// Copyright 2021 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 ipv4 contains the implementation of the ipv4 network protocol. package ipv4 import ( "fmt" "math" "reflect" "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 ( // ReassembleTimeout is the time a packet stays in the reassembly // system before being evicted. // As per RFC 791 section 3.2: // The current recommendation for the initial timer setting is 15 seconds. // This may be changed as experience with this protocol accumulates. // // Considering that it is an old recommendation, we use the same reassembly // timeout that linux defines, which is 30 seconds: // https://github.com/torvalds/linux/blob/47ec5303d73ea344e84f46660fff693c57641386/include/net/ip.h#L138 ReassembleTimeout = 30 * time.Second // ProtocolNumber is the ipv4 protocol number. ProtocolNumber = header.IPv4ProtocolNumber // MaxTotalSize is maximum size that can be encoded in the 16-bit // TotalLength field of the ipv4 header. MaxTotalSize = 0xffff // DefaultTTL is the default time-to-live value for this endpoint. DefaultTTL = 64 // buckets is the number of identifier buckets. buckets = 2048 // The size of a fragment block, in bytes, as per RFC 791 section 3.1, // page 14. fragmentblockSize = 8 ) var ipv4BroadcastAddr = header.IPv4Broadcast.WithPrefix() var _ stack.LinkResolvableNetworkEndpoint = (*endpoint)(nil) var _ stack.GroupAddressableEndpoint = (*endpoint)(nil) var _ stack.AddressableEndpoint = (*endpoint)(nil) var _ stack.NetworkEndpoint = (*endpoint)(nil) type endpoint struct { nic stack.NetworkInterface dispatcher stack.TransportDispatcher protocol *protocol stats sharedStats // enabled is set to 1 when the enpoint is enabled and 0 when it is // disabled. // // Must be accessed using atomic operations. enabled uint32 mu struct { sync.RWMutex addressableEndpointState stack.AddressableEndpointState igmp igmpState } } // HandleLinkResolutionFailure implements stack.LinkResolvableNetworkEndpoint. func (e *endpoint) HandleLinkResolutionFailure(pkt *stack.PacketBuffer) { // handleControl expects the entire offending packet to be in the packet // buffer's data field. pkt = stack.NewPacketBuffer(stack.PacketBufferOptions{ Data: buffer.NewVectorisedView(pkt.Size(), pkt.Views()), }) pkt.NICID = e.nic.ID() pkt.NetworkProtocolNumber = ProtocolNumber // Use the same control type as an ICMPv4 destination host unreachable error // since the host is considered unreachable if we cannot resolve the link // address to the next hop. e.handleControl(stack.ControlNoRoute, 0, pkt) } // NewEndpoint creates a new ipv4 endpoint. func (p *protocol) NewEndpoint(nic stack.NetworkInterface, _ stack.LinkAddressCache, _ stack.NUDHandler, dispatcher stack.TransportDispatcher) stack.NetworkEndpoint { e := &endpoint{ nic: nic, dispatcher: dispatcher, protocol: p, } e.mu.Lock() e.mu.addressableEndpointState.Init(e) e.mu.igmp.init(e) e.mu.Unlock() tcpip.InitStatCounters(reflect.ValueOf(&e.stats.localStats).Elem()) stackStats := p.stack.Stats() e.stats.ip.Init(&e.stats.localStats.IP, &stackStats.IP) e.stats.icmp.init(&e.stats.localStats.ICMP, &stackStats.ICMP.V4) e.stats.igmp.init(&e.stats.localStats.IGMP, &stackStats.IGMP) p.mu.Lock() p.mu.eps[nic.ID()] = e p.mu.Unlock() return e } func (p *protocol) forgetEndpoint(nicID tcpip.NICID) { p.mu.Lock() defer p.mu.Unlock() delete(p.mu.eps, nicID) } // 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 } // Create an endpoint to receive broadcast packets on this interface. ep, err := e.mu.addressableEndpointState.AddAndAcquirePermanentAddress(ipv4BroadcastAddr, stack.NeverPrimaryEndpoint, stack.AddressConfigStatic, false /* deprecated */) if err != nil { return err } // We have no need for the address endpoint. ep.DecRef() // Groups may have been joined while the endpoint was disabled, or the // endpoint may have left groups from the perspective of IGMP when the // endpoint was disabled. Either way, we need to let routers know to // send us multicast traffic. e.mu.igmp.initializeAll() // As per RFC 1122 section 3.3.7, all hosts should join the all-hosts // multicast group. Note, the IANA calls the all-hosts multicast group the // all-systems multicast group. if err := e.joinGroupLocked(header.IPv4AllSystems); err != nil { // joinGroupLocked only returns an error if the group address is not a valid // IPv4 multicast address. panic(fmt.Sprintf("e.joinGroupLocked(%s): %s", header.IPv4AllSystems, err)) } 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.isEnabled() { return } // The endpoint may have already left the multicast group. switch err := e.leaveGroupLocked(header.IPv4AllSystems); err.(type) { case nil, *tcpip.ErrBadLocalAddress: default: panic(fmt.Sprintf("unexpected error when leaving group = %s: %s", header.IPv4AllSystems, err)) } // Leave groups from the perspective of IGMP so that routers know that // we are no longer interested in the group. e.mu.igmp.softLeaveAll() // The address may have already been removed. switch err := e.mu.addressableEndpointState.RemovePermanentAddress(ipv4BroadcastAddr.Address); err.(type) { case nil, *tcpip.ErrBadLocalAddress: default: panic(fmt.Sprintf("unexpected error when removing address = %s: %s", ipv4BroadcastAddr.Address, err)) } // Reset the IGMP V1 present flag. // // If the node comes back up on the same network, it will re-learn that it // needs to perform IGMPv1. e.mu.igmp.resetV1Present() if !e.setEnabled(false) { panic("should have only done work to disable the endpoint if it was enabled") } } // DefaultTTL is the default time-to-live value 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 { networkMTU, err := calculateNetworkMTU(e.nic.MTU(), header.IPv4MinimumSize) if err != nil { return 0 } return networkMTU } // MaxHeaderLength returns the maximum length needed by ipv4 headers (and // underlying protocols). func (e *endpoint) MaxHeaderLength() uint16 { return e.nic.MaxHeaderLength() + header.IPv4MaximumHeaderSize } // NetworkProtocolNumber implements stack.NetworkEndpoint.NetworkProtocolNumber. func (e *endpoint) NetworkProtocolNumber() tcpip.NetworkProtocolNumber { return e.protocol.Number() } func (e *endpoint) addIPHeader(srcAddr, dstAddr tcpip.Address, pkt *stack.PacketBuffer, params stack.NetworkHeaderParams, options header.IPv4OptionsSerializer) tcpip.Error { hdrLen := header.IPv4MinimumSize var optLen int if options != nil { optLen = int(options.Length()) } hdrLen += optLen if hdrLen > header.IPv4MaximumHeaderSize { return &tcpip.ErrMessageTooLong{} } ip := header.IPv4(pkt.NetworkHeader().Push(hdrLen)) length := pkt.Size() if length > math.MaxUint16 { return &tcpip.ErrMessageTooLong{} } // RFC 6864 section 4.3 mandates uniqueness of ID values for non-atomic // datagrams. Since the DF bit is never being set here, all datagrams // are non-atomic and need an ID. id := atomic.AddUint32(&e.protocol.ids[hashRoute(srcAddr, dstAddr, params.Protocol, e.protocol.hashIV)%buckets], 1) ip.Encode(&header.IPv4Fields{ TotalLength: uint16(length), ID: uint16(id), TTL: params.TTL, TOS: params.TOS, Protocol: uint8(params.Protocol), SrcAddr: srcAddr, DstAddr: dstAddr, Options: options, }) ip.SetChecksum(^ip.CalculateChecksum()) pkt.NetworkProtocolNumber = ProtocolNumber return nil } // 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. func (e *endpoint) handleFragments(r *stack.Route, gso *stack.GSO, networkMTU uint32, pkt *stack.PacketBuffer, handler func(*stack.PacketBuffer) tcpip.Error) (int, int, tcpip.Error) { // Round the MTU down to align to 8 bytes. fragmentPayloadSize := networkMTU &^ 7 networkHeader := header.IPv4(pkt.NetworkHeader().View()) pf := fragmentation.MakePacketFragmenter(pkt, fragmentPayloadSize, pkt.AvailableHeaderBytes()+len(networkHeader)) var n int for { fragPkt, more := buildNextFragment(&pf, networkHeader) 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 { if err := e.addIPHeader(r.LocalAddress, r.RemoteAddress, pkt, params, nil /* options */); err != nil { return err } // iptables filtering. All packets that reach here are locally // generated. outNicName := e.protocol.stack.FindNICNameFromID(e.nic.ID()) if ok := e.protocol.stack.IPTables().Check(stack.Output, pkt, gso, r, "" /* preroutingAddr */, "" /* inNicName */, outNicName); !ok { // iptables is telling us to drop the packet. e.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.IPv4(pkt.NetworkHeader().View()) ep, err := e.protocol.stack.FindNetworkEndpoint(ProtocolNumber, netHeader.DestinationAddress()) if err == nil { pkt := pkt.CloneToInbound() if e.protocol.stack.ParsePacketBuffer(ProtocolNumber, pkt) == stack.ParsedOK { // Since we rewrote the packet but it is being routed back to us, we can // safely assume the checksum is valid. pkt.RXTransportChecksumValidated = true ep.(*endpoint).handlePacket(pkt) } return nil } } return e.writePacket(r, gso, pkt, false /* headerIncluded */) } func (e *endpoint) writePacket(r *stack.Route, gso *stack.GSO, pkt *stack.PacketBuffer, headerIncluded bool) tcpip.Error { if r.Loop&stack.PacketLoop != 0 { pkt := pkt.CloneToInbound() if e.protocol.stack.ParsePacketBuffer(ProtocolNumber, pkt) == stack.ParsedOK { // If the packet was generated by the stack (not a raw/packet endpoint // where a packet may be written with the header included), then we can // safely assume the checksum is valid. pkt.RXTransportChecksumValidated = !headerIncluded e.handlePacket(pkt) } } if r.Loop&stack.PacketOut == 0 { return nil } stats := e.stats.ip networkMTU, err := calculateNetworkMTU(e.nic.MTU(), uint32(pkt.NetworkHeader().View().Size())) if err != nil { stats.OutgoingPacketErrors.Increment() return err } if packetMustBeFragmented(pkt, networkMTU, gso) { sent, remain, err := e.handleFragments(r, gso, networkMTU, pkt, 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) }) stats.PacketsSent.IncrementBy(uint64(sent)) stats.OutgoingPacketErrors.IncrementBy(uint64(remain)) return err } if err := e.nic.WritePacket(r, gso, ProtocolNumber, pkt); err != nil { stats.OutgoingPacketErrors.Increment() return err } stats.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("multiple packets in local loop") } if r.Loop&stack.PacketOut == 0 { return pkts.Len(), nil } stats := e.stats.ip for pkt := pkts.Front(); pkt != nil; pkt = pkt.Next() { if err := e.addIPHeader(r.LocalAddress, r.RemoteAddress, pkt, params, nil /* options */); err != nil { return 0, err } networkMTU, err := calculateNetworkMTU(e.nic.MTU(), uint32(pkt.NetworkHeader().View().Size())) if err != nil { stats.OutgoingPacketErrors.IncrementBy(uint64(pkts.Len())) return 0, err } if packetMustBeFragmented(pkt, networkMTU, gso) { // Keep track of the packet that is about to be fragmented so it can be // removed once the fragmentation is done. originalPkt := pkt if _, _, err := e.handleFragments(r, gso, networkMTU, pkt, func(fragPkt *stack.PacketBuffer) tcpip.Error { // Modify the packet list in place with the new fragments. pkts.InsertAfter(pkt, fragPkt) pkt = fragPkt return nil }); err != nil { panic(fmt.Sprintf("e.handleFragments(_, _, %d, _, _) = %s", networkMTU, err)) } // Remove the packet that was just fragmented and process the rest. pkts.Remove(originalPkt) } } outNicName := e.protocol.stack.FindNICNameFromID(e.nic.ID()) // iptables filtering. All packets that reach here are locally // generated. dropped, natPkts := e.protocol.stack.IPTables().CheckPackets(stack.Output, pkts, gso, r, "", outNicName) 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) stats.PacketsSent.IncrementBy(uint64(n)) if err != nil { stats.OutgoingPacketErrors.IncrementBy(uint64(pkts.Len() - n)) } return n, err } stats.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.IPv4(pkt.NetworkHeader().View()) if ep, err := e.protocol.stack.FindNetworkEndpoint(ProtocolNumber, netHeader.DestinationAddress()); err == nil { pkt := pkt.CloneToInbound() if e.protocol.stack.ParsePacketBuffer(ProtocolNumber, pkt) == stack.ParsedOK { // Since we rewrote the packet but it is being routed back to us, we // can safely assume the checksum is valid. pkt.RXTransportChecksumValidated = true ep.(*endpoint).handlePacket(pkt) } n++ continue } } if err := e.nic.WritePacket(r, gso, ProtocolNumber, pkt); err != nil { stats.PacketsSent.IncrementBy(uint64(n)) stats.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++ } stats.PacketsSent.IncrementBy(uint64(n)) // Dropped packets aren't errors, so include them in the return value. return n + len(dropped), nil } // WriteHeaderIncludedPacket 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.IPv4MinimumSize) if !ok { return &tcpip.ErrMalformedHeader{} } hdrLen := header.IPv4(h).HeaderLength() if hdrLen < header.IPv4MinimumSize { return &tcpip.ErrMalformedHeader{} } h, ok = pkt.Data.PullUp(int(hdrLen)) if !ok { return &tcpip.ErrMalformedHeader{} } ip := header.IPv4(h) // Always set the total length. pktSize := pkt.Data.Size() ip.SetTotalLength(uint16(pktSize)) // Set the source address when zero. if ip.SourceAddress() == header.IPv4Any { 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) // Set the packet ID when zero. if ip.ID() == 0 { // RFC 6864 section 4.3 mandates uniqueness of ID values for // non-atomic datagrams, so assign an ID to all such datagrams // according to the definition given in RFC 6864 section 4. if ip.Flags()&header.IPv4FlagDontFragment == 0 || ip.Flags()&header.IPv4FlagMoreFragments != 0 || ip.FragmentOffset() > 0 { ip.SetID(uint16(atomic.AddUint32(&e.protocol.ids[hashRoute(r.LocalAddress, r.RemoteAddress, 0 /* protocol */, e.protocol.hashIV)%buckets], 1))) } } // Always set the checksum. ip.SetChecksum(0) ip.SetChecksum(^ip.CalculateChecksum()) // 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. if !parse.IPv4(pkt) || !header.IPv4(pkt.NetworkHeader().View()).IsValid(pktSize) { return &tcpip.ErrMalformedHeader{} } return e.writePacket(r, nil /* gso */, pkt, true /* headerIncluded */) } // forwardPacket attempts to forward a packet to its final destination. func (e *endpoint) forwardPacket(pkt *stack.PacketBuffer) tcpip.Error { h := header.IPv4(pkt.NetworkHeader().View()) ttl := h.TTL() if ttl == 0 { // As per RFC 792 page 6, Time Exceeded Message, // // If the gateway processing a datagram finds the time to live field // is zero it must discard the datagram. The gateway may also notify // the source host via the time exceeded message. return e.protocol.returnError(&icmpReasonTTLExceeded{}, pkt) } dstAddr := h.DestinationAddress() // Check if the destination is owned by the stack. networkEndpoint, err := e.protocol.stack.FindNetworkEndpoint(ProtocolNumber, dstAddr) if err == nil { networkEndpoint.(*endpoint).handlePacket(pkt) return nil } if _, ok := err.(*tcpip.ErrBadAddress); !ok { return err } r, err := e.protocol.stack.FindRoute(0, "", dstAddr, ProtocolNumber, false /* multicastLoop */) if err != nil { return err } defer r.Release() // We need to do a deep copy of the IP packet because // WriteHeaderIncludedPacket takes ownership of the packet buffer, but we do // not own it. newHdr := header.IPv4(stack.PayloadSince(pkt.NetworkHeader())) // As per RFC 791 page 30, Time to Live, // // This field must be decreased at each point that the internet header // is processed to reflect the time spent processing the datagram. // Even if no local information is available on the time actually // spent, the field must be decremented by 1. newHdr.SetTTL(ttl - 1) return r.WriteHeaderIncludedPacket(stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: int(r.MaxHeaderLength()), Data: buffer.View(newHdr).ToVectorisedView(), })) } // HandlePacket is called by the link layer when new ipv4 packets arrive for // this endpoint. func (e *endpoint) HandlePacket(pkt *stack.PacketBuffer) { stats := e.stats.ip stats.PacketsReceived.Increment() if !e.isEnabled() { stats.DisabledPacketsReceived.Increment() return } // Loopback traffic skips the prerouting chain. if !e.nic.IsLoopback() { inNicName := e.protocol.stack.FindNICNameFromID(e.nic.ID()) if ok := e.protocol.stack.IPTables().Check(stack.Prerouting, pkt, nil, nil, e.MainAddress().Address, inNicName, "" /* outNicName */); !ok { // iptables is telling us to drop the packet. stats.IPTablesPreroutingDropped.Increment() return } } e.handlePacket(pkt) } // handlePacket is like HandlePacket except it does not perform the prerouting // iptables hook. func (e *endpoint) handlePacket(pkt *stack.PacketBuffer) { pkt.NICID = e.nic.ID() stats := e.stats h := header.IPv4(pkt.NetworkHeader().View()) if !h.IsValid(pkt.Data.Size() + pkt.NetworkHeader().View().Size() + pkt.TransportHeader().View().Size()) { stats.ip.MalformedPacketsReceived.Increment() return } // There has been some confusion regarding verifying checksums. We need // just look for negative 0 (0xffff) as the checksum, as it's not possible to // get positive 0 (0) for the checksum. Some bad implementations could get it // when doing entry replacement in the early days of the Internet, // however the lore that one needs to check for both persists. // // RFC 1624 section 1 describes the source of this confusion as: // [the partial recalculation method described in RFC 1071] computes a // result for certain cases that differs from the one obtained from // scratch (one's complement of one's complement sum of the original // fields). // // However RFC 1624 section 5 clarifies that if using the verification method // "recommended by RFC 1071, it does not matter if an intermediate system // generated a -0 instead of +0". // // RFC1071 page 1 specifies the verification method as: // (3) To check a checksum, the 1's complement sum is computed over the // same set of octets, including the checksum field. If the result // is all 1 bits (-0 in 1's complement arithmetic), the check // succeeds. if h.CalculateChecksum() != 0xffff { stats.ip.MalformedPacketsReceived.Increment() return } srcAddr := h.SourceAddress() dstAddr := h.DestinationAddress() // As per RFC 1122 section 3.2.1.3: // When a host sends any datagram, the IP source address MUST // be one of its own IP addresses (but not a broadcast or // multicast address). if srcAddr == header.IPv4Broadcast || header.IsV4MulticastAddress(srcAddr) { stats.ip.InvalidSourceAddressesReceived.Increment() return } // Make sure the source address is not a subnet-local broadcast address. if addressEndpoint := e.AcquireAssignedAddress(srcAddr, false /* createTemp */, stack.NeverPrimaryEndpoint); addressEndpoint != nil { subnet := addressEndpoint.Subnet() addressEndpoint.DecRef() if subnet.IsBroadcast(srcAddr) { stats.ip.InvalidSourceAddressesReceived.Increment() return } } // The destination address should be an address we own or a group we joined // for us to receive the packet. Otherwise, attempt to forward the packet. if addressEndpoint := e.AcquireAssignedAddress(dstAddr, e.nic.Promiscuous(), stack.CanBePrimaryEndpoint); addressEndpoint != nil { subnet := addressEndpoint.AddressWithPrefix().Subnet() addressEndpoint.DecRef() pkt.NetworkPacketInfo.LocalAddressBroadcast = subnet.IsBroadcast(dstAddr) || dstAddr == header.IPv4Broadcast } else if !e.IsInGroup(dstAddr) { if !e.protocol.Forwarding() { stats.ip.InvalidDestinationAddressesReceived.Increment() return } _ = e.forwardPacket(pkt) return } // iptables filtering. All packets that reach here are intended for // this machine and will not be forwarded. inNicName := e.protocol.stack.FindNICNameFromID(e.nic.ID()) if ok := e.protocol.stack.IPTables().Check(stack.Input, pkt, nil, nil, "" /* preroutingAddr */, inNicName, "" /* outNicName */); !ok { // iptables is telling us to drop the packet. stats.ip.IPTablesInputDropped.Increment() return } if h.More() || h.FragmentOffset() != 0 { if pkt.Data.Size()+pkt.TransportHeader().View().Size() == 0 { // Drop the packet as it's marked as a fragment but has // no payload. stats.ip.MalformedPacketsReceived.Increment() stats.ip.MalformedFragmentsReceived.Increment() return } // The packet is a fragment, let's try to reassemble it. start := h.FragmentOffset() // Drop the fragment if the size of the reassembled payload would exceed the // maximum payload size. // // Note that this addition doesn't overflow even on 32bit architecture // because pkt.Data.Size() should not exceed 65535 (the max IP datagram // size). Otherwise the packet would've been rejected as invalid before // reaching here. if int(start)+pkt.Data.Size() > header.IPv4MaximumPayloadSize { stats.ip.MalformedPacketsReceived.Increment() stats.ip.MalformedFragmentsReceived.Increment() return } proto := h.Protocol() data, _, ready, err := e.protocol.fragmentation.Process( // As per RFC 791 section 2.3, the identification value is unique // for a source-destination pair and protocol. fragmentation.FragmentID{ Source: h.SourceAddress(), Destination: h.DestinationAddress(), ID: uint32(h.ID()), Protocol: proto, }, start, start+uint16(pkt.Data.Size())-1, h.More(), proto, pkt, ) if err != nil { stats.ip.MalformedPacketsReceived.Increment() stats.ip.MalformedFragmentsReceived.Increment() return } if !ready { return } pkt.Data = data // The reassembler doesn't take care of fixing up the header, so we need // to do it here. h.SetTotalLength(uint16(pkt.Data.Size() + len((h)))) h.SetFlagsFragmentOffset(0, 0) } stats.ip.PacketsDelivered.Increment() p := h.TransportProtocol() if p == header.ICMPv4ProtocolNumber { // TODO(gvisor.dev/issues/3810): when we sort out ICMP and transport // headers, the setting of the transport number here should be // unnecessary and removed. pkt.TransportProtocolNumber = p e.handleICMP(pkt) return } if p == header.IGMPProtocolNumber { e.mu.Lock() e.mu.igmp.handleIGMP(pkt) e.mu.Unlock() return } if opts := h.Options(); len(opts) != 0 { // TODO(gvisor.dev/issue/4586): // When we add forwarding support we should use the verified options // rather than just throwing them away. if _, optProblem := e.processIPOptions(pkt, opts, &optionUsageReceive{}); optProblem != nil { if optProblem.NeedICMP { _ = e.protocol.returnError(&icmpReasonParamProblem{ pointer: optProblem.Pointer, }, pkt) e.protocol.stack.Stats().MalformedRcvdPackets.Increment() stats.ip.MalformedPacketsReceived.Increment() } return } } switch res := e.dispatcher.DeliverTransportPacket(p, pkt); res { case stack.TransportPacketHandled: case stack.TransportPacketDestinationPortUnreachable: // As per RFC: 1122 Section 3.2.2.1 A host SHOULD generate Destination // Unreachable messages with code: // 3 (Port Unreachable), when the designated transport protocol // (e.g., UDP) is unable to demultiplex the datagram but has no // protocol mechanism to inform the sender. _ = e.protocol.returnError(&icmpReasonPortUnreachable{}, pkt) case stack.TransportPacketProtocolUnreachable: // As per RFC: 1122 Section 3.2.2.1 // A host SHOULD generate Destination Unreachable messages with code: // 2 (Protocol Unreachable), when the designated transport protocol // is not supported _ = e.protocol.returnError(&icmpReasonProtoUnreachable{}, pkt) default: panic(fmt.Sprintf("unrecognized result from DeliverTransportPacket = %d", res)) } } // Close cleans up resources associated with the endpoint. func (e *endpoint) Close() { e.mu.Lock() defer e.mu.Unlock() e.disableLocked() e.mu.addressableEndpointState.Cleanup() e.protocol.forgetEndpoint(e.nic.ID()) } // AddAndAcquirePermanentAddress implements stack.AddressableEndpoint. func (e *endpoint) AddAndAcquirePermanentAddress(addr tcpip.AddressWithPrefix, peb stack.PrimaryEndpointBehavior, configType stack.AddressConfigType, deprecated bool) (stack.AddressEndpoint, tcpip.Error) { e.mu.Lock() defer e.mu.Unlock() ep, err := e.mu.addressableEndpointState.AddAndAcquirePermanentAddress(addr, peb, configType, deprecated) if err == nil { e.mu.igmp.sendQueuedReports() } return ep, err } // RemovePermanentAddress implements stack.AddressableEndpoint. func (e *endpoint) RemovePermanentAddress(addr tcpip.Address) tcpip.Error { e.mu.Lock() defer e.mu.Unlock() return e.mu.addressableEndpointState.RemovePermanentAddress(addr) } // 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() loopback := e.nic.IsLoopback() return e.mu.addressableEndpointState.AcquireAssignedAddressOrMatching(localAddr, func(addressEndpoint stack.AddressEndpoint) bool { subnet := addressEndpoint.Subnet() // IPv4 has a notion of a subnet broadcast address and considers the // loopback interface bound to an address's whole subnet (on linux). return subnet.IsBroadcast(localAddr) || (loopback && subnet.Contains(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: igmp.ep.mu must be read locked. func (e *endpoint) acquireOutgoingPrimaryAddressRLocked(remoteAddr tcpip.Address, allowExpired bool) stack.AddressEndpoint { return e.mu.addressableEndpointState.AcquireOutgoingPrimaryAddress(remoteAddr, allowExpired) } // 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) tcpip.Error { e.mu.Lock() defer e.mu.Unlock() return e.joinGroupLocked(addr) } // joinGroupLocked is like JoinGroup but with locking requirements. // // Precondition: e.mu must be locked. func (e *endpoint) joinGroupLocked(addr tcpip.Address) tcpip.Error { if !header.IsV4MulticastAddress(addr) { return &tcpip.ErrBadAddress{} } e.mu.igmp.joinGroup(addr) return nil } // LeaveGroup implements stack.GroupAddressableEndpoint. func (e *endpoint) LeaveGroup(addr tcpip.Address) tcpip.Error { e.mu.Lock() defer e.mu.Unlock() return e.leaveGroupLocked(addr) } // leaveGroupLocked is like LeaveGroup but with locking requirements. // // Precondition: e.mu must be locked. func (e *endpoint) leaveGroupLocked(addr tcpip.Address) tcpip.Error { return e.mu.igmp.leaveGroup(addr) } // IsInGroup implements stack.GroupAddressableEndpoint. func (e *endpoint) IsInGroup(addr tcpip.Address) bool { e.mu.RLock() defer e.mu.RUnlock() return e.mu.igmp.isInGroup(addr) } // Stats implements stack.NetworkEndpoint. func (e *endpoint) Stats() stack.NetworkEndpointStats { return &e.stats.localStats } var _ stack.ForwardingNetworkProtocol = (*protocol)(nil) var _ stack.NetworkProtocol = (*protocol)(nil) var _ fragmentation.TimeoutHandler = (*protocol)(nil) type protocol struct { stack *stack.Stack mu struct { sync.RWMutex // eps is keyed by NICID to allow protocol methods to retrieve an endpoint // when handling a packet, by looking at which NIC handled the packet. eps map[tcpip.NICID]*endpoint } // 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 ids []uint32 hashIV uint32 fragmentation *fragmentation.Fragmentation options Options } // Number returns the ipv4 protocol number. func (p *protocol) Number() tcpip.NetworkProtocolNumber { return ProtocolNumber } // MinimumPacketSize returns the minimum valid ipv4 packet size. func (p *protocol) MinimumPacketSize() int { return header.IPv4MinimumSize } // DefaultPrefixLen returns the IPv4 default prefix length. func (p *protocol) DefaultPrefixLen() int { return header.IPv4AddressSize * 8 } // ParseAddresses implements NetworkProtocol.ParseAddresses. func (*protocol) ParseAddresses(v buffer.View) (src, dst tcpip.Address) { h := header.IPv4(v) return h.SourceAddress(), h.DestinationAddress() } // 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) { if ok := parse.IPv4(pkt); !ok { return 0, false, false } ipHdr := header.IPv4(pkt.NetworkHeader().View()) return ipHdr.TransportProtocol(), !ipHdr.More() && ipHdr.FragmentOffset() == 0, true } // Forwarding implements stack.ForwardingNetworkProtocol. func (p *protocol) Forwarding() bool { return uint8(atomic.LoadUint32(&p.forwarding)) == 1 } // SetForwarding implements stack.ForwardingNetworkProtocol. func (p *protocol) SetForwarding(v bool) { if v { atomic.StoreUint32(&p.forwarding, 1) } else { atomic.StoreUint32(&p.forwarding, 0) } } // calculateNetworkMTU calculates the network-layer payload MTU based on the // link-layer payload mtu. func calculateNetworkMTU(linkMTU, networkHeaderSize uint32) (uint32, tcpip.Error) { if linkMTU < header.IPv4MinimumMTU { return 0, &tcpip.ErrInvalidEndpointState{} } // As per RFC 791 section 3.1, an IPv4 header cannot exceed 60 bytes in // length: // The maximal internet header is 60 octets, and a typical internet header // is 20 octets, allowing a margin for headers of higher level protocols. if networkHeaderSize > header.IPv4MaximumHeaderSize { return 0, &tcpip.ErrMalformedHeader{} } networkMTU := linkMTU if networkMTU > MaxTotalSize { networkMTU = MaxTotalSize } return networkMTU - uint32(networkHeaderSize), nil } func packetMustBeFragmented(pkt *stack.PacketBuffer, networkMTU uint32, gso *stack.GSO) bool { payload := pkt.TransportHeader().View().Size() + pkt.Data.Size() return (gso == nil || gso.Type == stack.GSONone) && uint32(payload) > networkMTU } // addressToUint32 translates an IPv4 address into its little endian uint32 // representation. // // This function does the same thing as binary.LittleEndian.Uint32 but operates // on a tcpip.Address (a string) without the need to convert it to a byte slice, // which would cause an allocation. func addressToUint32(addr tcpip.Address) uint32 { _ = addr[3] // bounds check hint to compiler return uint32(addr[0]) | uint32(addr[1])<<8 | uint32(addr[2])<<16 | uint32(addr[3])<<24 } // hashRoute calculates a hash value for the given source/destination pair using // the addresses, transport protocol number and a 32-bit number to generate the // hash. func hashRoute(srcAddr, dstAddr tcpip.Address, protocol tcpip.TransportProtocolNumber, hashIV uint32) uint32 { a := addressToUint32(srcAddr) b := addressToUint32(dstAddr) return hash.Hash3Words(a, b, uint32(protocol), hashIV) } // Options holds options to configure a new protocol. type Options struct { // IGMP holds options for IGMP. IGMP IGMPOptions } // NewProtocolWithOptions returns an IPv4 network protocol. func NewProtocolWithOptions(opts Options) stack.NetworkProtocolFactory { ids := make([]uint32, buckets) // Randomly initialize hashIV and the ids. r := hash.RandN32(1 + buckets) for i := range ids { ids[i] = r[i] } hashIV := r[buckets] return func(s *stack.Stack) stack.NetworkProtocol { p := &protocol{ stack: s, ids: ids, hashIV: hashIV, defaultTTL: DefaultTTL, options: opts, } p.fragmentation = fragmentation.NewFragmentation(fragmentblockSize, fragmentation.HighFragThreshold, fragmentation.LowFragThreshold, ReassembleTimeout, s.Clock(), p) p.mu.eps = make(map[tcpip.NICID]*endpoint) return p } } // NewProtocol is equivalent to NewProtocolWithOptions with an empty Options. func NewProtocol(s *stack.Stack) stack.NetworkProtocol { return NewProtocolWithOptions(Options{})(s) } func buildNextFragment(pf *fragmentation.PacketFragmenter, originalIPHeader header.IPv4) (*stack.PacketBuffer, bool) { fragPkt, offset, copied, more := pf.BuildNextFragment() fragPkt.NetworkProtocolNumber = ProtocolNumber originalIPHeaderLength := len(originalIPHeader) nextFragIPHeader := header.IPv4(fragPkt.NetworkHeader().Push(originalIPHeaderLength)) fragPkt.NetworkProtocolNumber = ProtocolNumber if copied := copy(nextFragIPHeader, originalIPHeader); copied != len(originalIPHeader) { panic(fmt.Sprintf("wrong number of bytes copied into fragmentIPHeaders: got = %d, want = %d", copied, originalIPHeaderLength)) } flags := originalIPHeader.Flags() if more { flags |= header.IPv4FlagMoreFragments } nextFragIPHeader.SetFlagsFragmentOffset(flags, uint16(offset)) nextFragIPHeader.SetTotalLength(uint16(nextFragIPHeader.HeaderLength()) + uint16(copied)) nextFragIPHeader.SetChecksum(0) nextFragIPHeader.SetChecksum(^nextFragIPHeader.CalculateChecksum()) return fragPkt, more } // optionAction describes possible actions that may be taken on an option // while processing it. type optionAction uint8 const ( // optionRemove says that the option should not be in the output option set. optionRemove optionAction = iota // optionProcess says that the option should be fully processed. optionProcess // optionVerify says the option should be checked and passed unchanged. optionVerify // optionPass says to pass the output set without checking. optionPass ) // optionActions list what to do for each option in a given scenario. type optionActions struct { // timestamp controls what to do with a Timestamp option. timestamp optionAction // recordroute controls what to do with a Record Route option. recordRoute optionAction // unknown controls what to do with an unknown option. unknown optionAction } // optionsUsage specifies the ways options may be operated upon for a given // scenario during packet processing. type optionsUsage interface { actions() optionActions } // optionUsageReceive implements optionsUsage for received packets. type optionUsageReceive struct{} // actions implements optionsUsage. func (*optionUsageReceive) actions() optionActions { return optionActions{ timestamp: optionVerify, recordRoute: optionVerify, unknown: optionPass, } } // TODO(gvisor.dev/issue/4586): Add an entry here for forwarding when it // is enabled (Process, Process, Pass) and for fragmenting (Process, Process, // Pass for frag1, but Remove,Remove,Remove for all other frags). // optionUsageEcho implements optionsUsage for echo packet processing. type optionUsageEcho struct{} // actions implements optionsUsage. func (*optionUsageEcho) actions() optionActions { return optionActions{ timestamp: optionProcess, recordRoute: optionProcess, unknown: optionRemove, } } // handleTimestamp does any required processing on a Timestamp option // in place. func handleTimestamp(tsOpt header.IPv4OptionTimestamp, localAddress tcpip.Address, clock tcpip.Clock, usage optionsUsage) *header.IPv4OptParameterProblem { flags := tsOpt.Flags() var entrySize uint8 switch flags { case header.IPv4OptionTimestampOnlyFlag: entrySize = header.IPv4OptionTimestampSize case header.IPv4OptionTimestampWithIPFlag, header.IPv4OptionTimestampWithPredefinedIPFlag: entrySize = header.IPv4OptionTimestampWithAddrSize default: return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptTSOFLWAndFLGOffset, NeedICMP: true, } } pointer := tsOpt.Pointer() // RFC 791 page 22 states: "The smallest legal value is 5." // Since the pointer is 1 based, and the header is 4 bytes long the // pointer must point beyond the header therefore 4 or less is bad. if pointer <= header.IPv4OptionTimestampHdrLength { return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptTSPointerOffset, NeedICMP: true, } } // To simplify processing below, base further work on the array of timestamps // beyond the header, rather than on the whole option. Also to aid // calculations set 'nextSlot' to be 0 based as in the packet it is 1 based. nextSlot := pointer - (header.IPv4OptionTimestampHdrLength + 1) optLen := tsOpt.Size() dataLength := optLen - header.IPv4OptionTimestampHdrLength // In the section below, we verify the pointer, length and overflow counter // fields of the option. The distinction is in which byte you return as being // in error in the ICMP packet. Offsets 1 (length), 2 pointer) // or 3 (overflowed counter). // // The following RFC sections cover this section: // // RFC 791 (page 22): // If there is some room but not enough room for a full timestamp // to be inserted, or the overflow count itself overflows, the // original datagram is considered to be in error and is discarded. // In either case an ICMP parameter problem message may be sent to // the source host [3]. // // You can get this situation in two ways. Firstly if the data area is not // a multiple of the entry size or secondly, if the pointer is not at a // multiple of the entry size. The wording of the RFC suggests that // this is not an error until you actually run out of space. if pointer > optLen { // RFC 791 (page 22) says we should switch to using the overflow count. // If the timestamp data area is already full (the pointer exceeds // the length) the datagram is forwarded without inserting the // timestamp, but the overflow count is incremented by one. if flags == header.IPv4OptionTimestampWithPredefinedIPFlag { // By definition we have nothing to do. return nil } if tsOpt.IncOverflow() != 0 { return nil } // The overflow count is also full. return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptTSOFLWAndFLGOffset, NeedICMP: true, } } if nextSlot+entrySize > dataLength { // The data area isn't full but there isn't room for a new entry. // Either Length or Pointer could be bad. if false { // We must select Pointer for Linux compatibility, even if // only the length is bad. // The Linux code is at (in October 2020) // https://github.com/torvalds/linux/blob/bbf5c979011a099af5dc76498918ed7df445635b/net/ipv4/ip_options.c#L367-L370 // if (optptr[2]+3 > optlen) { // pp_ptr = optptr + 2; // goto error; // } // which doesn't distinguish between which of optptr[2] or optlen // is wrong, but just arbitrarily decides on optptr+2. if dataLength%entrySize != 0 { // The Data section size should be a multiple of the expected // timestamp entry size. return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptionLengthOffset, NeedICMP: false, } } // If the size is OK, the pointer must be corrupted. } return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptTSPointerOffset, NeedICMP: true, } } if usage.actions().timestamp == optionProcess { tsOpt.UpdateTimestamp(localAddress, clock) } return nil } // handleRecordRoute checks and processes a Record route option. It is much // like the timestamp type 1 option, but without timestamps. The passed in // address is stored in the option in the correct spot if possible. func handleRecordRoute(rrOpt header.IPv4OptionRecordRoute, localAddress tcpip.Address, usage optionsUsage) *header.IPv4OptParameterProblem { optlen := rrOpt.Size() if optlen < header.IPv4AddressSize+header.IPv4OptionRecordRouteHdrLength { return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptionLengthOffset, NeedICMP: true, } } pointer := rrOpt.Pointer() // RFC 791 page 20 states: // The pointer is relative to this option, and the // smallest legal value for the pointer is 4. // Since the pointer is 1 based, and the header is 3 bytes long the // pointer must point beyond the header therefore 3 or less is bad. if pointer <= header.IPv4OptionRecordRouteHdrLength { return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptRRPointerOffset, NeedICMP: true, } } // RFC 791 page 21 says // If the route data area is already full (the pointer exceeds the // length) the datagram is forwarded without inserting the address // into the recorded route. If there is some room but not enough // room for a full address to be inserted, the original datagram is // considered to be in error and is discarded. In either case an // ICMP parameter problem message may be sent to the source // host. // The use of the words "In either case" suggests that a 'full' RR option // could generate an ICMP at every hop after it fills up. We chose to not // do this (as do most implementations). It is probable that the inclusion // of these words is a copy/paste error from the timestamp option where // there are two failure reasons given. if pointer > optlen { return nil } // The data area isn't full but there isn't room for a new entry. // Either Length or Pointer could be bad. We must select Pointer for Linux // compatibility, even if only the length is bad. NB. pointer is 1 based. if pointer+header.IPv4AddressSize > optlen+1 { if false { // This is what we would do if we were not being Linux compatible. // Check for bad pointer or length value. Must be a multiple of 4 after // accounting for the 3 byte header and not within that header. // RFC 791, page 20 says: // The pointer is relative to this option, and the // smallest legal value for the pointer is 4. // // A recorded route is composed of a series of internet addresses. // Each internet address is 32 bits or 4 octets. // Linux skips this test so we must too. See Linux code at: // https://github.com/torvalds/linux/blob/bbf5c979011a099af5dc76498918ed7df445635b/net/ipv4/ip_options.c#L338-L341 // if (optptr[2]+3 > optlen) { // pp_ptr = optptr + 2; // goto error; // } if (optlen-header.IPv4OptionRecordRouteHdrLength)%header.IPv4AddressSize != 0 { // Length is bad, not on integral number of slots. return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptionLengthOffset, NeedICMP: true, } } // If not length, the fault must be with the pointer. } return &header.IPv4OptParameterProblem{ Pointer: header.IPv4OptRRPointerOffset, NeedICMP: true, } } if usage.actions().recordRoute == optionVerify { return nil } rrOpt.StoreAddress(localAddress) return nil } // processIPOptions parses the IPv4 options and produces a new set of options // suitable for use in the next step of packet processing as informed by usage. // The original will not be touched. // // Returns // - The location of an error if there was one (or 0 if no error) // - If there is an error, information as to what it was was. // - The replacement option set. func (e *endpoint) processIPOptions(pkt *stack.PacketBuffer, orig header.IPv4Options, usage optionsUsage) (header.IPv4Options, *header.IPv4OptParameterProblem) { stats := e.stats.ip opts := header.IPv4Options(orig) optIter := opts.MakeIterator() // Each option other than NOP must only appear (RFC 791 section 3.1, at the // definition of every type). Keep track of each of the possible types in // the 8 bit 'type' field. var seenOptions [math.MaxUint8 + 1]bool // TODO(gvisor.dev/issue/4586): // This will need tweaking when we start really forwarding packets // as we may need to get two addresses, for rx and tx interfaces. // We will also have to take usage into account. prefixedAddress, ok := e.protocol.stack.GetMainNICAddress(e.nic.ID(), ProtocolNumber) localAddress := prefixedAddress.Address if !ok { h := header.IPv4(pkt.NetworkHeader().View()) dstAddr := h.DestinationAddress() if pkt.NetworkPacketInfo.LocalAddressBroadcast || header.IsV4MulticastAddress(dstAddr) { return nil, &header.IPv4OptParameterProblem{ NeedICMP: false, } } localAddress = dstAddr } for { option, done, optProblem := optIter.Next() if done || optProblem != nil { return optIter.Finalize(), optProblem } optType := option.Type() if optType == header.IPv4OptionNOPType { optIter.PushNOPOrEnd(optType) continue } if optType == header.IPv4OptionListEndType { optIter.PushNOPOrEnd(optType) return optIter.Finalize(), nil } // check for repeating options (multiple NOPs are OK) if seenOptions[optType] { return nil, &header.IPv4OptParameterProblem{ Pointer: optIter.ErrCursor, NeedICMP: true, } } seenOptions[optType] = true optLen := int(option.Size()) switch option := option.(type) { case *header.IPv4OptionTimestamp: stats.OptionTSReceived.Increment() if usage.actions().timestamp != optionRemove { clock := e.protocol.stack.Clock() newBuffer := optIter.RemainingBuffer()[:len(*option)] _ = copy(newBuffer, option.Contents()) if optProblem := handleTimestamp(header.IPv4OptionTimestamp(newBuffer), localAddress, clock, usage); optProblem != nil { optProblem.Pointer += optIter.ErrCursor return nil, optProblem } optIter.ConsumeBuffer(optLen) } case *header.IPv4OptionRecordRoute: stats.OptionRRReceived.Increment() if usage.actions().recordRoute != optionRemove { newBuffer := optIter.RemainingBuffer()[:len(*option)] _ = copy(newBuffer, option.Contents()) if optProblem := handleRecordRoute(header.IPv4OptionRecordRoute(newBuffer), localAddress, usage); optProblem != nil { optProblem.Pointer += optIter.ErrCursor return nil, optProblem } optIter.ConsumeBuffer(optLen) } default: stats.OptionUnknownReceived.Increment() if usage.actions().unknown == optionPass { newBuffer := optIter.RemainingBuffer()[:optLen] // Arguments already heavily checked.. ignore result. _ = copy(newBuffer, option.Contents()) optIter.ConsumeBuffer(optLen) } } } }