// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package ipv6 import ( "fmt" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/stack" ) // handleControl handles the case when an ICMP packet contains the headers of // the original packet that caused the ICMP one to be sent. This information is // used to find out which transport endpoint must be notified about the ICMP // packet. func (e *endpoint) handleControl(typ stack.ControlType, extra uint32, pkt *stack.PacketBuffer) { h, ok := pkt.Data.PullUp(header.IPv6MinimumSize) if !ok { return } hdr := header.IPv6(h) // We don't use IsValid() here because ICMP only requires that up to // 1280 bytes of the original packet be included. So it's likely that it // is truncated, which would cause IsValid to return false. // // Drop packet if it doesn't have the basic IPv6 header or if the // original source address doesn't match an address we own. src := hdr.SourceAddress() if e.protocol.stack.CheckLocalAddress(e.nic.ID(), ProtocolNumber, src) == 0 { return } // Skip the IP header, then handle the fragmentation header if there // is one. pkt.Data.TrimFront(header.IPv6MinimumSize) p := hdr.TransportProtocol() if p == header.IPv6FragmentHeader { f, ok := pkt.Data.PullUp(header.IPv6FragmentHeaderSize) if !ok { return } fragHdr := header.IPv6Fragment(f) if !fragHdr.IsValid() || fragHdr.FragmentOffset() != 0 { // We can't handle fragments that aren't at offset 0 // because they don't have the transport headers. return } // Skip fragmentation header and find out the actual protocol // number. pkt.Data.TrimFront(header.IPv6FragmentHeaderSize) p = fragHdr.TransportProtocol() } // Deliver the control packet to the transport endpoint. e.dispatcher.DeliverTransportControlPacket(src, hdr.DestinationAddress(), ProtocolNumber, p, typ, extra, pkt) } // getLinkAddrOption searches NDP options for a given link address option using // the provided getAddr function as a filter. Returns the link address if // found; otherwise, returns the zero link address value. Also returns true if // the options are valid as per the wire format, false otherwise. func getLinkAddrOption(it header.NDPOptionIterator, getAddr func(header.NDPOption) tcpip.LinkAddress) (tcpip.LinkAddress, bool) { var linkAddr tcpip.LinkAddress for { opt, done, err := it.Next() if err != nil { return "", false } if done { break } if addr := getAddr(opt); len(addr) != 0 { // No RFCs define what to do when an NDP message has multiple Link-Layer // Address options. Since no interface can have multiple link-layer // addresses, we consider such messages invalid. if len(linkAddr) != 0 { return "", false } linkAddr = addr } } return linkAddr, true } // getSourceLinkAddr searches NDP options for the source link address option. // Returns the link address if found; otherwise, returns the zero link address // value. Also returns true if the options are valid as per the wire format, // false otherwise. func getSourceLinkAddr(it header.NDPOptionIterator) (tcpip.LinkAddress, bool) { return getLinkAddrOption(it, func(opt header.NDPOption) tcpip.LinkAddress { if src, ok := opt.(header.NDPSourceLinkLayerAddressOption); ok { return src.EthernetAddress() } return "" }) } // getTargetLinkAddr searches NDP options for the target link address option. // Returns the link address if found; otherwise, returns the zero link address // value. Also returns true if the options are valid as per the wire format, // false otherwise. func getTargetLinkAddr(it header.NDPOptionIterator) (tcpip.LinkAddress, bool) { return getLinkAddrOption(it, func(opt header.NDPOption) tcpip.LinkAddress { if dst, ok := opt.(header.NDPTargetLinkLayerAddressOption); ok { return dst.EthernetAddress() } return "" }) } func (e *endpoint) handleICMP(r *stack.Route, pkt *stack.PacketBuffer, hasFragmentHeader bool) { stats := r.Stats().ICMP sent := stats.V6PacketsSent received := stats.V6PacketsReceived // TODO(gvisor.dev/issue/170): ICMP packets don't have their // TransportHeader fields set. See icmp/protocol.go:protocol.Parse for a // full explanation. v, ok := pkt.Data.PullUp(header.ICMPv6HeaderSize) if !ok { received.Invalid.Increment() return } h := header.ICMPv6(v) iph := header.IPv6(pkt.NetworkHeader().View()) // Validate ICMPv6 checksum before processing the packet. // // This copy is used as extra payload during the checksum calculation. payload := pkt.Data.Clone(nil) payload.TrimFront(len(h)) if got, want := h.Checksum(), header.ICMPv6Checksum(h, iph.SourceAddress(), iph.DestinationAddress(), payload); got != want { received.Invalid.Increment() return } isNDPValid := func() bool { // As per RFC 4861 sections 4.1 - 4.5, 6.1.1, 6.1.2, 7.1.1, 7.1.2 and // 8.1, nodes MUST silently drop NDP packets where the Hop Limit field // in the IPv6 header is not set to 255, or the ICMPv6 Code field is not // set to 0. // // As per RFC 6980 section 5, nodes MUST silently drop NDP messages if the // packet includes a fragmentation header. return !hasFragmentHeader && iph.HopLimit() == header.NDPHopLimit && h.Code() == 0 } // TODO(b/112892170): Meaningfully handle all ICMP types. switch h.Type() { case header.ICMPv6PacketTooBig: received.PacketTooBig.Increment() hdr, ok := pkt.Data.PullUp(header.ICMPv6PacketTooBigMinimumSize) if !ok { received.Invalid.Increment() return } pkt.Data.TrimFront(header.ICMPv6PacketTooBigMinimumSize) mtu := header.ICMPv6(hdr).MTU() e.handleControl(stack.ControlPacketTooBig, calculateMTU(mtu), pkt) case header.ICMPv6DstUnreachable: received.DstUnreachable.Increment() hdr, ok := pkt.Data.PullUp(header.ICMPv6DstUnreachableMinimumSize) if !ok { received.Invalid.Increment() return } pkt.Data.TrimFront(header.ICMPv6DstUnreachableMinimumSize) switch header.ICMPv6(hdr).Code() { case header.ICMPv6NetworkUnreachable: e.handleControl(stack.ControlNetworkUnreachable, 0, pkt) case header.ICMPv6PortUnreachable: e.handleControl(stack.ControlPortUnreachable, 0, pkt) } case header.ICMPv6NeighborSolicit: received.NeighborSolicit.Increment() if !isNDPValid() || pkt.Data.Size() < header.ICMPv6NeighborSolicitMinimumSize { received.Invalid.Increment() return } // The remainder of payload must be only the neighbor solicitation, so // payload.ToView() always returns the solicitation. Per RFC 6980 section 5, // NDP messages cannot be fragmented. Also note that in the common case NDP // datagrams are very small and ToView() will not incur allocations. ns := header.NDPNeighborSolicit(payload.ToView()) targetAddr := ns.TargetAddress() // As per RFC 4861 section 4.3, the Target Address MUST NOT be a multicast // address. if header.IsV6MulticastAddress(targetAddr) { received.Invalid.Increment() return } if e.hasTentativeAddr(targetAddr) { // If the target address is tentative and the source of the packet is a // unicast (specified) address, then the source of the packet is // attempting to perform address resolution on the target. In this case, // the solicitation is silently ignored, as per RFC 4862 section 5.4.3. // // If the target address is tentative and the source of the packet is the // unspecified address (::), then we know another node is also performing // DAD for the same address (since the target address is tentative for us, // we know we are also performing DAD on it). In this case we let the // stack know so it can handle such a scenario and do nothing further with // the NS. if r.RemoteAddress == header.IPv6Any { // We would get an error if the address no longer exists or the address // is no longer tentative (DAD resolved between the call to // hasTentativeAddr and this point). Both of these are valid scenarios: // 1) An address may be removed at any time. // 2) As per RFC 4862 section 5.4, DAD is not a perfect: // "Note that the method for detecting duplicates // is not completely reliable, and it is possible that duplicate // addresses will still exist" // // TODO(gvisor.dev/issue/4046): Handle the scenario when a duplicate // address is detected for an assigned address. if err := e.dupTentativeAddrDetected(targetAddr); err != nil && err != tcpip.ErrBadAddress && err != tcpip.ErrInvalidEndpointState { panic(fmt.Sprintf("unexpected error handling duplicate tentative address: %s", err)) } } // Do not handle neighbor solicitations targeted to an address that is // tentative on the NIC any further. return } // At this point we know that the target address is not tentative on the NIC // so the packet is processed as defined in RFC 4861, as per RFC 4862 // section 5.4.3. // Is the NS targeting us? if r.Stack().CheckLocalAddress(e.nic.ID(), ProtocolNumber, targetAddr) == 0 { return } it, err := ns.Options().Iter(false /* check */) if err != nil { // Options are not valid as per the wire format, silently drop the packet. received.Invalid.Increment() return } sourceLinkAddr, ok := getSourceLinkAddr(it) if !ok { received.Invalid.Increment() return } unspecifiedSource := r.RemoteAddress == header.IPv6Any // As per RFC 4861 section 4.3, the Source Link-Layer Address Option MUST // NOT be included when the source IP address is the unspecified address. // Otherwise, on link layers that have addresses this option MUST be // included in multicast solicitations and SHOULD be included in unicast // solicitations. if len(sourceLinkAddr) == 0 { if header.IsV6MulticastAddress(r.LocalAddress) && !unspecifiedSource { received.Invalid.Increment() return } } else if unspecifiedSource { received.Invalid.Increment() return } else if e.nud != nil { e.nud.HandleProbe(r.RemoteAddress, r.LocalAddress, header.IPv6ProtocolNumber, sourceLinkAddr, e.protocol) } else { e.linkAddrCache.AddLinkAddress(e.nic.ID(), r.RemoteAddress, sourceLinkAddr) } // As per RFC 4861 section 7.1.1: // A node MUST silently discard any received Neighbor Solicitation // messages that do not satisfy all of the following validity checks: // ... // - If the IP source address is the unspecified address, the IP // destination address is a solicited-node multicast address. if unspecifiedSource && !header.IsSolicitedNodeAddr(r.LocalAddress) { received.Invalid.Increment() return } // ICMPv6 Neighbor Solicit messages are always sent to // specially crafted IPv6 multicast addresses. As a result, the // route we end up with here has as its LocalAddress such a // multicast address. It would be nonsense to claim that our // source address is a multicast address, so we manually set // the source address to the target address requested in the // solicit message. Since that requires mutating the route, we // must first clone it. r := r.Clone() defer r.Release() r.LocalAddress = targetAddr // As per RFC 4861 section 7.2.4, if the the source of the solicitation is // the unspecified address, the node MUST set the Solicited flag to zero and // multicast the advertisement to the all-nodes address. solicited := true if unspecifiedSource { solicited = false r.RemoteAddress = header.IPv6AllNodesMulticastAddress } // If the NS has a source link-layer option, use the link address it // specifies as the remote link address for the response instead of the // source link address of the packet. // // TODO(#2401): As per RFC 4861 section 7.2.4 we should consult our link // address cache for the right destination link address instead of manually // patching the route with the remote link address if one is specified in a // Source Link-Layer Address option. if len(sourceLinkAddr) != 0 { r.RemoteLinkAddress = sourceLinkAddr } optsSerializer := header.NDPOptionsSerializer{ header.NDPTargetLinkLayerAddressOption(r.LocalLinkAddress), } pkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: int(r.MaxHeaderLength()) + header.ICMPv6NeighborAdvertMinimumSize + int(optsSerializer.Length()), }) packet := header.ICMPv6(pkt.TransportHeader().Push(header.ICMPv6NeighborAdvertSize)) pkt.TransportProtocolNumber = header.ICMPv6ProtocolNumber packet.SetType(header.ICMPv6NeighborAdvert) na := header.NDPNeighborAdvert(packet.NDPPayload()) na.SetSolicitedFlag(solicited) na.SetOverrideFlag(true) na.SetTargetAddress(targetAddr) opts := na.Options() opts.Serialize(optsSerializer) packet.SetChecksum(header.ICMPv6Checksum(packet, r.LocalAddress, r.RemoteAddress, buffer.VectorisedView{})) // RFC 4861 Neighbor Discovery for IP version 6 (IPv6) // // 7.1.2. Validation of Neighbor Advertisements // // The IP Hop Limit field has a value of 255, i.e., the packet // could not possibly have been forwarded by a router. if err := r.WritePacket(nil /* gso */, stack.NetworkHeaderParams{Protocol: header.ICMPv6ProtocolNumber, TTL: header.NDPHopLimit, TOS: stack.DefaultTOS}, pkt); err != nil { sent.Dropped.Increment() return } sent.NeighborAdvert.Increment() case header.ICMPv6NeighborAdvert: received.NeighborAdvert.Increment() if !isNDPValid() || pkt.Data.Size() < header.ICMPv6NeighborAdvertSize { received.Invalid.Increment() return } // The remainder of payload must be only the neighbor advertisement, so // payload.ToView() always returns the advertisement. Per RFC 6980 section // 5, NDP messages cannot be fragmented. Also note that in the common case // NDP datagrams are very small and ToView() will not incur allocations. na := header.NDPNeighborAdvert(payload.ToView()) targetAddr := na.TargetAddress() if e.hasTentativeAddr(targetAddr) { // We just got an NA from a node that owns an address we are performing // DAD on, implying the address is not unique. In this case we let the // stack know so it can handle such a scenario and do nothing furthur with // the NDP NA. // // We would get an error if the address no longer exists or the address // is no longer tentative (DAD resolved between the call to // hasTentativeAddr and this point). Both of these are valid scenarios: // 1) An address may be removed at any time. // 2) As per RFC 4862 section 5.4, DAD is not a perfect: // "Note that the method for detecting duplicates // is not completely reliable, and it is possible that duplicate // addresses will still exist" // // TODO(gvisor.dev/issue/4046): Handle the scenario when a duplicate // address is detected for an assigned address. if err := e.dupTentativeAddrDetected(targetAddr); err != nil && err != tcpip.ErrBadAddress && err != tcpip.ErrInvalidEndpointState { panic(fmt.Sprintf("unexpected error handling duplicate tentative address: %s", err)) } return } it, err := na.Options().Iter(false /* check */) if err != nil { // If we have a malformed NDP NA option, drop the packet. received.Invalid.Increment() return } // At this point we know that the target address is not tentative on the // NIC. However, the target address may still be assigned to the NIC but not // tentative (it could be permanent). Such a scenario is beyond the scope of // RFC 4862. As such, we simply ignore such a scenario for now and proceed // as normal. // // TODO(b/143147598): Handle the scenario described above. Also inform the // netstack integration that a duplicate address was detected outside of // DAD. targetLinkAddr, ok := getTargetLinkAddr(it) if !ok { received.Invalid.Increment() return } // If the NA message has the target link layer option, update the link // address cache with the link address for the target of the message. if len(targetLinkAddr) != 0 { if e.nud == nil { e.linkAddrCache.AddLinkAddress(e.nic.ID(), targetAddr, targetLinkAddr) return } e.nud.HandleConfirmation(targetAddr, targetLinkAddr, stack.ReachabilityConfirmationFlags{ Solicited: na.SolicitedFlag(), Override: na.OverrideFlag(), IsRouter: na.RouterFlag(), }) } case header.ICMPv6EchoRequest: received.EchoRequest.Increment() icmpHdr, ok := pkt.TransportHeader().Consume(header.ICMPv6EchoMinimumSize) if !ok { received.Invalid.Increment() return } // As per RFC 4291 section 2.7, multicast addresses must not be used as // source addresses in IPv6 packets. localAddr := r.LocalAddress if header.IsV6MulticastAddress(r.LocalAddress) { localAddr = "" } r, err := r.Stack().FindRoute(e.nic.ID(), localAddr, r.RemoteAddress, ProtocolNumber, false /* multicastLoop */) if err != nil { // If we cannot find a route to the destination, silently drop the packet. return } defer r.Release() replyPkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: int(r.MaxHeaderLength()) + header.ICMPv6EchoMinimumSize, Data: pkt.Data, }) packet := header.ICMPv6(replyPkt.TransportHeader().Push(header.ICMPv6EchoMinimumSize)) pkt.TransportProtocolNumber = header.ICMPv6ProtocolNumber copy(packet, icmpHdr) packet.SetType(header.ICMPv6EchoReply) packet.SetChecksum(header.ICMPv6Checksum(packet, r.LocalAddress, r.RemoteAddress, pkt.Data)) if err := r.WritePacket(nil /* gso */, stack.NetworkHeaderParams{Protocol: header.ICMPv6ProtocolNumber, TTL: r.DefaultTTL(), TOS: stack.DefaultTOS}, replyPkt); err != nil { sent.Dropped.Increment() return } sent.EchoReply.Increment() case header.ICMPv6EchoReply: received.EchoReply.Increment() if pkt.Data.Size() < header.ICMPv6EchoMinimumSize { received.Invalid.Increment() return } e.dispatcher.DeliverTransportPacket(r, header.ICMPv6ProtocolNumber, pkt) case header.ICMPv6TimeExceeded: received.TimeExceeded.Increment() case header.ICMPv6ParamProblem: received.ParamProblem.Increment() case header.ICMPv6RouterSolicit: received.RouterSolicit.Increment() // // Validate the RS as per RFC 4861 section 6.1.1. // // Is the NDP payload of sufficient size to hold a Router Solictation? if !isNDPValid() || pkt.Data.Size()-header.ICMPv6HeaderSize < header.NDPRSMinimumSize { received.Invalid.Increment() return } stack := r.Stack() // Is the networking stack operating as a router? if !stack.Forwarding(ProtocolNumber) { // ... No, silently drop the packet. received.RouterOnlyPacketsDroppedByHost.Increment() return } // Note that in the common case NDP datagrams are very small and ToView() // will not incur allocations. rs := header.NDPRouterSolicit(payload.ToView()) it, err := rs.Options().Iter(false /* check */) if err != nil { // Options are not valid as per the wire format, silently drop the packet. received.Invalid.Increment() return } sourceLinkAddr, ok := getSourceLinkAddr(it) if !ok { received.Invalid.Increment() return } // If the RS message has the source link layer option, update the link // address cache with the link address for the source of the message. if len(sourceLinkAddr) != 0 { // As per RFC 4861 section 4.1, the Source Link-Layer Address Option MUST // NOT be included when the source IP address is the unspecified address. // Otherwise, it SHOULD be included on link layers that have addresses. if r.RemoteAddress == header.IPv6Any { received.Invalid.Increment() return } if e.nud != nil { // A RS with a specified source IP address modifies the NUD state // machine in the same way a reachability probe would. e.nud.HandleProbe(r.RemoteAddress, r.LocalAddress, header.IPv6ProtocolNumber, sourceLinkAddr, e.protocol) } } case header.ICMPv6RouterAdvert: received.RouterAdvert.Increment() // // Validate the RA as per RFC 4861 section 6.1.2. // // Is the NDP payload of sufficient size to hold a Router Advertisement? if !isNDPValid() || pkt.Data.Size()-header.ICMPv6HeaderSize < header.NDPRAMinimumSize { received.Invalid.Increment() return } routerAddr := iph.SourceAddress() // Is the IP Source Address a link-local address? if !header.IsV6LinkLocalAddress(routerAddr) { // ...No, silently drop the packet. received.Invalid.Increment() return } // Note that in the common case NDP datagrams are very small and ToView() // will not incur allocations. ra := header.NDPRouterAdvert(payload.ToView()) it, err := ra.Options().Iter(false /* check */) if err != nil { // Options are not valid as per the wire format, silently drop the packet. received.Invalid.Increment() return } sourceLinkAddr, ok := getSourceLinkAddr(it) if !ok { received.Invalid.Increment() return } // // At this point, we have a valid Router Advertisement, as far // as RFC 4861 section 6.1.2 is concerned. // // If the RA has the source link layer option, update the link address // cache with the link address for the advertised router. if len(sourceLinkAddr) != 0 && e.nud != nil { e.nud.HandleProbe(routerAddr, r.LocalAddress, header.IPv6ProtocolNumber, sourceLinkAddr, e.protocol) } e.mu.Lock() e.mu.ndp.handleRA(routerAddr, ra) e.mu.Unlock() case header.ICMPv6RedirectMsg: // TODO(gvisor.dev/issue/2285): Call `e.nud.HandleProbe` after validating // this redirect message, as per RFC 4871 section 7.3.3: // // "A Neighbor Cache entry enters the STALE state when created as a // result of receiving packets other than solicited Neighbor // Advertisements (i.e., Router Solicitations, Router Advertisements, // Redirects, and Neighbor Solicitations). These packets contain the // link-layer address of either the sender or, in the case of Redirect, // the redirection target. However, receipt of these link-layer // addresses does not confirm reachability of the forward-direction path // to that node. Placing a newly created Neighbor Cache entry for which // the link-layer address is known in the STALE state provides assurance // that path failures are detected quickly. In addition, should a cached // link-layer address be modified due to receiving one of the above // messages, the state SHOULD also be set to STALE to provide prompt // verification that the path to the new link-layer address is working." received.RedirectMsg.Increment() if !isNDPValid() { received.Invalid.Increment() return } default: received.Invalid.Increment() } } const ( ndpSolicitedFlag = 1 << 6 ndpOverrideFlag = 1 << 5 ndpOptSrcLinkAddr = 1 ndpOptDstLinkAddr = 2 icmpV6FlagOffset = 4 icmpV6OptOffset = 24 icmpV6LengthOffset = 25 ) var _ stack.LinkAddressResolver = (*protocol)(nil) // LinkAddressProtocol implements stack.LinkAddressResolver. func (*protocol) LinkAddressProtocol() tcpip.NetworkProtocolNumber { return header.IPv6ProtocolNumber } // LinkAddressRequest implements stack.LinkAddressResolver. func (*protocol) LinkAddressRequest(addr, localAddr tcpip.Address, remoteLinkAddr tcpip.LinkAddress, linkEP stack.LinkEndpoint) *tcpip.Error { // TODO(b/148672031): Use stack.FindRoute instead of manually creating the // route here. Note, we would need the nicID to do this properly so the right // NIC (associated to linkEP) is used to send the NDP NS message. r := stack.Route{ LocalAddress: localAddr, RemoteAddress: addr, RemoteLinkAddress: remoteLinkAddr, } // If a remote address is not already known, then send a multicast // solicitation since multicast addresses have a static mapping to link // addresses. if len(r.RemoteLinkAddress) == 0 { r.RemoteAddress = header.SolicitedNodeAddr(addr) r.RemoteLinkAddress = header.EthernetAddressFromMulticastIPv6Address(r.RemoteAddress) } pkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: int(linkEP.MaxHeaderLength()) + header.IPv6MinimumSize + header.ICMPv6NeighborAdvertSize, }) icmpHdr := header.ICMPv6(pkt.TransportHeader().Push(header.ICMPv6NeighborAdvertSize)) pkt.TransportProtocolNumber = header.ICMPv6ProtocolNumber icmpHdr.SetType(header.ICMPv6NeighborSolicit) copy(icmpHdr[icmpV6OptOffset-len(addr):], addr) icmpHdr[icmpV6OptOffset] = ndpOptSrcLinkAddr icmpHdr[icmpV6LengthOffset] = 1 copy(icmpHdr[icmpV6LengthOffset+1:], linkEP.LinkAddress()) icmpHdr.SetChecksum(header.ICMPv6Checksum(icmpHdr, r.LocalAddress, r.RemoteAddress, buffer.VectorisedView{})) length := uint16(pkt.Size()) ip := header.IPv6(pkt.NetworkHeader().Push(header.IPv6MinimumSize)) ip.Encode(&header.IPv6Fields{ PayloadLength: length, NextHeader: uint8(header.ICMPv6ProtocolNumber), HopLimit: header.NDPHopLimit, SrcAddr: r.LocalAddress, DstAddr: r.RemoteAddress, }) // TODO(stijlist): count this in ICMP stats. return linkEP.WritePacket(&r, nil /* gso */, ProtocolNumber, pkt) } // ResolveStaticAddress implements stack.LinkAddressResolver. func (*protocol) ResolveStaticAddress(addr tcpip.Address) (tcpip.LinkAddress, bool) { if header.IsV6MulticastAddress(addr) { return header.EthernetAddressFromMulticastIPv6Address(addr), true } return tcpip.LinkAddress([]byte(nil)), false } // ======= ICMP Error packet generation ========= // icmpReason is a marker interface for IPv6 specific ICMP errors. type icmpReason interface { isICMPReason() } // icmpReasonParameterProblem is an error during processing of extension headers // or the fixed header defined in RFC 4443 section 3.4. type icmpReasonParameterProblem struct { code header.ICMPv6Code // respondToMulticast indicates that we are sending a packet that falls under // the exception outlined by RFC 4443 section 2.4 point e.3 exception 2: // // (e.3) A packet destined to an IPv6 multicast address. (There are // two exceptions to this rule: (1) the Packet Too Big Message // (Section 3.2) to allow Path MTU discovery to work for IPv6 // multicast, and (2) the Parameter Problem Message, Code 2 // (Section 3.4) reporting an unrecognized IPv6 option (see // Section 4.2 of [IPv6]) that has the Option Type highest- // order two bits set to 10). respondToMulticast bool // pointer is defined in the RFC 4443 setion 3.4 which reads: // // Pointer Identifies the octet offset within the invoking packet // where the error was detected. // // The pointer will point beyond the end of the ICMPv6 // packet if the field in error is beyond what can fit // in the maximum size of an ICMPv6 error message. pointer uint32 } func (*icmpReasonParameterProblem) isICMPReason() {} // icmpReasonPortUnreachable is an error where the transport protocol has no // listener and no alternative means to inform the sender. type icmpReasonPortUnreachable struct{} func (*icmpReasonPortUnreachable) isICMPReason() {} // returnError takes an error descriptor and generates the appropriate ICMP // error packet for IPv6 and sends it. func (p *protocol) returnError(r *stack.Route, reason icmpReason, pkt *stack.PacketBuffer) *tcpip.Error { // Only send ICMP error if the address is not a multicast v6 // address and the source is not the unspecified address. // // There are exceptions to this rule. // See: point e.3) RFC 4443 section-2.4 // // (e) An ICMPv6 error message MUST NOT be originated as a result of // receiving the following: // // (e.1) An ICMPv6 error message. // // (e.2) An ICMPv6 redirect message [IPv6-DISC]. // // (e.3) A packet destined to an IPv6 multicast address. (There are // two exceptions to this rule: (1) the Packet Too Big Message // (Section 3.2) to allow Path MTU discovery to work for IPv6 // multicast, and (2) the Parameter Problem Message, Code 2 // (Section 3.4) reporting an unrecognized IPv6 option (see // Section 4.2 of [IPv6]) that has the Option Type highest- // order two bits set to 10). // var allowResponseToMulticast bool if reason, ok := reason.(*icmpReasonParameterProblem); ok { allowResponseToMulticast = reason.respondToMulticast } if (!allowResponseToMulticast && header.IsV6MulticastAddress(r.LocalAddress)) || r.RemoteAddress == header.IPv6Any { return nil } // Even if we were able to receive a packet from some remote, we may not have // a route to it - the remote may be blocked via routing rules. We must always // consult our routing table and find a route to the remote before sending any // packet. route, err := p.stack.FindRoute(r.NICID(), r.LocalAddress, r.RemoteAddress, ProtocolNumber, false /* multicastLoop */) if err != nil { return err } defer route.Release() // From this point on, the incoming route should no longer be used; route // must be used to send the ICMP error. r = nil stats := p.stack.Stats().ICMP sent := stats.V6PacketsSent if !p.stack.AllowICMPMessage() { sent.RateLimited.Increment() return nil } network, transport := pkt.NetworkHeader().View(), pkt.TransportHeader().View() if pkt.TransportProtocolNumber == header.ICMPv6ProtocolNumber { // TODO(gvisor.dev/issues/3810): Sort this out when ICMP headers are stored. // Unfortunately at this time ICMP Packets do not have a transport // header separated out. It is in the Data part so we need to // separate it out now. We will just pretend it is a minimal length // ICMP packet as we don't really care if any later bits of a // larger ICMP packet are in the header view or in the Data view. transport, ok := pkt.TransportHeader().Consume(header.ICMPv6MinimumSize) if !ok { return nil } typ := header.ICMPv6(transport).Type() if typ.IsErrorType() || typ == header.ICMPv6RedirectMsg { return nil } } // As per RFC 4443 section 2.4 // // (c) Every ICMPv6 error message (type < 128) MUST include // as much of the IPv6 offending (invoking) packet (the // packet that caused the error) as possible without making // the error message packet exceed the minimum IPv6 MTU // [IPv6]. mtu := int(route.MTU()) if mtu > header.IPv6MinimumMTU { mtu = header.IPv6MinimumMTU } headerLen := int(route.MaxHeaderLength()) + header.ICMPv6ErrorHeaderSize available := int(mtu) - headerLen if available < header.IPv6MinimumSize { return nil } payloadLen := network.Size() + transport.Size() + pkt.Data.Size() if payloadLen > available { payloadLen = available } payload := buffer.NewVectorisedView(pkt.Size(), pkt.Views()) payload.CapLength(payloadLen) newPkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ ReserveHeaderBytes: headerLen, Data: payload, }) newPkt.TransportProtocolNumber = header.ICMPv6ProtocolNumber icmpHdr := header.ICMPv6(newPkt.TransportHeader().Push(header.ICMPv6DstUnreachableMinimumSize)) var counter *tcpip.StatCounter switch reason := reason.(type) { case *icmpReasonParameterProblem: icmpHdr.SetType(header.ICMPv6ParamProblem) icmpHdr.SetCode(reason.code) icmpHdr.SetTypeSpecific(reason.pointer) counter = sent.ParamProblem case *icmpReasonPortUnreachable: icmpHdr.SetType(header.ICMPv6DstUnreachable) icmpHdr.SetCode(header.ICMPv6PortUnreachable) counter = sent.DstUnreachable default: panic(fmt.Sprintf("unsupported ICMP type %T", reason)) } icmpHdr.SetChecksum(header.ICMPv6Checksum(icmpHdr, route.LocalAddress, route.RemoteAddress, newPkt.Data)) if err := route.WritePacket( nil, /* gso */ stack.NetworkHeaderParams{ Protocol: header.ICMPv6ProtocolNumber, TTL: route.DefaultTTL(), TOS: stack.DefaultTOS, }, newPkt, ); err != nil { sent.Dropped.Increment() return err } counter.Increment() return nil }