addr tcpip.Address) (bool, *tcpip.Error) {
e.mu.Lock()
defer e.mu.Unlock()
return e.mu.addressableEndpointState.LeaveGroup(addr)
}
// IsInGroup implements stack.GroupAddressableEndpoint.
func (e *endpoint) IsInGroup(addr tcpip.Address) bool {
e.mu.RLock()
defer e.mu.RUnlock()
return e.mu.addressableEndpointState.IsInGroup(addr)
}
var _ stack.ForwardingNetworkProtocol = (*protocol)(nil)
var _ stack.NetworkProtocol = (*protocol)(nil)
type protocol struct {
stack *stack.Stack
mu struct {
sync.RWMutex
eps map[*endpoint]struct{}
}
ids []uint32
hashIV uint32
// defaultTTL is the current default TTL for the protocol. Only the
// uint8 portion of it is meaningful.
//
// Must be accessed using atomic operations.
defaultTTL uint32
// forwarding is set to 1 when the protocol has forwarding enabled and 0
// when it is disabled.
//
// Must be accessed using atomic operations.
forwarding uint32
fragmentation *fragmentation.Fragmentation
// ndpDisp is the NDP event dispatcher that is used to send the netstack
// integrator NDP related events.
ndpDisp NDPDispatcher
// ndpConfigs is the default NDP configurations used by an IPv6 endpoint.
ndpConfigs NDPConfigurations
// opaqueIIDOpts hold the options for generating opaque interface identifiers
// (IIDs) as outlined by RFC 7217.
opaqueIIDOpts OpaqueInterfaceIdentifierOptions
// tempIIDSeed is used to seed the initial temporary interface identifier
// history value used to generate IIDs for temporary SLAAC addresses.
tempIIDSeed []byte
// autoGenIPv6LinkLocal determines whether or not the stack attempts to
// auto-generate an IPv6 link-local address for newly enabled non-loopback
// NICs. See the AutoGenIPv6LinkLocal field of Options for more details.
autoGenIPv6LinkLocal bool
}
// Number returns the ipv6 protocol number.
func (p *protocol) Number() tcpip.NetworkProtocolNumber {
return ProtocolNumber
}
// MinimumPacketSize returns the minimum valid ipv6 packet size.
func (p *protocol) MinimumPacketSize() int {
return header.IPv6MinimumSize
}
// DefaultPrefixLen returns the IPv6 default prefix length.
func (p *protocol) DefaultPrefixLen() int {
return header.IPv6AddressSize * 8
}
// ParseAddresses implements NetworkProtocol.ParseAddresses.
func (*protocol) ParseAddresses(v buffer.View) (src, dst tcpip.Address) {
h := header.IPv6(v)
return h.SourceAddress(), h.DestinationAddress()
}
// NewEndpoint creates a new ipv6 endpoint.
func (p *protocol) NewEndpoint(nic stack.NetworkInterface, linkAddrCache stack.LinkAddressCache, nud stack.NUDHandler, dispatcher stack.TransportDispatcher) stack.NetworkEndpoint {
e := &endpoint{
nic: nic,
linkAddrCache: linkAddrCache,
nud: nud,
dispatcher: dispatcher,
protocol: p,
}
e.mu.addressableEndpointState.Init(e)
e.mu.ndp = ndpState{
ep: e,
configs: p.ndpConfigs,
dad: make(map[tcpip.Address]dadState),
defaultRouters: make(map[tcpip.Address]defaultRouterState),
onLinkPrefixes: make(map[tcpip.Subnet]onLinkPrefixState),
slaacPrefixes: make(map[tcpip.Subnet]slaacPrefixState),
}
e.mu.ndp.initializeTempAddrState()
p.mu.Lock()
defer p.mu.Unlock()
p.mu.eps[e] = struct{}{}
return e
}
func (p *protocol) forgetEndpoint(e *endpoint) {
p.mu.Lock()
defer p.mu.Unlock()
delete(p.mu.eps, e)
}
// SetOption implements NetworkProtocol.SetOption.
func (p *protocol) SetOption(option tcpip.SettableNetworkProtocolOption) *tcpip.Error {
switch v := option.(type) {
case *tcpip.DefaultTTLOption:
p.SetDefaultTTL(uint8(*v))
return nil
default:
return tcpip.ErrUnknownProtocolOption
}
}
// Option implements NetworkProtocol.Option.
func (p *protocol) Option(option tcpip.GettableNetworkProtocolOption) *tcpip.Error {
switch v := option.(type) {
case *tcpip.DefaultTTLOption:
*v = tcpip.DefaultTTLOption(p.DefaultTTL())
return nil
default:
return tcpip.ErrUnknownProtocolOption
}
}
// SetDefaultTTL sets the default TTL for endpoints created with this protocol.
func (p *protocol) SetDefaultTTL(ttl uint8) {
atomic.StoreUint32(&p.defaultTTL, uint32(ttl))
}
// DefaultTTL returns the default TTL for endpoints created with this protocol.
func (p *protocol) DefaultTTL() uint8 {
return uint8(atomic.LoadUint32(&p.defaultTTL))
}
// Close implements stack.TransportProtocol.Close.
func (*protocol) Close() {}
// Wait implements stack.TransportProtocol.Wait.
func (*protocol) Wait() {}
// Parse implements stack.NetworkProtocol.Parse.
func (*protocol) Parse(pkt *stack.PacketBuffer) (proto tcpip.TransportProtocolNumber, hasTransportHdr bool, ok bool) {
proto, _, fragOffset, fragMore, ok := parse.IPv6(pkt)
if !ok {
return 0, false, false
}
return proto, !fragMore && fragOffset == 0, true
}
// Forwarding implements stack.ForwardingNetworkProtocol.
func (p *protocol) Forwarding() bool {
return uint8(atomic.LoadUint32(&p.forwarding)) == 1
}
// setForwarding sets the forwarding status for the protocol.
//
// Returns true if the forwarding status was updated.
func (p *protocol) setForwarding(v bool) bool {
if v {
return atomic.SwapUint32(&p.forwarding, 1) == 0
}
return atomic.SwapUint32(&p.forwarding, 0) == 1
}
// SetForwarding implements stack.ForwardingNetworkProtocol.
func (p *protocol) SetForwarding(v bool) {
p.mu.Lock()
defer p.mu.Unlock()
if !p.setForwarding(v) {
return
}
for ep := range p.mu.eps {
ep.transitionForwarding(v)
}
}
// calculateMTU calculates the network-layer payload MTU based on the link-layer
// payload mtu.
func calculateMTU(mtu uint32) uint32 {
mtu -= header.IPv6MinimumSize
if mtu <= maxPayloadSize {
return mtu
}
return maxPayloadSize
}
// Options holds options to configure a new protocol.
type Options struct {
// NDPConfigs is the default NDP configurations used by interfaces.
NDPConfigs NDPConfigurations
// AutoGenIPv6LinkLocal determines whether or not the stack attempts to
// auto-generate an IPv6 link-local address for newly enabled non-loopback
// NICs.
//
// Note, setting this to true does not mean that a link-local address is
// assigned right away, or at all. If Duplicate Address Detection is enabled,
// an address is only assigned if it successfully resolves. If it fails, no
// further attempts are made to auto-generate an IPv6 link-local adddress.
//
// The generated link-local address follows RFC 4291 Appendix A guidelines.
AutoGenIPv6LinkLocal bool
// NDPDisp is the NDP event dispatcher that an integrator can provide to
// receive NDP related events.
NDPDisp NDPDispatcher
// OpaqueIIDOpts hold the options for generating opaque interface
// identifiers (IIDs) as outlined by RFC 7217.
OpaqueIIDOpts OpaqueInterfaceIdentifierOptions
// TempIIDSeed is used to seed the initial temporary interface identifier
// history value used to generate IIDs for temporary SLAAC addresses.
//
// Temporary SLAAC adresses are short-lived addresses which are unpredictable
// and random from the perspective of other nodes on the network. It is
// recommended that the seed be a random byte buffer of at least
// header.IIDSize bytes to make sure that temporary SLAAC addresses are
// sufficiently random. It should follow minimum randomness requirements for
// security as outlined by RFC 4086.
//
// Note: using a nil value, the same seed across netstack program runs, or a
// seed that is too small would reduce randomness and increase predictability,
// defeating the purpose of temporary SLAAC addresses.
TempIIDSeed []byte
}
// NewProtocolWithOptions returns an IPv6 network protocol.
func NewProtocolWithOptions(opts Options) stack.NetworkProtocolFactory {
opts.NDPConfigs.validate()
ids := hash.RandN32(buckets)
hashIV := hash.RandN32(1)[0]
return func(s *stack.Stack) stack.NetworkProtocol {
p := &protocol{
stack: s,
fragmentation: fragmentation.NewFragmentation(header.IPv6FragmentExtHdrFragmentOffsetBytesPerUnit, fragmentation.HighFragThreshold, fragmentation.LowFragThreshold, reassembleTimeout, s.Clock()),
ids: ids,
hashIV: hashIV,
ndpDisp: opts.NDPDisp,
ndpConfigs: opts.NDPConfigs,
opaqueIIDOpts: opts.OpaqueIIDOpts,
tempIIDSeed: opts.TempIIDSeed,
autoGenIPv6LinkLocal: opts.AutoGenIPv6LinkLocal,
}
p.mu.eps = make(map[*endpoint]struct{})
p.SetDefaultTTL(DefaultTTL)
return p
}
}
// NewProtocol is equivalent to NewProtocolWithOptions with an empty Options.
func NewProtocol(s *stack.Stack) stack.NetworkProtocol {
return NewProtocolWithOptions(Options{})(s)
}
// calculateFragmentInnerMTU calculates the maximum number of bytes of
// fragmentable data a fragment can have, based on the link layer mtu and pkt's
// network header size.
func calculateFragmentInnerMTU(mtu uint32, pkt *stack.PacketBuffer) uint32 {
// TODO(gvisor.dev/issue/3912): Once the Authentication or ESP Headers are
// supported for outbound packets, their length should not affect the fragment
// MTU because they should only be transmitted once.
mtu -= uint32(pkt.NetworkHeader().View().Size())
mtu -= header.IPv6FragmentHeaderSize
// Round the MTU down to align to 8 bytes.
mtu &^= 7
if mtu <= maxPayloadSize {
return mtu
}
return maxPayloadSize
}
func calculateFragmentReserve(pkt *stack.PacketBuffer) int {
return pkt.AvailableHeaderBytes() + pkt.NetworkHeader().View().Size() + header.IPv6FragmentHeaderSize
}
// hashRoute calculates a hash value for the given route. It uses the source &
// destination address and 32-bit number to generate the hash.
func hashRoute(r *stack.Route, hashIV uint32) uint32 {
// The FNV-1a was chosen because it is a fast hashing algorithm, and
// cryptographic properties are not needed here.
h := fnv.New32a()
if _, err := h.Write([]byte(r.LocalAddress)); err != nil {
panic(fmt.Sprintf("Hash.Write: %s, but Hash' implementation of Write is not expected to ever return an error", err))
}
if _, err := h.Write([]byte(r.RemoteAddress)); err != nil {
panic(fmt.Sprintf("Hash.Write: %s, but Hash' implementation of Write is not expected to ever return an error", err))
}
s := make([]byte, 4)
binary.LittleEndian.PutUint32(s, hashIV)
if _, err := h.Write(s); err != nil {
panic(fmt.Sprintf("Hash.Write: %s, but Hash' implementation of Write is not expected ever to return an error", err))
}
return h.Sum32()
}
func buildNextFragment(pf *fragmentation.PacketFragmenter, originalIPHeaders header.IPv6, transportProto tcpip.TransportProtocolNumber, id uint32) (*stack.PacketBuffer, bool) {
fragPkt, offset, copied, more := pf.BuildNextFragment()
fragPkt.NetworkProtocolNumber = ProtocolNumber
originalIPHeadersLength := len(originalIPHeaders)
fragmentIPHeadersLength := originalIPHeadersLength + header.IPv6FragmentHeaderSize
fragmentIPHeaders := header.IPv6(fragPkt.NetworkHeader().Push(fragmentIPHeadersLength))
// Copy the IPv6 header and any extension headers already populated.
if copied := copy(fragmentIPHeaders, originalIPHeaders); copied != originalIPHeadersLength {
panic(fmt.Sprintf("wrong number of bytes copied into fragmentIPHeaders: got %d, want %d", copied, originalIPHeadersLength))
}
fragmentIPHeaders.SetNextHeader(header.IPv6FragmentHeader)
fragmentIPHeaders.SetPayloadLength(uint16(copied + fragmentIPHeadersLength - header.IPv6MinimumSize))
fragmentHeader := header.IPv6Fragment(fragmentIPHeaders[originalIPHeadersLength:])
fragmentHeader.Encode(&header.IPv6FragmentFields{
M: more,
FragmentOffset: uint16(offset / header.IPv6FragmentExtHdrFragmentOffsetBytesPerUnit),
Identification: id,
NextHeader: uint8(transportProto),
})
return fragPkt, more
}
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